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INDEX

Activity, definition and unit, PI:12 Activity median aerodynamic diameter

P1:24, 29, 63; PlS:Errata; P3S:3 Aerosols, radioactive ~1:23 a-emitters assumed to be on bone sur-

faces P1:38 Annual limit on intake P1:2, 3, 4, 8,

18, 20, 21, 29, 53, 63; PlS:1,3; PlS:Erratai P2S:1,.3; P3S:3

Becquerel (Bq)l:l, 12 E-emitters Pi:50

assumed to be bone surfaces PI:41 uniformly distributed throughout

volume of bone P1:39 Body fluids

activity transferred from gastrointestinal tract P1:32

transfer of radionuclide from lung P1:27

Bone 6 -emitters uniformly distributed

throughout volume of P1:39 dosimetric model for P1:35 trabecular and cortical, number of

nuclear transformations in P1:43 Bone dosimetry P1:3 Bone surfaces

a-emitters assumed to be on P1:38 3 -emitters assumed to be on P1:41

Bronchial tree, deposition in P1:24 Cancer Pl:l, 2, 6 Cell sterilization P1:15 Cells near bone surfaces, committed

dose equivalent P1:45 Cellular distribution of dose P1:14 Chemical toxicity P1:53

Committed dose equivalent P1:6, 8, 12; PlS:3; P2S:3; P3S:3

bone surface cells P1:35 cells near bone surfaces P1:45 gastrointestinal tract P1:32 lung P1:28 red bone marrow PX:35, 45 tissue P1:6

Compartmental models, exact and approxi- mate solutions of P1:56

Daughter radionuclides Pl:lB, 26, 43, 49, 52, 59, 61; Pls:l

Decay schemes P1:16; PlS:l; P2S:l; P3S:l

Deposition and retention model P1:23 Derived air concentration P1:2, 3, 4, 9,

18, 20, 21, 29, 53, 63; Pls:l, 3; PlS:Errata; P2S:3;-P3S:3

for submersion in radioactive cloud Pl:lO, 50; P1S:Errata

Dose-equivalent P1:l.T Dose-equivalent estimation from radio-

nuclides in people of different ages P1:54

Dose-equivalent limits for occupational exposure P1:5 for stochastic effects P1:6

Dose-equivalent rate PlS:3; P2~:3 from external and internal radiation

for submersion in radioactive cloud P1:47

in body tissues from submersion in radioactive cloud P1:49

Dosimetric data assumptions concerning chemical and

physical form P1:52

LIMITS FOR INTAKES OF RADIONUCLIDES BY WORKERS

Dosimetric data (contd.) assumptions concerning chemical

toxicity P1:53 assumptions concerning daughter

radionuclides P1:52 assumptions concerning exposed

individual P1:53 assumptions concerning metabolic

models P1:52

exposure to mixture of radionuclides by inhalation, ingestion and submersion Pl:53

use and limitations of P1:52 Dosimetric model

bone P1:35 gastrointestinal tract P1:30 respiratory system P1:23 submersion in radioactive cloud

Pl:3, 47 Electrons, dose equivalent rates P1:50 Fission fragments Pl:42 Gastrointestinal tract P1:3

activity transferred from respiratory system P1:31

activity transferred to body fluids P1:32

committed.dose equivalent P1:32 dosimetric model for P1:30 number of transformations in various

compartments of P1:60 transfer of radionuclide from lung

P1:27 Gray (gy) Pl:l, 12 Hereditary disease Pl:l, 2, 6 Internal dose control

basic limits P1:5 secondary and derived limits P1:18

Lung committed.dose equivalent P1:28 number of transformations in pulmon-

ary region P1:59 number of transformations in tracheo-

bronchial region P1:58 number of transformations in various

compartments P1:60 transfer of radionculide to body

fluids or gastrointestinal tract P1:27

Masses of organs and tissues of Refer- ence Man P1:16

Maximum permissible body burden Pl:l Maximum permissible concentration in

air and in water Pl:l, 2 Metabolic data P1:3, 63 Metabolic models P1:52, 56 Mineral bone, o-emitters uniformly

distributed throughout volume Pl:37; PlS:Errata

Modifying factors= Nasal passage, deposition in P1:24 Number of'transformations P2S:2; P3S:2

daughter radionuclide in pulmonary region P1:59

in source organs or tissues PlS:2 inhaled radionuclide in tracheo-

bronchial region of lung P1:58 source organ over 50 years P1:17 trabecular and cortical bone P1:43 various compartments of lung and

gastrointestinal tract P1:60 Osteogenic cells, dose equivalent cal-

culation P1:35 Particle size correction P1:29 Photon emitters, dose equivalent rate

P1:49 Pulmonary lymphatic system P1:25 Pulmonary parenchyma P1:24 Quality factor P1:3, 12, 13, 32 Radioactive aerosols P1:23 Radioactive cloud

dosimetric model for submersion in P1:3, 47

Radiological protection measures P1:15 Recoil atoms P1:42 Red bone marrow, committed dose equiva-

lent P1:45 Reference Man P1:2, 6, 8, 9 Respiratory system P1:3

activity transferred to gastrointestinal tract P1:31

clearance model P1:25; PlS:Errata dosimetric model for P1:23 dust deposition P1:24; PlS:Errata

Restrictions on rate of intake of radioactive materials P1:7

SI units Pl:l, 12 Sievert (Sv) Pl:l, 12 Skeletal tissues, absorbed fractions in

Pl:37 Source organs, mass of P1:16 Specific effective 'energy P1:3, 4, 15,

28, 32, 34; P1S:l; P2S:l; P3S:l Standard Man P1:l Stem cells, dose equivalents Pl:35 Target organs, mass of P1:16 Trachea, deposition in P1:24 Weight,ed cormnitted dose equivalent

PlS:3; P2S:3; P3S:3 Weighted dose equivalent rate PlS:3;

P2S:3 Weighting factors for stochastic risks

P1:6

INDEX TO RADIONUCLIDES

Note: In order to conserve space certain abbreviated forms are used throughout this index. The full meaning is indicated below by the additional wording shown in parenthesis.

Classification of isotopes (for bone dosimetry) Committed dose equivalent (in soft tissues or target

organs or tissues) Dose equivalent rate (in lung) Number of transformations (in source'organs or tissues) Weighted committed dose equivalent (in soft tissues or

target organs or tissues)

Actinium annual limits on intake P3:107 classification of isotopes P3:107 derived air concentration P3:107 distribution and retention P3:106 inhalation classes P3:106 metabolic data P3:106 metabolic model P3:106 metabolism P3:106 uptake to blood P3:106

Actinium-223 specific effective energy P3S:805

Actinium-224 annual limits on intake P3S:768 committed dose equivalent P3S:767 decay scheme P3S:759 derived air concentration P3S:768 number of transformations P3S:765 specificeffective energyP3S:759,811 weighted cmtd. dose equiv. P3S:767

Actinium-225 annual limits on intake P3S:773 connnitted dose equivalent P3S:772 decay scheme P3S:769 derived air concentration P3S:773 number of transformations P3S:771 specific effective energy PlS:283,

315; P3S:769 weighted cmtd. dose equiv. P3S:773

Actinium- 226 annual limits on intake P3S:785 committed dose equivalent P3S:784 decay scheme P35:774 derived air concentration P3S:785 number of transformations P3S:782 specific effective energy P3S:774 weighted cmtd. close equiv. P3S:785

Actinium-227 annual limits on intake P3S:791 committed dose equivalent P3S:790 decay scheme P3S:786 derived air concentration P3S:791 number of transformations P3S:789 specific effective energy PlS:291,

324, 344; P3S:786, 824 weighted cmtd. dose equiv. P3S:790

Actinium-228 annual limits on intake P3S:803 committed dose equivalent P3S:BOl decay scheme P3S:792 derived air concentration P3S:803 number of transformations P3S:BOO specific effective energy PlS:296,

330; PZS:731, P3s:792 weighted cmtd. dose equiv. P3S:BOZ

Aluminium annual limits on intake P3:13 classification of isotopes P3:13

4 LIMITS FOR INTAKES OF RADIONUCLIDES BY WORKERS

derived air concentration P3:13 distribution and retention P3:12 inhalation classes P3:12 metabolic data ~3:12 metabolic model P3:12

_... _-.-

committed dose equivalent decay scheme PlS:451 derived air concentration number of transformations specific effective energy

PlS:451

PlS:454 PlS:453 PlS:451

metaDoL1sm PJ:lL Reference Man data P3:12 uptake to blood P3:12

_ ..* Aluminium- Lb

weighted cmtd. dcse equiv. PlS:454 Americium-241

annual limits on intake PlS:456 committed dose equivalent FlS:456 decay scheme PlS:455 derived air concentration FlS:456 number of transformations PlS:455 specific effective energy FlS:420,

455, 477, 502, 513 Americium-242m

annual limits on intake P3S:30 committed dose equivalent P3S:29 decay scheme P3S:28 derived air concentration F3S:30 number of transformations F3S:28 specific effective energy P3~:28 weighted cmtd. dose equiv. P3S:29

Aluminium-28

specific effective energy F3S:25 Americium

annual limits on intake Pl:llO chelated compounds P1:109 classification of isotopes P1:109 derived air concentration Fl:llO distribution and retention F1:108 inhalation classes F1:108 metabolic data F1:108 metabolic mcdel Pl:lOB metabolism F1:108 uptake to blood P1:108

Americium-237 annual limits on intake PlS:442 committed dose equivalent PlS:442 decay scheme FlS:440 derived air concentration FlS:442 number of transformations FlS:441 specific effective energy FlS:440 weighted cmtd. dose equiv. PlS:442

Americium-238 annual limits on intake FlS:446 committed dose equivalent FlS:445 decay scheme FlS:443 derived air concentration F18:446 number of transformations PlS:445 specific effective energy PlS:443,

487 weighted cmtd. dose equiv. PlS:446

Americium-239 annual limits on intake PlS:450 committed dose equivalent PlS:449 decay scheme PlS:447 derived air concentration PlS:450 number of transformations PlS:449 specific effective energy FlS:447 weighted cmtd. dose equiv. PlS:450

Americium-240 annual limits on intake PlS:454

annual limits on intake FlS:460 committed dose equivalent PlS:459 decay scheme PlS:457 derived air concentration PlS:460 number of transformations PlS:459 specific effective energy PlS:457 weighted cmtd. dose equiv. PlS:460

Americium-242 annual limits on intake PlS:465 committed dose equivalent PlS:464 decay scheme PlS:461 derived air concentration FlS:465 number of transformations FlS:464 specific effective energy PlS:457,

461 weighted cmtd. dose equiv. FlS:465

Americium-243 annual limits on intake PlS:467 committed dose equivalent FlS:466 decay scheme FlS:465 derived air ‘gncentration FlS:467 number of transformations PlS:466 specific effective energy FlS:427,

465, 518; P35:850 weighted cmtd. dose equiv. PlS:467

Americium-244m annual limits on intake PlS:471 committed dose equivalent PlS:470 decay scheme PlS:468 derived air concentration PlS:471 number of transformations PlS:470 specific effective energy PlS:468 weighted cmtd. dcse equiv. FlS:471

Americium-244 annual limits on intake PlS:475 comitted dose equivalent PlS:474 decay scheme PlS:472 derived air concentration PlS:475 number of transformations PlS:474 specific effective energy FlS:472 weighted cmtd. dose equiv. PlS:475

INDEX 5

Americium-245 annual limits on intake PlS:479 committed dose.equivalent PlS:478 decay scheme Pl.9:476 derived air concentration PlS:479 number of transformations PlS:478 specific effective energy PlS:436,

476; P3s:853 weighted cmtd. dose equiv. PlS:479

Americium-246m annual limits on intake PlS:482 committed dose equivalent PlS:481 decay scheme PlS:480 derived air concentration PlS:482 number of transformations PlS:481 specific effective energy PlS:480 weighted cmtd. dose equiv. PlS:482

Americium-246 annual limits on intake PlS:485 committed dose equivalent PlS:484 decay scheme PlS:483 derived air concentration PlS:485 number of transformations PlS:484 specific effective energy PlS:483 weighted comtd. dose equiv. PlS:485

Antimony annual limits on intake P3:48,49 classification of isotopes P3:47 derived air concentration P3:48,

49 distribution and retention P3:47 inhalation classes P3:46 metabolic data P3:46 metabolic model P3:46 metabolism P3:46 Reference Man data P3:46 uptake to blood P3:46

Antimony-115 annual limits on intake P3:221 committed dose equivalent P3S:221 decay scheme P3S:220 derived air concentration P3S:221 number of transformations P3S:220 specific effective energy P3S:220 weighted cmtd. dose equiv. P3S:221

Antimony-116m annual limits on intake P3S:224 committed dose equivalent P3S:223 decay scheme P3S:222 derived air concentration P3S:224 number of transformations P3S:223 specific effective energy P3S:222 weighted cmtd. dose equiv. P3S:224

Antimony-116 annual limits on intake P3S:226 committed dose equivalent P3S:226

decay scheme P3S:225 derived air concentration P3S:226 number of transformations P3S:225 specific effective energy PlS:157;

P3S:225 weighted cmtd. dose equiv. P3:226

Antimony-117 annual limits on intake P3S:229 committed dose equivalent P3S:228 decay scheme P3S:227 derived air concentration P3S:229 number of transformations P3S:228 specific effective energy P3S:227 weighted cmtd. dose equiv. P3S:229

Antimony-118m annual limits on intake P3S:232 committed dose equivalent P3S:231 decay scheme P3S:230 derived air concentration P3S:232 number of transformations P3S:231 specific effective energy P3S:230 weighted cmtd. dose equiv. P3S:232

Antimony-119 annual limits on intake P3S:235 committed dose equivalent P3S:234 decay scheme P3S:233 derived air concentration P35:235 number of transformations P3S:234 specific effective energy P3S:233 weighted cmtd. dose equiv. P3S:235

Antimony-120 (15.89m) annual limits on intake P3S:236 committed dose equivalent P3S:236 decay scheme P35:235 derived air concentration P3S:236 number of transformations P3S:236 specific effective energy P3S:235 weighted cmtd. dose equiv. P3S:236

Antimony-120 (5.76d) annual limits on intake P3S:239 committed dose equivalent P3S:238 decay scheme P3S:237 derived air concentration P3S:239 number of transformations P3S:238 specific effective energy P3S:237 weighted cmtd. dose equiv. P3S:239


Antimony-124m annual limits on intake P3S:245


committed dose equivalent P3S:245 decay scheme P3S:243 derived air concentration P3S:245 number of transformations P3S:244 specific effective energy P3S:243 weighted cmtd. dose equiv. P3S:245

Antimony-124 annual limits on intake P3S:248 committed dose equivalent P3S:247 decay scheme P3S:246 derived air concentration P3S:248 number of transformations P3S:247 specificeffective energyP3S:244,246 weighted cmtd. dose equiv. P3S:248

Antimony-125 annual limits on intake P3S:253 committed dose equivalent P3~:251 decay scheme P3S:249 derived air concentration P3S:254 number of transformations P3S:251 specific effective energy P3S:204,

249 weighted cmtd. dose equiv. P3S:252

Antimony-126m annual limits on intake P3S:255 committed dose equivalent P35:254 decay scheme P3S:253 derived air concentration P3S:255 number of transformations P3S:254 specific effective energy P3S:208,


Antimony-126 annual limits on intake P3S:257 committed dose equivalent P3S:256 decay scheme P3S:255 derived air concentration P3S:257 number of transformations P3S:256 specific effective energy P3S:209,

253, 255 weighted cmtd. dose equiv. P3S:257

Antimony-127 annual limits on intake P3S:261 committed dose equivalent P3S:260 decay scheme P3S:258 derived air concentration P3S:261 number of transformations P3S:260 specific effective energy P3S:213,


Antimony-128 specific effective energy P3S:217

Antimony-128 (10.4m) annual Limits on intake P3S:265 committed dose equivalent P3S:264 decay scheme P3S:264

derived air concentration P3S:265 number of transformations P3S:264 specific effective energy P3S:264 weighted cmtd. dose equiv. P3S:265

Antimony-128 (9.01h) annual limits on intake P3S:263 committed dose equivalent P35:263 decay scheme P3S:262 derived air concentration P3S:263 number of transformations P3S:262 specific effective energy P3S:262 weighted cmtd. dose equiv. P3S:263

b Antimony-129 annual limits on intake P3S:268 committed dose equivalent P3S:267 decay scheme P3S:265 derived air concentration P3S:268 number of transformations P3S:266 specific effective energy P3S:265 weighted cmtd. dose equiv. P3S:267

Antimony-130 annual limits on intake P3S:269 committed dose equivalent P3S:269 decay scheme P3S:268 derived air concentration P3S:269 number of transformations P3S:268 specific effective energy P35:268 weighted cmtd. dose equiv. P3S:269


Argon derived air concentration P2:lO dose equivalent rate P1:48 metabolic data P2:lO

Argon-37 decay scheme P2S:24 derived air concentration P2S:24 dose equivalent rate P2S:24 specific effective energy P2S:24 weighted cmtd. dose equiv. P2S:24

Argon-39 decay scheme P2S:24 derived air concentration P2S:26 dose equivalent rate P2S:25 specific effective energy P2S:24 weighted cmtd. dose equiv, P2S:26

Argon-41 decay scheme P2S:26 derived air concentration P2S:28 dose equivalent rate P2S:27

INDEX

number of transformations P25:27 specific effective energy P2S:26 weighted cmtd. dose equiv. P2S:28

Arsenic annual limits on intake P3:37 classification of isotopes P3:35 derived air concentration P3:37 distribution and retention P3:34 inhalation classes P3:34 metabolic data P3:34 metabolic model P3:34 metabolism P3:34 Reference Man data P3:34 uptake to blood P3:34

Arsenic-69 annual limits on intake P3S:128 committed dose equivalent P3S:128 decay scheme P3S:127 derived air concentration P3S:128 number of transformations P3S:127 specific effective energy P35:127 weighted cmtd. dose equiv. P35:128

Arsenic-70 annual limits on intake P3S:130 committed dose equivalent P3S:129 decay scheme P3S:128 derived air concentration P3S:l30 number of transformations P3S:l29 specific effective energy P3S:12g,


Arsenic-71 annual limits on intake P3S:132 committed dose equivalent P3S:132 decay scheme P3S:130 derived air concentration P35:132 number of transformations P3S:131 specific effective energy P3S:130 weighted cnrd. dose equiv. P3S:132

Arsenic-72 annual limits on intake P3S:134 committed dose equivalent P3S:134 decay scheme P3S:133 derived air concentration P3S:134 number of transformations P3S:133 specific effective energy P3S:133 weighted cmtd. dose equiv. P3S:134

Arsenic-73 annual limits on intake P3S:136 committed dose equivalent P35:136 decay scheme P3S:135 derived air concentration P3S:136 number of transformations P3S:135 specific effective energy P3S:135,


Arsenic-74 annual limits on intake P3S:138 committed dose equivalent P3S:138 decay scheme P3S:137 derived air concentration P3S:138 number of transformations P35:13? specific effective energy P3S:137 weighted cmtd. dose equiv. P3~:138

Arsenic-76 annual limits on intake P3S:140 committed dose equivalent P3S:139 decay scheme P3S:139 derived air concentration P3S:140 number of transformations P3S:139 specific effective energy P3S:139 weighted cmtd. dose equiv. P3S:140

Arsenic-77 annual limits on intake P3S:142 committed dose equivalent P3S:141 decay scheme P3S:li40 derived air concentration P3S:142 number of transformations P3S:141

specif.iceffective energyP3S:122,140 weighted cmtd. dose equiv. P3S:141

Arsenic-78 annual limits on intake P35:143 committed dose equivalent P3S:143 decay scheme P3S:l42 derived air concentration P3~:143 number of transformations P3S:142 specificeffective energyP35:125,142

weighted cmtd. dose equiv. P3S:143 Astatine

annual limits on intake P3:103 classification of isotopes P3:102 derived air concentration P3:103 distribution and retention P3:102 inhalation classes P3:102 metabolic data P3:102 metabolic model P3:102 metabolism P3:102 uptake to blood P3:102

Astatine-207 annual limits on intake P3S:741 committed dose equivalent P3S:740 decay scheme P3S:737 derived air concentration P3~:741 number of transformations P3S:740 specific effective energy P3S:737 weighted cmtd. dose equiv. P3S:741

Astatine-211 annual limits on intake P3S:745 committed dose equivalent P3S:743 decay scheme P3S:742 derived air concentration P3~:745 number of transformations P3S:743

8 LIMITS FOR INTAKES OF

specific effective energy P35:742 weighted cmtd. dose equiv. P3S:744

Astatine-215 specific effective energy P3S:805

Astatine-216

RADIONUCLIDES BY WORKERS

specific effective energy P2S:386, 388, 390; P3S:273

weighted cmtd. dose equiv. P2S:391 Barium-133m

annual limits on intake P2S:394 specificeffective energyP3S:762,813

Astatine-217 committed dose equivalent P2S:393 decay scheme P2S:392

specific effective energy PlS:283, derived air concentration P2S:394 316, 360; P35:770 number of transformations P2S:393

Astatine-218 specific effective energy PIS:287,

specific effective energy P2S:392


Barium-133 annual limits on intake P2S:396 committed dose equivalent P2S:395 decay scheme P25:394

Barium derived air concentration P2S:396 annual limits on intake P2:49 number of transformations P2S:395 behaviour of daughters P2:48 classification of isotopes P2:48

specificeffective energyP2S:392,394 weighted cmtd. dose equiv. P2S:396

derived air concentration P2:49 Barium-135m distribution and retention P2:48 annual limits on intake P2S:398 inhalation classes P2:48 committed dose equivalent P2S:397 metabolic data P2:48 decay scheme P2S:397 metabolic model P2:48 derived air concentration P2S:398 metabolism P2:48 number of transformations P2S:397 Reference Man data P2:48 specific effective energy P2S:397 uptake to blood P2:48 weighted cmtd. dose equiv. P2S:398

Barium-126 Barium-137m annual limits on intake P2S:383 committed dose equivalent P2S:382 decay scheme P2S:381 derived air concentration P2S:383 number of transformations P2S:382 specific effective energy P2S:381 weighted cmtd. dose equiv. P2S:383

Barium-128 annual limits on intake P25:386 committed dose equivalent P2S:385 decay scheme P2S:383 derived air concentration P2S:386 number of transformations P2S:384 specific effective energy P2S:383 weighted cmtd. dose equiv. P2S:385

Barium-131m annual limits on intake P2S:388 committed dose equivalent P2S:387 decay scheme P2S:386 derived air concentration P2S:388 number of transformations P2S:387 specific effective energy P2S:386 weighted cmtd. dose equiv. P2S:387

Barium-131 annual limits on intake P2S:391 committed dose equivalent P2S:390 decay scheme P2S:388 derived air concentration P2S:391

specific effective energy PlS:235 Barium-139

annual limits on intake P2S:400 committed dose equivalent P2S:399 decay scheme P2S:398 derived air concentration P2S:400 number of transformations P2S:399 specific effective energy P2S:398 weighted cmtd. dose equiv. P2S:399

Barium-140 annual limits on intake P2S:402 committed dose equivalent P2S:401 decay scheme P2S:400 derived air concentration P2S:402 number of transformations P2S:401 specific effective energy P2S:400 weighted cmtd. dose equiv. P2S:402

Barium-141 annual limits on intake P2S:405 committed dose equivalent P2S:405 decay scheme PZS:403 derived air concentration P2S:405 number of transformations P2S:404 specific effective energy P2S:403 weighted cmtd. dose equiv. P2S:405

Barium-142 annual limits on intake P2S:407 committed dose equivalent P2S:407

decay scheme P2S:406 derived air concentration P2S:407 number of transformations P2S:406 specific effective energy P2S:406 weighted cmtd. dose equiv. PZS:407

Berkelium annual limits on intake P3:112 chelated compounds P3:lll classification of isotopes P3:112 derived air concentration P3:112 distribution and retention P3:lll inhalation classes P3:lll metabolic data P3:lll metabolic model P3:lll metabolism P3:lll uptake to blood P3:lll

Berkelium-245 annual limits on intake P3S:844 committed dose equivalent P3S:843 decay scheme P35:841 derived air concentration P3S:844 number of transformations P3S:843 specific effective energy P3S:841 weighted cmtd. dose equiv. P3S:844

Berkelium-246 annual limits on intake P3S:848 committed dose equivalent P3S:847 decay scheme P3S:845 derived air concentration P3S:848 number of transformations P3S:847 specific effective energy P3S:845 weighted cmtd. dose equiv. P3S:848

Berkelium-247

specific effective energy P3S:856, 876, 880, 912

weighted cmtd. dose equiv. P3S:860 Beryllium

annual limits on intake P3:3 classification of isotopes P3:2 derived air concentration P3:3 distribution and retention P3:l inhalation classes P3:l metabolic data P3:l metabolic model P3:l metabolism P3:l Reference Man data P3:l uptake to blood P3:l

Beryllium-7 annual limits on intake P3S:7 committed dose equivalent ~3:6 decay scheme P3S:5 derived air concentration P3S:7 number of transformations P3S:6 specific effective energy P3S:5 weighted comtd. dose equiv. P3S:7

Beryllium-10 annual limits on intake P3S:9 committed dose equivalent P3S:9 decay scheme P3S:8 derived air concentration P3S:9 number of transformations P3S:8 specific effective energy P3S:8 weighted cmtd. dose equiv. P3S:9

Bismuth annual limits on intake P2:68 classification of isotopes P2:67 derived air concentration P2:68 distribution and retention P2:67 inhalation classes P2:67 metabolic data P2:67 metabolic model P2:67 metabolism P2:67 Reference Man data P2:67 uptake to blood P2:67

Bismuth-200 annual limits on intake P2S:678 committed dose equivalent P2S:677 decay scheme P2S:675 derived air concentration P2S:678 number of transformations P2S:676 specific effective energy P2S:675 weighted cmtd. dose equiv. P2S:677

Bismuth-201 annual limits on intake P2S:681 committed dose equivalent P2S:680 decay scheme P25:678 derived air concentration P2S:681 number of transformations P2S:679

number of transformations P3S:859 specific effective energy P2S:678

annual limits on intake P3S:851 committed dose equivalent P3S:851 decay scheme P3S:849 derived air concentration P3~:851 number of transformations P3S:850 specific effective energy P3S:850,

869 weighted cmtd. dose equiv. P3~:851

Berkelium-249 annual limits on intake P3S:855 committed dose equivalent P3S:855 decay scheme P3S:852 derived air concentration P3S:855 number of transformations P3S:854 specific effective energy PlS:523,

549; P3s:852, 872, 888, 899, 906 weighted cmtd. dose equiv. P3~:855

Berkelium-250 annual limits on intake P3S:860 committed dose equivalent P3~:860 decay scheme P3S:856 derived air concentration P3S:860

INDEX 9


weighted cmtd. dose equiv. P2S:680 Bismuth-202

annual limits on intake PZS:684 connnitted dose equivalent PZS:683 decay scheme P2S:681 derived air concentration PZS:684 number of transformations PZS:683 specific effective energy P25:681 weighted cmtd. dose equiv. PZS:684

Bismuth-203 annual limits on intake PZS:687 committed dose equivalent PZS:686 decay scheme P2S:685 derived air concentration PZS:687 number of transformations P25:686 specific effective energy PlS:259;

PZS:685; P3s:739 weighted cmtd. dose equiv. P2~:687

Bismuth-205 annual limits on intake PZS:690 committed dose equivalent PZS:689 decay scheme P2S:688 derived air concentration PZS:690 number of transformations PZS:688 specific effective energy PlS:264;

PZS:688 weighted cmtd. dose equiv. PZS:689

Bismuth-206 annual limits on intake PZS:692 committed dose equivalent PZS:691 decay scheme PZS:690 derived air concentration PZS:692 number of transformations PZS:691 specific effective energy PZS:690 weighted cmtd. dose equiv. PZS:692

Bismuth-207 annual limits on intake PZS:694 committed dose equivalent PZS:693 decay scheme PZS:692 derived air concentration P25:694 number of transformations PZS:693 specific effective energy PlS:269;

PZS:692; P3S:738 weighted cmtd. dose equiv. P2~:694

BismuthZlOm annual limits on intake PZS:696 committed dose equivalent PZS:695 decay scheme P2S:694 derived air concentration PZS:696 number of transformations PZS:695 specific effective energy P25:694 weighted cmtd. dose equiv. P2~:696

Bismuth-210 annual limits on intake PZS:698 committed dose equivalent PZS:697 decay scheme P25:696

derived air concentration PZS:698 number of transformations PZS:697 specific effective energy PlS:288,

303, 321, 340, 390, 490; P2s:659, 672, 696; P3S:749, 781, 821

weighted cmtd. dose equiv. PZS:698 Bismuth-211

specific effective energy PlS:275, 293, 307, 326, 348; PZS:662; P3s:755, 788, 807, 826

Bismuth-212 annual limits on intake PZS:701 committed dose equivalent PZS:700 decay scheme P2S:698 derived air concentration PZS:701 number of transformations PZS:699 specific effective energy PlS:279,

298, 312, 332, 354, 400, 497, 530; P25:666, 698, 709, 726, 733; P3S:763, 798, 813, 831

weighted cmtd. dose equiv. PZS:700 Bismuth-213

annual limits on intake PZS:704 committed dose equivalent PZS:703 decay scheme PZS:701 derived air concentration PZS:704 number of transformations PZS:702 specific effective energy PlS:283,

316, 360; pZS:701; P3s:770 weighted cmtd. dose equiv. PZS:703

Bismuth-214 annual limits on intake PZS:705 committed dose equivalent PZS:705 decay scheme P25:704 derived air concentration PZS:705 number of transformations PZS:705 specific effective energy PlS:287,

320; PZS:671, 704; P3S:777 weighted cmtd. dose equiv. PZS:705

Bromine annual limits on intake P2:26 behaviour of daughters P2:24 classification of isotopes P2:24 derived air concentration P2:26 distribution and retention P2:24 inhalation classes P2:24 metabolic data P2:24 metabolic model P2:24 metabolism P2:24

Reference Man data P2:24 uptake to blood P2:24

Bromine-74m annual limits on intake PZS:98 committed dose equivalent PZS:97 decay scheme PZS:97 derived air concentration PZS:98

number of transformations P2S:97 specific effective energy P2S:97 weighted cmtd. dose equiv. P2S:98

Bromine-74 annual limits on intake P2S:99 committed dose equivalent PZS:99 decay scheme P2S:98 derived air concentration P2S:99 number of transformations P2S:98 specific effective energy P2S:98 weighted cmtd. dose equiv. P2S:99

Bromine-75

INDEX 1

derived air concentration P2S:lll number of transformations P2S:llO specific effective energy P2~:109 weighted cmtd. dose equiv.P2S:lll

Bromine-83 annual limits on intake P2S:113 committed dose equivalent P2S:113 decay scheme P2S:112 derived air concentration P2S:113 number of transformations P2S:112 specific effective energy P2S:112;

P3S:163 weighted cmtd. dose equiv. P2S:113

Bromine-84 annual limits on intake P2S:114 committed dose equivalent P2S:114 decay scheme P2S::113 derived air concentration P2S:114 number of transformations P2S:114 specific effective energy P2~:113 weighted cmtd. dose equiv. P2S:114

annual limits on intake P2S:lOl committed dose equivalent P2S:lOO decay scheme P2S:99 derived air concentration P2S:lOl number of transformations P2S:lOO specific effective energy P2S:99 weighted cmtd. dose equiv. P2S:lOO

Bromine- 76 annual limits on intake ~2S:103 committed dose equivalent P2S:102 decay scheme P2S:lOl derived air concentration P2S:103 number of transformations P2S:lOl specific effective energy P2S:lOl weighted cmtd. dose equiv. P2S:102

Bromine- 77 Cadmium annual limits on intake P2S:lO5 committed dose equivalent P2S:104 decay scheme P2S:103 derived air concentration P2S:LO5 number of transformations P2S:104 specific effective energy P2S:103 weighted cmtd. dose equiv. P2S:105

Bromine-80m annual limits on intake P2S:107 committed dose equivalent P2S:107 decay scheme P2S:106 derived air concentration P2S:107 number of transformations P2S:106 specific effective energy P2S:106 weighted cmtd. dose equiv. P2S:107

Bromine-80

annual limits on intake P2:44 classification of isotopes P2:43 derived air concentration P2:44 distribution and retention P2:42 inhalation classes P2:42 metabolic data P2:42 metabolic model P2.42 metabolism P2:42 Reference Man data P2:42 uptake to blood P2:42

Cadmium-104

annual limits on intake P2S:109 committed dose equivalent P2S:lOB decay scheme P2S:lOB derived air concentration P2S:109 number of transformations P2S:lOB specific effective energy P2S:106,

annual limits on intake P2S:295 committed dose equivalent P2S:293 decay scheme P2S:291 derived air concentration P2S:295 number of transformations P2S:293 specific effective energy P2~:291 weighted cmtd. dose equiv. P2S:294

Cadmium-107

108 weighted cmtd. dose equiv. P2S:lOB

Bromine-82 annual limits on intake P2S:lll committed dose equivalent P2S:llO

annual limits on intake P2S:298 committed dose equivalent P2S:297 decay scheme P2S:296 derived air concentration P2S:298 number of transformations P2S:296 specific effective energy P2S:296 weighted cmtd. dose equiv. PZS:297

Cadmium-109 decay scheme P2S:109 annual limits on intake P2S:300


committed dose equivalent P2S:299 decay scheme PZS:299 derived air concentration PZS:300 number of transformations PZS:299 specific effective energy PZS:299,

323 weighted cmtd. dose equiv. PZS:300

Cadmium-113m annual limits on intake PZS:302 cosnnitted dose equivalent PZS:301 decay scheme PZS:301 derived air concentration PZS:302 number of transformations PZS:301 specific effective energy PZS:301 weighted cmtd. dose equiv. PZS:302

Cadmium-113 annual limits on intake PZS:304 committed dose equivalent PZS:303 decay scheme PZS:303 derived air concentration PZS:304 number of transformations PZS:303 specific effective energy PZS:303 weighted cmtd. dose equiv. PZS:304

Cadmium-115m annual limits on intake P25:307 committed dose equivalent PZS:306 decay scheme PZS:305 derived air concentration PZS:307 number of transformations PZS:305 specific effective energy PZS:287,


Cadmium-115 annual limits on intake P2~:310 committed dose equivalent PZS:309 decay scheme PZS:308 derived air concentration PZS:310 number of transformations PZS:309 specific effective energy PZS:287,


Cadmium-117m annual limits on intake PZS:316 committed dose equivalent ~2S:315 decay scheme PZS:311 derived air concentration PZS:316 number of transformations ~2S:314 specific effective energy PZS:311 weighted cmtd. dose equiv. P2~:315

Cadmium-117 annual limits on intake PZS:321 committed dose equivalent PZS:320 decay scheme PZS:317 derived air concentration PZS:321 number of transformations P2S:319 specific effective energy PZS:317

weighted cmtd. dose equiv. PZS:320 Caesium

annual limits on intake P1:92, 93 behaviour of daughters P1:92 classification of isotopes P1:92 derived air concentration P1:92,93 distribution and retention P1:91 inhalation classes P1:91 metabolic data Pl:91 metabolic model P1:91 metabolism P1:91 Reference Man data P1:91 uptake to blood P1:91

Caesium-125 annual limits on intake PlS:214 committed dose equivalent PlS:213 decay scheme PlS:213 derived air concentration PlS:214 number of transformations PlS:213 specific effective energy PlS:213 weighted cmtd. dose equiv. PlS:214

Caesium-126 specific effective energy PZS:381


Caesium-128 specific effective energy PZS:384

Caesium-129 annual limits on intake P1~:218 committed dose equivalent PlS:217 decay scheme PlS:216 derived air concentration PlS:218 number of transformations PlS:217 specific effective energy PlS:216 weighted cmtd. dose equiv. PlS:218

Caesium-130 annual limits on intake PlS:219 committed dose equivalent PlS:219 decay scheme PlS:218 derived air concentration. PlS:219 number of transformations PlS:219 specific effective energy PlS:218 weighted cmtd. dose equiv. PlS:219

Caesium-131 annual limits on intake P18:222 committed dose equivalent PlS:220 decay scheme PlS:220 derived air concentration PlS:222 number of transformations PlS:220 specific effective energy PlS:220;

INDEX 13

PZS:389; P3s:274 weighted cmtd. dose equiv. PlS:221

Caesium-132 annual limits on intake PlS:224 committed dose equivalent PlS:22'3 decay scheme PlS:222 derived air concentration PlS:224 number of transformations PlS:222 specific effective energy PlS:222 weighted cmtd. dose equiv. PlS:223

Caesium-134m annual limits on intake PlS:226 committed dose equivalent PlS:225 decay scheme PlS:224 derived air concentration P18:226 number of transformations PlS:225 specific effective energy PlS:224 weighted cmtd. dose equiv. PlS:226

Caesium-134 annual limits on intake PlS:228 committed dose equivalent PlS:227 decay scheme PlS:226 derived air concentration PlS:228 number of transformations PlS:227 specificeffective energyPlS:225,226 weighted cmtd. dose equiv. PlS:228

Caesium-135m annual limits on intake P1~:230 committed dose equivalent PlS:229 decay scheme PlS:228 derived air concentration Pl~:230 number of transformations PlS:229 specific effective energy Pis:228 weighted cmtd. dose equiv. PlS:230



Caesium-137 annual limits on intake PlS:237 committed dose equivalent ~lS:236 decay scheme PlS:235 derived air concentration PlS:237 number of transformations PlS:236

specific effective energy PlS:235 weighted cmtd. dose equiv. PlS:237

Caesium-138 annual limits on intake PlS:239 committed dose equivalent PlS:238 decay scheme PlS:238 derived air concentration PlS:239 number of transformations PlS:238 specific effective energy Pis:238 weighted cmtd. dose equiv. PlS:238

Calcium annual limits on intake P2:14 classification of isotopes P2:13 derived air concentration P2:14 distribution and retention P2:13 inhalation classes P2:13 metabolic data P2:13 metabolic model P2:13 metabolism P2:13 Reference Man dat.a P2:13 uptake to blood P2:13

Calcium-41 annual limits on intake P2S:40 committed dose equivalent P2S:39 decay scheme P2S:39 derived air concentration P2S:40 number of transformations P2S:39 specific effective energy P2S:39 weighted cmtd. dose equiv. P2S:40



Californium annual limits on Intake P1:116 chelated compounds P1:114 classification of isotopes P1:115 derived air concentration P1:116 distribution and retention P1:114 inhalation classes P1:114 metabolic data P1:114 metabolic model PI:114 metabolism P1:114 uptake to blood P1:114


Californium-244 annual limits on intake PlS:532 committed dose equivalent PlS:532 decay scheme PlS:527 derived air concentration PlS:532 number of transformations PlS:530 specific effective energy PlS:527 weighted cmtd. dose equiv. PlS:532


Californium-248 annual limits on intake PlS:538 committed dose equivalent PlS:538 decay scheme PlS:536 derived air concentration PlS:538 number of transformations P1$:537 specific effective energy PlS:536;

P35:884 weighted cmtd. dose equiv. PlS:538

Californium-249 annual limits on intake PlS:541 committed dose equivalent PlS:540 decay scheme PlS:539 derived air concentration PlS:541 number of transformations PlS:540 specific effective energy PlS:523.

539, 550; P3S:853, 872, 889, 900, 907

weighted cmtd. dose equiv. PlS:540 Californium-250

annual limits on intake PlS:543 committed dose equivalent P1~:542 decay scheme PlS:541 derived air concentration PlS:543 number of transformations PlS:542 specific effective energy PlS:541;

P3S:857,862, 876,880, 892,913 weighted cmtd. dose equiv. PlS:543

Californium-251 annual limits on intake PlS:545 committed dose equivalent PlS:544 decay scheme PlS:543 derived air concentration PlS:545 number of transformations PlS:544 specific effective energy PlS3543;

P3S:868 weighted cmtd. dose equiv. PlS:547

Californium-252 annual limits on intake PlS:547 committed dose equivalent P1~:545

decay scheme PlS:545 derived air concentration PlS:547 number of transformations PlS:545 specific effective energy PlS:545 weighted cmtd. dose equiv. PlS:547

Californium-253 annual limits on intake PlS:551 committed dose equivalent PlS:551 decay scheme PlS:548 derived air concentration PlS:551 number of transformations PlS:550 specific effective energy PlS:548;

P3s:989, 905 weighted cmtd. dose equiv. PlS:551


Carbon annual limits on intake P3:9 carbonates and carbides P3:6 classification of isotopes P3:7 derived air concentration P3:9 distribution and retention P3:6 gases P3:5 inhalation classes P3:4 metabolic data P3:4 metabolic model P3:4 metabolism P3:4 microdosimetric consideration P3:7 organic compounds P3:4 Reference Man data P3:4 uptake to blood P3:4

Carbon-11 decay scheme P3S:lO

Carbon-11 (carbon dioxide gas) annual limits on intake P3S:16 - committed dose equivalent P3S:15 derived air concentration ~3S:16 number of transformations P3S:14 specific effective energy P3S:14 weighted cmtd. dose equiv. P3S:15

Carbon-11 (carbon monoxide gas) annual limits on intake P3S:14 committed'dose equivalent P3S:13 derived air concentration P3S:14 number of transformations ~3S:12 specific effective energy P3S:lZ weighted cmtd. dose equiv. P3S:l3

Carbon-11 (labelled organic compounds) annual limits on intake P3S:lZ committed dose equivalent P3S:ll

INDEX 15

derived air concentration P3S:12

number of transformations P3S:lO

specific effective energy P3S:lO

weighted cmtd. dose equiv. P3S:ll

Carbon-14

decay scheme P3S:16

Carbon-14 (carbon dioxide gas)

annual limits on intake P3S:23

committed dose equivalent P3S:22


number of transformations P3S:22


weighted cmtd. dose equiv. P3S:23

Carbon-14 (carbon monoxide gas)







Carbon-14 (labelled organic compounds







Cerium

annual limits on intake P1:94

classification of isotopes P1:94

derived air concentration P1:94 distribution and retention P1:94

inhalation classes P1:94

metabolic data P1:94

metabolic model P1:94

metabolism P1:94

uptake to blood P1:94

Cerium-134

annual limits on intake PlS:241

committed dose equivalent PlS:241

decay scheme PlS:240

derived air concentration PlS:241

number of transformations PlS:240

specific effective energy PlS:240

weighted cmtd. dose equiv. PlS:241

Cerium-135




derived air concentration, PlS:244


specifi,c effective energy PlS:242


Cerium-137m








Cerium-137



decay scheme PlS246



specific effective energy PlS:245,

246; P3s:301

weighted cmtd. dose equiv. PlS:247 Cerium-139





number of transfcsrmations PlS:249

specific effective energy-PlS;248;

P3s:306, 324


Cerium-141






specific effective energy PlS:251;

P2s:404; P3S:292


Cerium-143







P3S:297


Cerium-144







Chlorine


behaviour of daughters P2:8


derived air concentrations P2:8

distribution and retention P2:8



metabolic data P2:8 metabolic model P2:8 metabolism P2:8 Reference Man data P2:8 uptake to blood P2:8

Chlorine-36 annual limits on intake P2S:20 committed dose equivalent P2S:19 decay scheme P2S:18 derived air concentration P2S:20 number of transformations P2S:18 specific effective energy P25:18 weighted cmtd. dose equiv. P2S:19

Chlorine-38 annual limits on intake P2S:21 committed dose equivalent P2S:21 decay scheme P2S:20 derived air concentration P2S:21 number of transformations P2S:21 specific effective energy PZS:20 weighted cmtd. dose equiv. P2S:21

Chlorine-39 annual limits on intake P2S:23 committed dose equivalent P2S:22 decay scheme P2S:22 derived air concentration ~2S:23 number of transformations P2S:22 specific effective energy P2S:22 weighted cmtd. dose equiv. P2S:22

Chromium annual limits on intake P2:16 classification of isotopes P2:16 derived air concentrations P2:16 distribution and retention P2:15 inhalation classes P2:15 metabolic data P2:15 metabolic model P2:15 metabolism P2:15 Reference Man data P2:15 uptake to blood P2:15

Chromium-48 annual limits on intake P2S:49 committed dose equivalent P?.S:47 decay scheme PZS:45 derived air concentration P2S:49 number of transformations PZS:47 specific effective energy P2S:45 weighted cmtd. dose equiv. PZS:48

Chromium-49 annual limits on intake P2S:52 committed dose equivalent P2S:51 decay scheme P2S:50 derived air concentration P2~:52 number of transformations ~2~:50 specific effective energy P2S:50 weighted cmtd. dose equiv. P2S:51

Chromium-51 annual limits on intake PZS:56 committed dose equivalent P2S:54 decay scheme P2S:53 derived air concentration PZS:56 number of transformations P2S:53 specific effective energy PlS:12;


Cobalt annual limits on intake P1:75 classification of isotopes P1:74 derived air concentrations PI:75 distribution and retention P1:74 inhalation classes P1:73 metabolic data P1:73 metabolic model P1:73 metabolism Pl:73 Reference Man data P1:73 uptake to blood P1:73

Cobalt-55 annual limits on intake PlS:29 committed dose equivalent PlS:28 decay scheme PlS:27 derived air concentrations PlS:29 number of transformations P1S:27 specific effective energy PlS:27 weighted cmtd. dose equiv. PlS:28

Cobalt-56 annual limits on intake PlS:31 committed dose equivalent P~s:~cI decay scheme PlS:29 derived air concentrations PlS:31 number of transformations PlS:29 specific effective energy PlS:29;

~3s:65, 68 weighted cmtd. dose equiv. PlS:30

Cobalt-57 annual limits on intake PlS:33 committed dose equivalent PIS:3i! decay scheme PIS:31 derived air concentrations PlS:33 number of transformations PlS:31 specific effective energy PlS:31;

P3S:70, 73 weighted cmtd. dose equiv. PlS:32

Cobalt-58m annual limits on intake PlS:35 committed dose equivalent PlS:34 decay scheme PlS:33 derived air concentrations P1S:35 number of transformations P1S:34 specific effective energy PlS:33 weighted cmtd. dose equiv. P1S:35

Cobalt-58 annual limits on intake PlS:37

INDEX

committed dose equivalent PlS:36 number of transformations P2S:JO

decay scheme PlS:35 specific effective energy P2S:JO

derived air concentrations PlS:37 weighted cmtd. dose equiv. P2S:Jl

number of transformations PlS:36 Copper-61

specific effective energy PlS:34,35 annual limits on intake P2S:75

weighted cmtd. dose equiv. PlS:37 committed dose equivalent P2S:74

Cobalt-60m decay scheme P2S:73

annual limits on intake PlS:39 derived air concentration P2S:75

committed dose equivalent PlS:39 number of transformations P2S:73

decay scheme PlS:38 specific effective energy P2S:73

derived air concentrations PlS:39 weighted cmtd. dose equiv. P2S:74

number of transformations PlS:38 Copper-62

specific effective energy PlS:38; specific effective energy P2S:82

P2s:66 Copper-64

weighted cmtd. dose equiv. PlS:39 annual limits on intake P2S:78

Cobalt-60 committed dose equivalent P2S:77

annual limits on intake PlS:41 decay scheme P2S:J6

committed dose equivalent PlS:40 derived air concerktration P2S:78

decay scheme PlS:39 number of transformations P2S:76

derived air concentrations PlS:41 specific effective energy P2S:76

number of transformations PlS:40 weighted cmtd. dose equiv. P2S:77

specific effective energy PlS:39.58 Copper-66

17

-_ P25:67


Cobalt-61



decay scheme PlS:42

derived air concentrations PlS:43




Cobalt-62m



lecay scheme PlS:43

derived air concentrations PlS:44




Copper








metabolism P2:19

Reference Man data P2:19


Copper-60

annual limits on intake P2S:JZ

committed dose equivalent PZS:71

decay scheme P2S:JO

derived air concentration PZS:72

specific effective energy P3S:89, 91

Copper-67

annual limits on intake PZS:81


decay scheme P2S:J9





Curium


chelated compounds Pl:ll2

classification of isotopes Pl:llZ


distribution and retention Pl:lll

inhalation classes Pl:lll

metabolic data Pl:lll

metabolic model PI.:111

metabolism Pl:lll

uptake to blood P1.:111

Curium-238



decay scheme PlS:4.86




weighted cmtd. dose equiv. PlS:493 Curium-240




derived air concentration Pls:500



specific effective energy PlS:494, Curium- 247 528


annual limits on intake PlS:504 committed dose equivalent P1~:503 decay scheme PlS:501 derived air concentration P1~:504 number of transformations ~1~:503 specific effective energy PlS:501 weighted cmtd. dose equiv. PlS:504

Curium-242

annual limits on intake PlS:519 committed dose equivalent PlS:518 decay scheme PIS:517 derived air concentration PlS:519 number of transformations PlS:518 specific effective energy PlS:517 weighted cmtd. dose equiv. PlS:519

Curium-248

annual limits on intake PlS:507 committed dose equivalent PlS:506 decay scheme PlS:505 derived air concentration P1~:507 number of transformations PlS:506 specific effective energy PlS:458,

462, 505, 533

annual limits on intake Pls:521 committed dose equivalent PlS:521 decay scheme PlS:520 derived air concentration PlS:521 number of transformations PlS:520 specific effective energy PlS:520 weighted cmtd. dose equiv. PlS:521

Curium-249


annual limits on intake PlS:509 committed dose equivalent PlS:509 decay scheme PlS:508 derived air concentration PlS:509 number of transformations PlS:508 specific effective energy PlS:508 weighted cmtd. dose equiv. PlS:509

Curium-244

annual limits on intake Pls:526 committed dose equivalent PlS:525 decay scheme PlS:522 derived air concentration PlS:526 number of transformations PlS:525 specific effective energy PlS:522,

549; P3s:899, 906 weighted cmtd. dose equiv. PlS:526

annual limits on intake PlS:512 committed dose equivalent PlS:511 decay scheme PlS:510 derived air concentration PlS:512 number of transformations P1~:511 specific effective energy PlS:469,

473, 510, 536; P3S:884 weighted cmtd. dose equiv. PlS:511

Curium-245 annual limits on intake PlS:514 committed dose equivalent PlS:514 decay scheme P1~:512 derived air concentration PlS:514 number of transformations PlS:513 specific effective energy PfS:437,

477, 512, 524, 539; P3s:842,854 weighted cmtd. dose equiv. P1S:514

Curium-246 annual limits on intake ~lS:516 committed dose equivalent PlS:516 decay scheme PlS:515 derived air concentration PlS:516 number of transformations PlS:515 specific effective energy ~lS;481,

484, 515, 542; P3s:846, 858,863, 877, 881, 913

Dysprosium annual limits on intake P3:74 chelated compounds P3:73 classification of isotopes P3:74 derived air concentration P3:74 distribution and retention P3:73 inhalation classes P3:73 metabolic data P3:73 metabolic model P3:73 metabolism P3:73 uptake to blood P3:73

Dysprosium-155 annual limits on intake P3S:478 committed dose equivalent P3S:477 decay scheme P3S:476 derived air concentration P3S:478 number of transformations P3S:477 specific effective energy P3S:476,


Dysprosium-157 annual limits on intake P3S:481 committed dose equivalent Pas:480 decay scheme P3S:478

weighted cmtd. dose equiv. Pls:516 derived air concentration P3S:481

INDEX


specific effective energy P3S:478,

490

weighted cmtd. dose equiv. P35:480 Dysprosium-159



decay scheme P3S:481



specific effective energy P35:481,


Dysprosium-165







weighted cmtd. dose equiv. P35:484

Dysprosium-166



decay scheme P35:485





Einsteinium


chelated compounds P3:114







metabolism P3:113


Einsteinium-250








Einsteinium-251


committed dose equivalent


derived air concentration

number of transformations

specific effective energy

19

P3S:870

P3s:870

P3S:869

P3s:868


Einsteinium-253







P3S:871, 888, 899, 905


Einsteinium-254m








Einsteinium-254







912


Erbium



derived air concentration P3:78





metabolism P3:77


Erbium-161








Erbium-165




derived air concentration P3~:515



specific effective energy P3S:513 weighted cmtd. dose equiv. P3S:515

Erbium-169 annual limits on intake P35:517 committed dose equivalent P3S:516 decay scheme P3S:515 derived air concentration P3S:517 number of transformations P3S:516 specific effective energy P3S:515 weighted cmtd. dose equiv. P3S:526

Erbium-171 annual limits on intake P3S:519 committed dose equivalent P3S:518 decay scheme P3S:517 derived air concentration P33:519 number of transformations P3S:518 specific effective energy P3S:517 weighted cmtd. dose equiv. P3S:519

Erbium-172 annual limits on intake P3S:521 committed 'dose equivalent P3S:521 decay scheme P3S:520 derived air concentration P3S:521 number of transformations P3S:520 specific effective energy P3S:520 weighted cmtd. dose equiv. P3~:521

Europium annual limits on intake P3:66 classification of isotopes P3:65 derived air concentration P3:66 distribution and retention P3:64 inhalation classes P3:64 metabolic data P3:64 metabolic model P3:64 metabolism P3:64 uptake to blood P3:64

Europium-145 annual limits on intake P3S:385 committed dose equivalent P3S:384 decay scheme ~3S:382 derived air concentration P3S:385 number of transformations P3S:384 specific effective energy P3S:382,


Europium-146 annual limits on intake P3S:388 committed dose equivalent P3S:387 decay scheme P3S:386 derived air concentration P3S:388 number of transformations P3S:387 specific effective energy P35:386,


Europium-147

committed dose equivalent P3S:390 decay scheme P3S:389 derived air concentration P3S:391 number of transformations P3S:390 specific effective energy P3S:389,


Europium-148 annual limits on intake P3S:394 committed dose equivalent P3S:393 decay scheme P3S:392 derived air concentration P3S:394 number of transformations P3S:393 specific effective energy P3S:392 weighted cm&d. dose equiv. P3S:394

Europium-149 annual limits on intake P3S:396 committed dose equivalent P3S:396 decay scheme P3S:395 derived air concentration P3S:396 number of transformations P3S:395 specific effective energy P3S:395,


Europium-150 (12.62 h) annual limits on intake P3S:338 committed dose equivalent P3S:397 decay scheme P3S:397 derived air concentration P3S:398 number of transformations P3S:397 specific effective energy P35:397 weighted cmtd. dose equiv. P3S:398

Europium-150 (34.2 y) annual limits on intake P3S:401 committed dose equivalent P3S:400 decay scheme P3S:399 derived air concentration P3S:401 number of transformations P3S:400 specific effective energy P3S:399 weighted cmtd. dose equiv. P3S:401

Europium-152m annual limits on intake P3S:403 committed dose equivalent P3S:403 decay scheme P3S:402 derived air concentration P3S:403 number of transformations P3S:402 specific effective energy P3S:402 weighted cmtd. dose equiv. P3S:403

Europium-I52 annual limits on intake P3S:406 committed dose equivalent P3S:405 decay scheme P3S:404 derived air concentration P3S:406 number of transformations P3S:405 specific effective energy P35:404 weighted cmtd. dose equiv. P3S:456 annual limits on intake P3S:391

INDEX 2

Europium-154








&opium-155







409

weighted cmtd. dose equiv. P3S:GlO

Europium-156


committed dose equivalent P3S:411 decay scheme P3S:411




411


Europium-157








Europium-158

annual limits on intake P35:41.5

committed dose equivalent P3S:41.5






Fermium



cisssification of isotopes P3:117





metabolic model P.3:116

metabolism P3:116

uptake to blood P.3:116

Fermium-252





number of transformations P35:885



Fermium-253








Fermium-254








Fermium-255



d;?cay scheme P3S:894





Fermium-257







904


Fluorine


classification of isotopes P2:l



inhalation classes P2:l

metabolic data P2:i

metabolic model P2:l

metabolism P2:l

Reference Man data P2:l

uptake to blood P211


Fluorine-18 annual limits on intake PZS:7 committed dose equivalent PZS:6 decay scheme P2~:5 derived air concentration P2S:7 number of transformations PZS:5 specific effective energy P2S:5 weighted cmtd. dose equiv. P2S:6

Francium annual limits on intake P3:105 classification of isotopes P3:104 derived air concentration P3:105 distribution and retention P3:104 inhalation classes P3:104 metabolic data P3:104 metabolic model P3:104 metabolism P3:104 uptake to blood P3:104

Francium-219 specific effective energy P3S:805

Francium-220 specific effective energy P3S:762,

813 Francium-221

specific effective energy PlS:283, 316, 359; P3s:769

Francium-222 annual limits on intake P3S:752 committed dose equivalent P3S:750 decay scheme P3S:746 derived air concentration P3S:752 number of transformations P3~:750 specific effective energy P3S:746

778 weighted cmtd. dose equiv. P35:751

Francium-223 annual limits on intake P3S:758 committed dose equivalent P3S:756 decay scheme P3S:752 derived air concentration P3S:758 number of transformations P3S:756 specific effective energy PlS:291,

324, 345; P3s:752, 786, 825 weighted cmtd. dose equiv. P3S:757

Francium-254 specific effective energy P3S:876

Gadolinium annual limits on intake P3:69 classification of isotopes P3:68 derived air concentration P3:69

distribution and retention P3:67 inhalation classes P3:67 metabolic data P3:67 metabolic model P3:67 metabolism P3:67 uptake to blood P3:67

Gadolinium-145 annual limits on intake P3S:418 committed dose equivalent P3S:417 decay scheme P3S:416 derived air concentration P3S:418 number of transformations P3S:417 specific effective energy P3S:416 weighted cmtd. dose equiv. P35:418

Gadolinium-146 annual limits on intake P3S:422 committed dose equivalent P3S:421 decay scheme P3S:419 derived air concentration P3S:422 number of transformations P3S:421 specific effective energy P3S:419 weighted cmtd. dose equiv. P3S:422

Gadolinium-147 annual limits on intake P35:427 committed dose equivalent P3S:425 decay scheme P3S:423 derived air concentration P3S:427 number of transformations P3S:425 specific effective energy P3S:423,


Gadolinium-148 annual limits on intake P3S:428 committed dose equivalent P3S:428 decay scheme P3S:427 derived air concentration P3S:428 number of transformations P3S:427 specific effective energy P3S:427 weighted cmtd. dose equiv. P3S:428

Gadolinium-149 annual limits on intake P3S:432 committed dose equivalent P3S:431 decay scheme P3S:429 derived air concentration P3S:432 number of transformations P3S:431 specific effective energy P3S:429,


Gadolinium-151 annual limits on intake P3S:435 committed dose equivalent P3S:434 decay scheme P35:433 derived air concentration P35:435 number of transformations P3S:434 specific effective energy P3S:433,

450

INDEX 23


Gadolinium-152








Gadolinium-153







453


Gadolinium-159








Gallium









metabolism P3:29


Gallium-65



decay scheme P3S:93





Gallium-66



decay scheme P3S:95




109


Gallium-67

annual limits on intake P3S:lOO


decay scheme P3S:98

derived air concentration P3S:lOO



112

weighted cmtd. dose equiv. P3S:lOO

Gallium-68

annual limits on intake P3S:lOZ

committed dose equivalent P3S:lOZ

decay scheme P3S:lOl

derived air concentration P3S:lOZ

number of transformations P3S:lOl

specific effective energy P3S:lOl,

113


Gallium- 70



decay scheme P3S:lO3




weighted comtd. dose equiv. P3S:103

Gallium-72

annual limits on intake P3S:lOC

committed dose equivalent P3~:105



number of transformations P3~:105

specific effective energy P2S:94;

P3S:104


Gallium-73

annual limits on intake ~3S:108


decay scheme P3S:lO7





Germanium








metabolism P3:32


Germanium-66

annual limits on intake P3S:lll

committed dose equivalent P3S:llO


derived air concentration P3s:lll


number of transformations P3S:llO specific effective energy P3S:109 weighted cmtd. dose equiv. P3S:lll

Germanium-67 annual limits on intake P3S:113 committed dose equivalent P3S:llZ decay scheme P3S:lll derived air concentration P3S:113 number of transformations P3~:112 specific effective energy P3S:lll weighted cmtd. dose equiv. P3S:112

Germanium-68 annual limits on intake P3S:116 committed dose equivalent P3S:114 decay scheme P3S:113 derived air concentration P3~:116 number of transformations P3~:114 specific effective energy P3S:113 weighted cmtd. dose equiv. P3S:115

Germanium-69 annual limits on intake P3S:llB committed dose equivalent P3S:117 decay scheme P3S:116 derived air concentration P3S:llB number of transformations P3S:116 specific effective energy P3S:116,


Germanium-71 annual limits on intake P3S:120 committed dose equivalent P3S:119 decay scheme P3S:118 derived air concentration P3S:lZO number of transformations P3~:118 specific effective energy P3S:118,


Germanium-75 annual Limits on intake P3S:121 committed dose equivalent P3S:l21 decay scheme P3S: 120 derived air concentration P3S:l21 number of transformations ~3~~121 specific effective energy P3~:12O weighted cmtd. dose equiv. P3S:121

Germanium-77 annual Limits on intake P3S:124 committed dose equivalent P3S:123 decay scheme P3~:122 derived air concentration P3S:124 number of transformations P3S:123 specific effective energy ~3s:122 weighted cmtd. dose equiv. P3S:l24

Germanium-78 annual Limits on intake P3S:126 committed dose equivalent P3S:125

-RADIONUCLIDES BY WORKERS

decay scheme P35:124 derived air concentration P3S:126 number of transformations P3S:125 specific effective energy P3S:124 weighted cmtd. dose equiv. P3S:126

Gold annual limits on intake P2:58;

~3:124Addendum _-. classification of isotopes P2:57 derived air concentration P2:58;

P3:124Addendum distribution and retention ~2:57 inhalation classes P2:57 metabolic data P2:57 metabolic model P2:57 metabolism P2:57 Reference Man data P2:57 uptake to blood P2:57

Gold-193 annual limits on intake P2S:532;

P3S:926Addendum committed dose equivalent PZS:531;

P3S:925Addendum

decayscheme PZS:530;P3S:923bddendum derived air concentration PZS:532:

P3S:926Addendum number of transformations PZS:531;

P3S:924Addendum specific effective energy PZS:530,

554, 558, 561, 563, 567, 570; P35:923Addendum

weighted cmtd. dose equiv. PZS:532; P3S:926_Addendum

Gold-194 annual limits on intake P2S:535;

P3S:929,Addendum committed dose equivalent PZS:534;

P3S:928Addendum decayscheme P25:533; P3S:927 Addendum derived air concentration P2S:535:

P3 S: 929Addendum --- number of transformations PZS:533;

P3S:927Addendum

specific effective energy ~2S:533, 572, 574, 577; P35:927 Addendum

weighted cmtd. dose equiv. PZS:535; P3S:929 ,&ddendui

Gold-195 annual limits on intake PZS:537;

P3S:932Addendum committed dose equivalent PZS:536;

P3S:93lAddendum decayscheme P2S:536;P3S:930 Addendum derived air concentration PZS:537;

P3S:932Addendum number of transformations P2S:536;

INDEX 25

P3S:930Addendum number of transformations pZS:546;

specific effective energy P2S:536, ~3~~943 Addendum

582, 586, 589, 591, 594, 597, specific effective energy P2S:545;

625; p3S:715, 930Addendum p3S:942Addendum

weighted cmtd. dose equiv. P2S:537; weighted cmtd. dose equiv. P2S:547; p3S:932Addendum p3S:944Addendum

Gold-198m Gold-200 annual limits on intake P2S:540; annual limits on intake P2S:549;

P35:936 Addendum p3Sz947Addendum

committed dose equivalent P25:539; committed dose equivalent P2S:548; p3S:934 Addendum p3S:946 Addendum

decayscheme P2S:538;P3S:933Addendum decay schemepZS:548; P3S:945Addendum

derived air concentration P2S:540; derived air concentration P2S:549; P3S:936Addendum ~3s: 947Addendum

number of transformations pZS:539; number of transformations P2S:548, P3S:934Addendum ~3~~946 Addendum

specific effective energy p2S:538; specific effective energy P2S:545; P3S:933 Addendum 548; ~3.~~707, 942, 945 Addendum

weighted cmtd. dose equiv. P2S:540; weighted cmtd. dose equiv. P2S:549; P3S:935Addendum ~35~946 Addendum --

Gold-198 Gold-201 annual limits on intake PZS:542; annual limits on intake P2S:551;

P3S:938Addendum P3S:948Addendum committed dose equivalent p2S:541; committed dose equivalent p2~:550;

P3S:937Addendum p3S:948 Addendum decay scheme P2S:541;P3S:936Addendum decay schemePZS:>>O; P3S:947Addendum

derived air concentration p2S:542; derived air concentration p2S:551; P3S:938Addendum p3S:948 Addendum

number of transformations p2S:541; number of transformations p2S:550; p3S:937 Addendum p3S:947 Addendum

specific effective energy PZS:541, specific effective energy P2S:550; 538; pS3:933, 936Addendum p3s:947 Addendum

weighted cmtd. dose equiv. p2S:542; weighted cmtd. dose equiv. p2S:551; P35:938 Addendum p3s:948 Addendum

Gold-199

annual limits on intake P2~:544; ~3~:941Addendum

committed dose equivalent p2S:543; P3S:940Addendum

decayscheme P2S:543;P3S:939Addendum

derived air concentration p2S:544; Hafnium P3S:941Addendum annual limits on intake P3:89

number of transformations P2S:S43; classification of isotopes p3:88 P3S:939 Addendum derived air concentration P3:89

specific effective energy p2S:543; distribution and retention P3:88 P35:705, 939Addendum inhalation classes P3:88

weighted cmtd. dose equiv. ~2S:544; metabolic data P3:88 ~3S:941Addendum metabolic model P.3:88

Gold-20Om metabolism P3:88 annual limits on intake p2S:547; uptake to blood P3:88

p3S:945 Addendum Hafnium-170 committed dose equivalent P25:546; annual limits on intake P3S:584

P3S:943Addendum committed dose equivalent P3S:583 decay scheme P2S:545;P3S:942Addendum decay scheme p3S:581 derived air concentration ~2S:547; derived air concentration P3S:584

P3S:945Addendum number of transformations P3S:583


specific effective energy P3S:581 decay scheme P3S:600 weighted cmtd. dose equiv. P3S:584 derived air concentration P3S:602

Hafnium-172 annual limits on intake P3S:587 committed dose equivalent P3S:586 decay scheme P3S:585 derived air concentration P3S:587 number of transformations P3S:585 specific effective energy P3S:585,

618 weighted cmtd. dose equiv. P35:586





Hafnium-177m annual limits on intake P3S:595 committed dose equivalent P3S:594 decay scheme P35:593 derived air concentration P3S:595 number of transformations P35:594 specific effective energy P35:593 weighted cmtd. dose equiv. P3S:595

Hafnium-178m annual limits on intake P3S:597 committed dose equivalent P3S:596 decay scheme P3S:595 derived air concentration P3S:597 number of transformations P3S:596 specific effective energy P3S:595 weighted cmtd. dose equiv. P3S:597


Hafnium-180m annual limits on intake P3S:602 committed dose equivalent P3S:601


Hafnium-181 annual limits on intake P35:604 committed dose equivalent P3S:604 decay scheme P3S:603 derived air concentration P3S:604 number of transformations P3S:603 specific effective energy P3S:603 weighted cmtd. dose equiv. P3S:604


Hafnium-182 annual limits on intake ~3S:611 committed dose equivalent P3S:610 decay scheme P3S:609 derived air concentration P3S:611 number of transformations P3S:609 specific effective energy P3S:606,


Hafnium-183 annual limits on intake P3S:614 committed dose equivalent P3S:613 decay scheme P3S:611 derived air concentration P3S:614 number of transformations ~3~:613 specific effective energy P3S:611 weighted cmtd. dose equiv. P3S:614

Hafnium-184 annual limits on intake P3S:617 committed dose equivalent P3~:616 decay scheme P3S:615 derived air concentration P3S:617 number of transformations P3S:616 specific effective energy P3S:615 weighted cmtd. dose equiv. P3S:617

Holmium annual limits on intake P3:76 classification of isotopes P3:76 derived air concentration P3:76 distribution and retention P3:75 inhalation classes P3:75 metabolic data P3:75 metabolic model P3:75 metabolism P3:75 uptake to blood P3:75

INDEX 27

Holmium-155 specific effective energy P3S:500 annual limits on intake P3S:489 weighted cmtd. dose equiv. P3S:501 committed dose equivalent P3S:489 Holmium-164 decay scheme P3S:487 annual limits on intake P3S:503 derived air concentration P3S:489 committed dose equivalent P3S:502 number of transformations P3S:488 decay scheme P3S:502 specific effective energy P3S:487 derived air concentration P3S:503 weighted cmtd. dose equiv. P3S:489 number of transformations P3S:502

Holmium-157 specific effective energy P3S:500, annual limits on intake P3S:492 502 committed dose equivalent P3S:491 weighted cmtd. dose equiv. P3S:503

decay scheme P3S:490 Holmium-166m

derived air concentration P3S:492 annual limits on intake P35:506

number of transformations P3S:490 committed dose equivalent P3S:505

specific effective energy P3S:490 decay scheme P3S:506

weighted cmtd. dose equiv. P3S:491 derived air concentration P3S:506

Holmium-159 number of transformations P3S:505

annual limits on intake P3S:494 specific effective energy P3S:504

committed dose equivalent P3S:493 weighted cmtd. dose equiv. P3S:506

decay scheme P3S:492 Holmium-166

derived air concentration P3S:494 annual limits on intake P3S:508

number of transformations P3S:493 committed dose equivalent P35:507

specific effective energy P3S:492 decay scheme P3S:506

weighted cmtd. dose equiv. P3S:494 derived air concentration P3S:508 Holmium-161 number of transformations P3S:507

annual limits on intake P3S:496 specific effective energy P3S:485,

committed dose equivalent P3S:495 506

decay scheme P3S:494 weighted cmtd. dose equiv. P3S:507

derived air concentration P3S:496 Holmium-167

number of transformations P3S:495 annual limits on intake P3S:509

specific effective energy P3S:494, committed dose equivalent P3S:509

510 decay scheme P3S:508

weighted cmtd. dose equiv. P3S:495 derived air concentration P3S:509 Holmium-162m number of transformations P3S:508

annual limits on intake P3S:498 specific effective energy P3S:508

committed dose equivalent P3S:497 weighted cmtd. dose equiv. P3S:509 decay scheme P3S:496 Hydrogen derived air concentration P3S:498 annual limits on intake P1:68; Pls:6 number of transformations P3S:497 committed dose equivalent PlS:5

specific effective energy P3S:496 decay scheme PlS:5

weighted cmtd. dose equiv. P3S:498 derived air concentration P1:68; Holmium-162 Pls:6

annual limits on intake P3S:499 dose equivalent rate PlS:5 committed dose equivalent P3S:499 elemental tritium P1:65 decay scheme P3S:498 metabolic data Pl:65 derived air concentration P3S:499 metabolic models P1:65

number of transformations P3S:499 metabolism P1:65

specific effective energy P3'S:496, number of transformations PlS:5 498 organic compounds P1:66

weighted cmtd. dose equiv. P3S:499 Reference Man data P1:65 Holmium-164m specific effective energy PlS:5

annual limits on intake P3S:501 tritiated water P1:65 committed dose equivalent P3S:501 weighted cmtd. dose equiv. PlS:5, 6 decay scheme P3S:500 Indium derived air concentration P3S:501 annual limits on intake P2:46 number of transformations P3S:500 classification of isotopes P2:45

28 LIMITS FOR INTAKES OF RADIONLJCLIDES BY WORKERS

specific effective energy PZS:335; P3s:189

weighted cmtd. dose equiv. PZS:337 Indium-114m

annual limits on intake PZS:341 committed dose equivalent PZS:340 decay scheme PZS:338 derived air concentration PZS:341 number of transformations P2~:340 specific effective energy PZS:338 weighted cmtd. dose equiv. PZS:341

Indium-114 specific effective energy PZS:339

Indium-115m annual limits on intake PZS\:343 committed dose equivalent PZS:342 decay scheme PZS:341 derived air concentration PZS:343 number of transformations PZS:342 specific effective energy PZS:288,

308, 341 weighted cmtd. dose equiv. PZS:343

Indium-115 annual limits on intake PZS:345 committed dose equivalent PZS:344 decay scheme PZS:343 derived air concentration PZS:345 number of transformations PZS:344 specific effective energy P7S:343 weighted cmtd. dose equiv. PZS:344

Indium-116m annual limits on intake PZS:347 committed dose equivalent PZS:346 decay scheme PZS:345 derived air concentration PZS:347 number of transformations PZS:346 specific effective energy PZS:345 weighted cmtd. dose equiv. PZS:347

Indium-117m annual limits on intake PZS:349 committed dose equivalent PZS:348 decay scheme PZS:347 derived air concentration P25:349 number of transformations PZS:348 specific effective energy PZS:312,

317, 347 weighted comtd. dose equiv. PZS:349

Indium-117 annual limits on intake PZS:351 committed dose equivalent PZS:350 decay scheme PZS:350 derived air concentration PZS:351 number of transformations PZS:350 specific effective energy PZS:312,

318, 348, 350 weighted cmtd. dose equiv. PZS:351

derived air concentration P2:46 distribution and retention P2:45 inhalation classes P2:45 metabolic data P2:45 metabolic model P2:45 metabolism P2:45 uptake to blood P2:45

Indium-109 annual limits on intake P2S:325 committed dose equivalent PZS:324 decay scheme PZS:322 derived air concentration PZS:325 number of transformations PZS:324 specific effective energy PZS:322 weighted cmtd. dose equiv. PZS:325

Indium-110 specific effective energy P3S:183

Indium-110 (69.lm) annual limits on intake PZS:327 committed dose equivalent PZS:326 decay scheme PZS:326 derived air concentration PZS:327 number of transformations PZS:326 specific effective energy PZS:326 weighted cmtd. dose equiv. PZS:327

Indium-110 (4.9h) annual limits on intake P25:330 committed dose equivalent P2S:329 decay scheme P2S:328 derived air concentration PZS:330 number of transformations PZS:329 specific effective energy PZS:328 weighted cmtd. dose equiv. PZS:330

Indium-111 annual limits on intake PZS:333 committed dose equivalent PZS:332 decay scheme PZS:331 derived air concentration PZS:333 number of transformations P25:332 specific effective energy PZS:331;

P3s:186 weighted cmtd. dose equiv. PZS:333

Indium-112 annual limits on intake PZS:335 committed dose equivalent PZS:334 decay scheme PZS:334 derived air concentration PZS:335 number of transformations PZS:334 specific effective energy P2S:334 weighted cmtd. dose equiv. PZS:335

Indium-113m annual limits on intake PZS:337 committed dose equivalent PZS:336 decay scheme PZS:335 derived air concentration P25:337 number of transformations PZS:336

INDEX 29

Indium-119m








Indium-119


Iodine

annual limits on intake P1:89, 90

behaviour of daught'ers P1:88


derived air concentration P1:89, 90


half-life P3:123Addendum




metabolism P1:88



Iodine-120m








Iodine-120








Iodine-121








Iodine-123








Iodine-124








Iodine-125








Iodine-126








Iodine-128








Iodine-129








Iodine-130








Iodine-131







181, 204; P3S:271



Iodine-132m annual limits on intake PlS:207 committed dose equivalent PlS:206 decay scheme PlS:205 derived air concentration PlS:207 number of transformations PlS:206 specific effective energy PlS:205 weighted cmtd. dose equiv. PlS:206

Iodine-132 annual limits on intake PlS:208 committed dose equivalent PlS:207 decay scheme PlS:207 derived air concentration PlS:208 number of transformations PlS:207 specific effective energy PlS:183,

206, 207 weighted cmtd. dose equiv. PlS:208





Iodine-135 annual limits on intake Plf:212 committed dose equivalent PlS:211 decay scheme PlS:211' derived air concentration PlS:212 number of transformations PlS:211 specific effective energy PlS:211 weighted cmtd. dose equiv. PlS:211

Iridium annual limits on intake P2:56 classification of isotopes P2:55 derived air concentration P2:56 distribution and retention P2:54 inhalation classes P2:54 metabolic data P2:54 metabolic model P2:54 metabolism P2:54 uptake to blood P2:54

Iridium-182 annual limits on intake P2S:481 committed dose equivalent P2S:480


decay scheme P2S:479 derived air concentration P2S:481 number of transformations P2S:480 specific effective energy P2S:479 weighted cmtd. dose P2S:481

Iridium-184 annual limits on intake P2S:484 committed dose equivalent P2S:482 decay scheme P2S:482 derived air concentration P2S:484 number of transformations P2S:482 specific effective energy P2S:482 weighted cmtd. dose equiv. P2S:483

Iridium-185 annual limits on intake P2S:489 committed dose equivalent P2S:487 decay scheme P25:484 derived air concentration P2S:489 number of transformations P2S:486 specific effective energy P2S:484 weighted cmtd. dose equiv. P2S:488

Iridium-186 annual limits on intake P2S:491 committed dose equivalent P2S:490 decay scheme P2S:489 derived air concentration P2S:491 number of transformations P2S:490 specific effective energy P2S:489;


Iridium-187 annual limits on intake P2S:494 committed dose equivalent P2S:493 decay scheme P2S:492 derived air concentration P2S:494 number of transformations P2S:493 specific effective energy P2S:492 weighted cmtd. dose equiv. P2S:494


P3s:681 weigh'ted cmtd. dose equiv. P2S:497



I NDF.X 3

specific effective energy PZS:525 weighted cmtd. dose equiv. P2S:527

Iridium-195






specific effecrive energy P2:525,

528

weighted cmtd. dose equiv. PZS:529

Iron








metabolism P2:17



Iron-52



decay scheme P2S:57



specific effective energy PZS:57


iron-55



decay scheme P2S:60




P2S:60


Iron-59



decay scheme P25:63



specific effective energy P2~:63


Iron-60



decay scheme P2S:66





Iridium-190m








Iridium-190






specific effective energy PZS:504,

508


Iridium-192m

annual limits on intake P2~:515







Iridium-192






specific effective PZS:512, 516


Iridium-194m








Iridium-194



decay scheme PZS:522


number of transformations PZS:523


522


Iridium-195m







Krypton derived air concentration P1:76;

P2:Addendum dose equivalent rate P1:48

Krypton-74 decay scheme PlS:45 derived air concentration PIS:47 dose equivalent rate PlS:45 specific effective energy PlS:45 weighted dose equiv. rate PlS:46

Krypton-76 decay scheme PlS:47 derived air concentration PlS:49 dose equivalent rate PlS:47 specific effective energy PlS:47 weighted dose equiv. rate PlS:48

Krypton-77 decay scheme PlS:49 derived air concentration PlS:50 dose equivalent rate PlS:49 specific effective energy PlS:49 weighted dose equiv. rate PlS:5fl

Krypton-79 decay scheme PlS:51 derived air concentration PlS:52 dose equivalent rate P1~:51 specific effective energy PlS:51 weighted dose equiv. rate PlS:52

Krypton-81 decay scheme PlS:52 derived air concentration PlS:54;

P2:Addendum dose equivalent rate PlS:53 specific effective energy PlS:52 weighted dose equiv. rate PlS:54

Krypton-83m decay scheme PlS:54 derived air concentration PlS:55;

P2:Addendum dose equivalent rate ~1~:55 specific effective energy PlS:54;

P2S:112, 123; P3s:164 weighted dose equiv. rate PlS:55

Krypton-85m decay scheme Pls:56 derived air concentration PlS:58 dose equivalent rate PlS:56 specific effective energy PlS:56 weighted dose equiv. rate P1S:57

Krypton-85 decay scheme PlS:58 derived air concentration ~lS:60 dose equivalent rate PlS:58 specific effective energy PlS:58 weighted dose equiv. rate PlS:59

Krypton-87

decay scheme PlS:60 derived air concentration ~lS:62 dose equivalent rate P1~:60 specific effective energy PlS:60 weighted dose equiv. rate PlS:61

Krypton-88 decay scheme PlS:62 derived air concentration PlS:64 dose equivalent rate PlS:62 specific effective energy PlS:62 weighted dose equiv. rate PlS:63

Lanthanum annual limits on intake P3:52 chelated compounds P3:51 classification of isotopes P3:51 derived air concentration P3:52 distribution and retention P3:50 inhalation classes P3:50 metabolic data P3:50 metabolic model P3:50 metabolism P3:50 uptake to blood P3:50

Lanthanum- 131 annual limits on intake P3S:277 committed dose equivalent P3S:276 decay scheme P3S:273 derived air concentration P3S:277 number of transformations P3S:275 specific effective energy P3S:273 weighted cmtd. dose equiv. P3~:276

Lanthanum-132 annual limits on intake P3S:279 committed dose equivalent P3S:278 decay scheme P3S:277 derived air concentration P3S:279 number of transformations P3S:278 specific effective energy P3S:277 weighted cmtd. dose equiv. P3S:279

Lanthanum-134 specific effective energy PlS:240

Lanthanum-135 annual limits on intake P3S:282 committed dose equivalent P3S:281 decay scheme P3S:280 derived air concentration P3S:282 number of transformations P3S:281 specific effective energy PlS:242;


Lanthanum-137 annual limits on intake P3S:285 committed dose equivalent P35:284

INDEX




specific effective energy P3s:283


Lanthanum-138 annual limits on intake P3S:288







Lanthanum-140







P3s:289


Lanthanum-141







P3S:292


Lanthanum-142

annual limits on intake P3s:2gfj



number of transformations P3S:295 specific effective energy P2S:406;

P35:294


Lanthanum-143







weighted cmtd. dose equiv.P3S:298 Lead








33

metabolism P2:64



Lead-195m








Lead-198








Lead-199








Lead-200







675


Lead-201







P2s:640, 678


Lead-202m







weighted cmtd. dose equiv. P2S:648 Lead-202


34 LIMITS FOR INTAKES OF RAiiIO?I;CLIDES BY WORKERS

committed dose equivalent P2S:650 decay scheme P2S:665 decay scheme P2S:649 derived air concentration P2S:670 derived air concentration P2S:651 number of transformations P2S:668 number of transformations P2S:650 specific effective energy PlS:279, specific effective energy PlS:259; 298, 312, 332, 354, 399, 497,

P2S:645, 649 529; P2s:665, 708, 726, 733; weighted cmtd. dose equiv. P2S:651 P3s:761, 797, 812, 830

Lead-203 weighted comtd. dose equiv. P2S:669 annual limits on intake P2S:654 Lead-214 committed dose equivalent P2S:653 annual limits on intake P2S:674 decay scheme P2S:652 committed dose equivalent P2S:674 derived air concentration P2S:654 decay scheme P2S:670 number of transformations P2S:653 derived air concentration P2S:674 specific effective energy P2S:652, number of transformations P2S:673

685; P3s:739 specific effective energy PlS:287, weighted cmtd. dose equiv. P2S:654 320; P2S:670; P3s:777

Lead-205 weighted cmtd. dose equiv. P2S:674 annual limits on intake P2S:656 Lutetium committed dose equivalent P2S:655 annual limits on intake P3:87 decay scheme P2S:655 classification of isotopes P3:86 derived air concentration P2S:656 derived air concentration P3:87 number of transformations P2S:655 distribution and retention P3:85 specific effective energy P2S:655 inhalation classes P3:85 weighted cmtd. dose equiv. P2S:656 metabolic data P3:85

Lead-209 metabolic model P3:85 annual limits on intake P2S:659 metabolism P3:85 committed dose equivalent P2S:658 uptake to blood P3:85 decay scheme P2S:657 Lutetium-169 derived air concentration P2S:659 annual limits on intake P3S:554 number of transformations PZS:657 committed dose equivalent P3S:553 specific effective energy PlS:317; decay scheme P3S:552

P2s:657, 702; P3S:771 derived air concentration P3S:554 weighted comtd. dose equiv. P2S:658 number of transformations P3S:553

Lead-210 specific effective energy P3S:552 annual limits on intake P2S:661 weighted cmtd. dose equiv. P3S:554 committed dose equivalent P2S:660 Lutetium-170 decay scheme P2S:659 annual limits on intake P3S:557 derived air concentration P2S:661 committed dose equivalent P3S:556 number of transformations P25:660 decay scheme P3S:555 specific effective energy PlS:288, derived air concentration P3S:557

303, 321, 340, 390, 49O;P2s:659, number of transformations P35:555 671; P3.5:748;780;820

weighted cmtd. dose equiv. P2~:661 Lead-211

annual limits on intake P2S:664 committed dose equivalent PZS:663 decay scheme P2S:661 derived air concentration P25:664 number of transformations P2S:663 specific effective energy PlS:275,

293, 307, 326, 347; P2s:661; P3S:754, 788, 806, 826

weighted cmtd. dose equiv. P2S:664 Lead-212

annual limits on intake P2S:670 committed dose equivalent P25:669


weighted cmtd. dose equiv. P3S:556 Lutetium-171


Lutetium-172 annual limits on intake P3S:561 committed dose equivalent P3S:560 decay scheme P3S:559

INDEX 35

derived air concentration P3S:561 number of transformations P3S:560 specific effective energy P3S:559,


Lutetium-173 annual limits on intake P3S:563 committed dose equivalent P3S:562 decay scheme P3S:561 derived air concentration P3S:563 number of transformations P3S:562 specific effective energy P3S:561,

588, 621

Lu t etium-174m annual limits on intake P3S:565 committed dose equivalent P3S:564 decay scheme ~3~:563 derived air concentration P3S:565 number of transformations P3S:564 specific effective energy P3S:563


annual limits on intake P3S:575 committed dose equivalent P3S:574 decay scheme P3S:573 derived air concentration P3S:575 number of transformations P3S:574 specific effective energy P3S:548,


Lutetium-178m


Lutetium-178 annual limits on intake P3S:578





derived air concentration P3S:576 number of transformations P3S:575

derived air concentration P3S:578 weighted cmtd. dose equiv. P3S:565

Lutetium-174 number of transformations P3S:577 specific effective energy P3S:550,



Lutetium-179


Lutetium-176m annual limits on intake P3S:568 committed dose equivalent P3S:568 decay scheme ~3S:567 derived air concentration P3S:568 number of transformations P3S:567 specific effective energy P3S:567 weighted cmtd. dose equiv. P3S:568

Lutetium-176


annual limits on intake P3S:570 committed dose equivalent P3S:570 decay scheme ~3S:569 derived air concentration P3S:570 number of transformations P3S:569 specific effective energy P3S:569 weighted cmtd. dose equiv. P3S:570

Lutetium-177m annual limits on intake P3S:573 committed dose equivalent P3S:572 decay scheme P3S:571 derived air concentration P3S:573 number of transformations P3S:572 specific effective energy P3S:571 weighted cmtd. dose equiv. P3S:573

Lutetium-177

Magnesium

annual limits on intake P3:ll classification of isotopes P3:li derived air concentration P3:ll distribution and retention P3:lO inhalation classes P3:lO metabolic data P3:lO metabolic model P3:lO metabolism P3:lO Reference Man data P3:lO uptake to blood P3:lO

Magnesium-28 annual limits on intake P3S:27 committed dose equivalent P3S:26 decay scheme P3S:24 derived air concentration P3S:27 number of transformations P3S:26

specific effective energy P3S:24 weighted cmtd. dose equiv. P3~:27

Manganese annual limits on intake P1:72 classification of isotopes Pl:72 derived air concentration P1:72 distribution and retention P1:71 inhalation classes P1:71 metabolic data P1:71 metabolic model P1:71 metabolism P1:71 Reference Man data P1:71 uptake to blood P1:71

Manganese-51 annual limits on intake PlS:13 committed dose equivalent PlS:13 decay scheme PlS:12 derived air concentration PlS:13 number of transformations PlS:l2 specific effective energy PlS:12 weighted cmtd. dose equiv. PlS:13

Manganese-52m annual limits on intake PlS:15 committed dose equivalent PlS:15 decay scheme PlS:14 derived air concentration PlS:15 number of transformations PlS:l4 specific effective energy PlS:14;


Manganese-52 annual limits on intake PlS:18 committed dose equivalent PlS:17 decay scheme Pls:16 derived air concentration PlS:18 number of transformations PlS:17 specific effective energy PlS:14,


Manganese-53 annual limits on intake PlS:21 committed dose equivalent PlS:20 decay scheme PlS:19 derived air concentration PlS:21 number of transformations PlS:20 specific effective energy PlS:19 weighted cmtd. dose equiv. PlS:21

Manganese-54 annual limits on intake PlS:24 committed dose equivalent PlS:23 decay scheme PlS:22


Mendelevium annual limits on intake P3:119 chelated compounds P3:118 classification of isotopes P3:118 derived air concentration P3:119 distribution and retention P3:118 inhalation classes P3:118 metabolic data P3:118 metabolic model P3:118 metabolism P3:118 uptake to blood P3:118

Mendelevium-257 annual limits on intake P3S:910 committed dose equivalent P3S:909 decay scheme P3S:903 derived air concentration P3S:910 number of transformations P3S:908 specific effective energy P3S:903 weighted cmtd. dose equiv. P3S:910

Mendelevium-258 annual limits on intake P3S:915 committed dose equivalent P3S:914 decay scheme P3S:911 derived air concentration P3S:915 number of transformations P3S:913 specific effective energy P3S:912 weighted cmtd. dose equiv. P3S:915

Mercury annual limits on intake P2:62,63 classification of isotopes P2:61 derived air concentration P2:62,

63 distribution and retention P2:60, 61 inhalation classes P2:59, 60 inorganic compounds P2:59, 63 metabolic data P2:59 metabolic model P2:59 metabolism P2:59 organic compounds P2:60, 62 Reference Man data P2:59 uptake to blood P2:59, 60 vapours P2:63

Mercury-193m (inorganic) annual limits on intake P2S:560 committed dose equivalent P2S:559 decay scheme P2S:552 derived air concentration P2S:560 number of transformations P2S:558 soecific effective enerev P25:557

derived air concentration PlS:24 number of transformations PlS:23 specific effective energy Pls:22 weighted cmtd. dose equiv. PlS:24

Manganese-56


INDEX 37


Mercury-193m (organic)








Mercury-193m (vapour)








Mercury-193 (inorganic)







567


Mercury-193 (organic)







562


Mercury-193 (vapour)







570


Mercury-194 (inorganic)




derived air concentration P2S:5?7



weighted cmtd. dose equiv. PZS:576 Mercury-194 (organic)








Mercury-194 (vapour)








Mercury-195m


Mercury-195m (inorganic)






specific effective energy P25:585


Mercury-195m (organic)







weighted cmtd. do.se equiv. PZS:584

Mercury-1Y5m (vapour)








Mercury-195



P3S:714

Mercury-195 (inorganCc>







594


Mercury-195 (organic:)



decay scheme P2S:SYO



number of transformations PZS:592 number of transformations PZS:606 specific effective energy P2~:581, specific effective energy PZS:599,

590 605 weighted cmtd. dose equiv. PZS:593 weighted comtd. dose equiv. PZS:607

Mercury-195 (vapour) 1 qercury-197 (vapour) annual limits on intake PZS:598 annual limits on intake PZS:611 committed dose equivalent PZS:597 committed dose equivalent PZS:611 decay scheme PZS:590 decay scheme PZS:605 derived air concentration PZS:598 derived air concentration PZS:611 number of transformations PZS:597 number of transformations PZS:610 specific effective energy PZS:588, specific effective energy PZS:604,

597 610 weighted cmtd. dose equiv. PZS:597

Mercury-197m decay scheme PZS:598

Mercury-197m (inorganic) annual limits on intake PZS:604 committed dose equivalent PZS:603 decay scheme PZS:598 derived air concentration PZS:604 number of transformations PZS:602 specific effective energy P2~:601 weighted cmtd. dose equiv. PZS:603

Mercury-197m (organic) annual limits on intake PZS:601 committed dose equivalent PZS:600 decay scheme PZS:598 derived air concentration PZS:601 number of transformations P2~:600 specific effective energy PZS:598 weighted cmtd. dose equiv. PZS:601

Mercury-197m (vapour) annual limits on intake PZS:605 committed dose equivalent PZS:604 decay scheme PZS:598 derived air concentration PZS:605 number of transformations PZS:604 specific effective energy PZS:604 weighted cmtd. dose equiv. PZS:605

Mercury-197 decay scheme PZS:605 specific effective energy P3S:717

Mercury-197 (inorganic) annual limits on intake PZS:610 committed dose equivalent PZS:609 decay scheme PZS:605 derived air concentration PZS:610 number of transformations PZS:608 specific effective energy PZS:602,

608 weighted cmtd. dose equiv. PZS:609

Mercury-197 (organic) annual limits on intake PZS:608 committed dose equivalent PZS:607 decay scheme PZS:605 derived air concentration P2S:608

weighted cmtd. dose equiv. PZS:611 Mercury-199m

decay scheme PZS:611 Mercury-199m (inorganic)

annual limits on intake PZS:614 committed dose equivalent PZS:614 decay scheme PZS:611 derived air concentration PZS:614 number of transformations PZS:613 specific effective energy PZS:613 weighted cmtd. dose equiv. PZS:614

Mercury-199m (organic) annual limits on intake PZS:613 committed dose equivalent PZS:612 decay scheme PZS:611 derived air concentration PZS:613 number of transformations PZS:612 specific effective energy PZS:611 weighted cmtd. dose equiv. PZS:612

Mercury-199m (vapour) annual limits on intake PZS:615 committed dose equivalent PZS:615 decay scheme PZS:611 derived air concentration P2~:615 number of transformations PZS:615 specific effective energy PZS:615 weighted cmtd. dose equiv. P2S:615

Mercury-203 decay scheme P2S:616

Mercury-203 (inorganic) annual limits on intake PZS:620 committed dose equivalent PZS:619 decay scheme PZS:616 derived air concentration PZS:620 number of transformations PZS:619 specific effective energy PZS:618 weighted cmtd. dose equiv. ~2~:620

Mercury-203 (organic) annual limits on intake PZS:618 committed dose equivalent PZS:617 decay scheme PZS:616 derived air concentration PZS:618 number of transformations PZS:616 specific effective energy PZS:616

INDEX 39

weighted cmtd. dose equiv. PZS:617 Mercury-203 (vapour)

annual limits on intake P2S:622 committed dose equivalent P2S:621 decay scheme P2S:616 derived air concentration P2S:622 number of transformations P2S:621 specific effective energy PZS:620 weighted cmtd. dose equiv. P2S:622

Molybdenum annual limits on intake P1:84 classification of isotopes P1:83 derived air concentration P1:84 distribution and retention P1:83 inhalation classes P1:83 metabolic data P1:83 metabolic model P1:83 metabolism P1:83 Reference Man data P1:83 uptake to blood P1:83

Molybdenum-90 annual limits on intake PlS:141 committed dose equivalent PlS:139 decay scheme PlS:137 derived air concentration PlS:141 number of transformations PlS:138 specific effective energy PlS:137 weighted cmtd. dose equiv. PlS:140

Molybdenum-93m annual limits on intake PlS:144 committed dose equivalent PlS:143 decay scheme PlS:141 derived air concentration PlS:144 number of transformations PlS:142 specific effective energy PlS:141 weighted cmtd. dose equiv. PlS:144

Molybdenum-93 annual limits on intake PlS:148:

I

P3:122Addendum committed dose equivalent PlS:147 decay scheme PlS:145 derived air concentration PlS:148;

P3:122 Addendum half-life P3:122Addendum number of transformations PlS:147 specific effective energy PlS:145 weighted cmtd. dose equiv. PlS:148

Molybdenum-99 annual limits on intake PlS:154 committed dose equivalent PlS:153 decay scheme PlS:l49 derived air concentration PlS:154 number of transformations PlS:152 specific effective energy PlS:149 weighted cmtd. dose equiv. PlS:154

Molybdenum-101


Neodymium annual limits on intake P3:57 classification of isotopes P3:56 derived air concentration P3:57 distribution and retention P3:56 inhalation classes P3:56 metabolic data P3:56 metabolic model P3:56 metabolism P3:56 uptake to blood P3:56

Neodymium-136 annual limits on intake P3S:320 committed dose equivalent P3S:319 decay scheme P3S:318 derived air concentration P3S:320 number of transformations P3S:319 specific effective energy P3S:318 weighted cmtd. dose equiv. P3S:320

Neodymium-138 annual limits on intake P3S:322 committed dose equivalent P3S:321 decay scheme P3~:320 derived air concentration P3S:322 number of transformations P3S:321 specific effective energy P3S:320 weighted cmtd. dose equiv. P3S:322

Neodymium-139m annual limits on intake P3S:326 committed dose equivalent P3S:325 decay scheme P3S:323 derived air concentration P3S:326 number of transformations P3S:324 specific effective energy P3S:323 weighted cmtd. dose equiv. P3S:325

Neodymium-139 annual limits on intake P3S:328 committed dose equivalent P3S:328 decay scheme P3S:326 derived air concentration P3S:328 number of transformations P3S:327 specific effective energy P3S:323,



Neodymium-141m annual limits on intake P2~:714 committed dose equivalent P2S:713 decay scheme P2S:712 derived air concentration ~2S:714 number of transformations P2S:713 specific effective energy ~2S:712 weighted cmtd. dose equiv. P2S:714

Neptunium-234 annual limits on intake P25:718 committed dose equivalent P2S:717 decay scheme P2S:715 derived air concentration P2S:718 number of transformations P2S:717 specific effective energy PlS:387,

487; P2s:715 weighted cmtd. dose equiv. P2S:718

Neptunium-235 annual limits on intake P2S:721 committed dose equivalent P2S:721 decay scheme P2S:719 derived air concentration P2S:721 number of transformations P2S:720 specific effective energy PlS:393;

P2S:719

specific effective energy P3S:338, 363, 366

Neodymium-141 annual limits on intake P3S:330 committed dose equivalent P3S:329 decay scheme P3S:329 derived air concentration P35:330 number of transformations P3S:329 specific effective energy P3S:329,

338, 363, 367 weighted cmtd. dose equiv. P3S:330

Neodymium-147 annual limits on intake P3S:332 committed dose equivalent P3S:332 decay scheme P3S:331 derived air concentration P3S:332 number of transformations P3S:331 specific effective energy P3S:315,


Neodymium-149 annual limits on intake P3S:335 committed dose equivalent P3S:334 decay scheme P35:333 derived air concentration P3S:335 number of transformations P3S:333 specific effective energy P3S:333 weighted cmtd. dose equiv. P3S:334

Neodymium-151 annual limits on intake P3S:337 committed dose equivalent P3S:336 decay scheme P35:335 derived air concentration P35:337 number of transformations P3S:336 specific effective energy P3S:335 weighted cmtd. dose equiv. P3S:336

Neptunium annual limits on intake P2:71 classification of isotopes P2:70 derived air concentration P2:71 distribution and retention P2:69 inhalation classes P2:69 metabolic data P2:69 metabolic model P2:69 metabolism P2:69 uptake to blood P2:69

Neptunium-232 annual limits on intake P2S:711 committed dose equivalent P2S:711 decay scheme P2S:706 derived air concentration P2S:711 number of transformations P2S:709 specific effective energy P2S:706 weighted cmtd. dose equiv. P2S:711

Neptunium-233 number of transformations P25:741

weighted cmtd. dose equiv. P2S:721 Neptunium-236 (22.5h)

annual limits on intake P2S:736 committed dose equivalent P2S:736 decay scheme P2S:729 derived air concentration ~2S:736 number of transformations P2S:734 specific effective energy P2S:729 weighted cmtd. dose equiv. P2S:736

Neptunium-236 (1.15~105~) annual limits on intake P2S:728 committed dose equivalent P2S:728 decay scheme P2S:722 derived air concentration P2S:728 number of transformations P2S:726 specific effective energy P2S:722 weighted cmtd. dose equiv. P2S:728

Neptunium-237 annual limits on intake P2S:739 committed dose equivalent P2S:739 decay scheme P2S:737 derived air concentration P2S:739 number of transformations P2S:738 specific effective energy PlS:441;


Neptunium-238 annual limits on intake P2~:743 committed dose equivalent P2S:742 decay scheme P2S:740 derived air concentration P2S:743

INDEX 4

specific effective energy PlS:458; number of transformations P3S:71 PZS:740 specific effective energy P3S:70

weighted cmtd. dose equiv. P2S:743 weight cmtd. dose equiv. P3S:72 Neptunium-239 Nickel-57 (vapour state)

annual limits on intake PZS:747 annual limits on intake P3S:75

committed dose equivalent PZS:746 committed dose equivalent P3S:74 decay scheme PZS:744 derived air concentration P3S:75 derived air concentration P2S:747 number of transformations P3S:74 number of transformations PZS:745 specific effective energy P3S:73

specific effective energy PlS:380, weighted cmtd. dose equiv. P3S:74

427, 466; PZS:744 Nickel-59

weighted cmtd. dose equiv. PZS:746 decay scheme P3S:75

Neptunium-24Cm Nickel-59 (inorganic)

specific effective energy PlS:383, annual limits on intake P3S:77

431 committed dose equivalent P3S:76

Neptunium-240 derived air concentration P3S:77 annual limits on intake P25:751 number of transformations P3.9~76 committed dose equivalent P2S:750 specific effective energy P3S:75

decay scheme PZS:748 weighted cmtd. dose equiv. P3S:77 derived air concentration P2S:751 Nickel-59 (vapour state)

number of transformations P2S:749 annual limits on intake P3S:80

specific effective energy P2S:748 committed dose equivalent P3S:79 weighted cmtd. dose equiv. PZS:751 derived air concentration P3S:80

Nickel number of transformations P3S:78

annual limits on intake P3:27, 28 specific effective energy P3S:78

classification of isotopes P3:26 weighted cmtd. dose equiv. P3S:79 derived air concentration P3:27, 28 Nickel-63





metabolism P3:25


uptake to blood ~3:25

Nickel-56

decay scheme P3S:64

Nickel-56 (inorganic)







Nickel-56 (vapour state)


committed dose equivalent P3S:'68





Nickel-57

decay scheme P3S:70





decay scheme P3S:80















Nickel-65

decay scheme P3S:85















Nickel-66 decay scheme P3S:88

Nickel-66 (inorganic) annual limits on intake P3S:90 committed dose equivalent P3S:90 derived air concentration P3S:90 number of transformations P3S:89 specific effective energy P3S:88 weighted cmtd. dose equiv. P3S:90

Nickel-66 (vapour state) annual limits on intake P3S:92 committed dose equivalent P3S:92 derived air concentration P3S:92 number of transformations P3S:91 specific effective energy P3S:91 weighted cmtd. dose equiv. P3S:92

Niobium annual limits on intake P1:82 classification of isotopes P1:82 derived air concentration P1:82 distribution and retention P1:81 inhalation classes P1:81 metabolic data P1:81 metabolic model P1:81 metabolism P1:81 Reference Man data P1:81 uptake to blood P1:81

Niobium-88 annual limits on intake PlS:116 committed dose equivalent PlS:116 decay scheme PlS:115 derived air concentration P1.S:116 number of transformations PlS:116 specific effective energy PlS:115 weighted cmtd. dose equiv. PlS:116

Niobium-89 (66 min) annual Limits on intake ~1~:118 committed dose equivalent PlS:l18 decay scheme PlS:ll7 derived air concentration PlS:l18 number of transformations PlS:l17 specific effective energy PlS:l17 weighted cmtd. dose equiv. PlS:118

Niobium-89 (122 min) annual limits on intake PlS:120 committed dose equivalent PlS:120 decay scheme PlS:119 derived air concentration PlS:l20 number of transformations PlS:l19 specific effective energy PlS:ll9 weighted cmtd. dose equiv. PlS:120

Niobium-90 annual limits on intake PlS:122

decay scheme PlS:lZl derived air concentration number of transformations specific effective energy

138

PlS:122 PlS:lZl PlS:lZl,

weighted cmtd. dose equlv. PlS:122 Niobium-93m

annual limits on intake PlS:124; ~3~122; P3S:920 Addendum

committed dose equivalent PlS:123; p3S:920Addendum

decay scheme ~1~:123; P3S:919 derived air concentration PlS:124;

P3:122;_P3S:920 number of transformations PlS:123;

P3S:920 specific effective energy PlS:105,

123, 146: P3s:919 weighted cmtd. dose equiv. PlS:124;

P3S:920 Niobium-94

annual limits on intake PlS:126 committed dose equivalent PlS:126 decay scheme PlS:125 derived air concentration PlS:126 number of transformations PlS:125 specific effective energy PlS:125 weighted cmtd. dose equiv. Pls:126

Niobium-95m annual limits on intake PlS:128 committed dose equivalent PlS:127 decay scheme P1~:127 derived air concentration PlS:128 number of transformations PlS:127 specific effective energy PlS:108,

127; PZS:162 weighted cmtd. dose equiv. P1~:128

Niobium-95 annual limits on intake PlS:130 committed dose equivalent PlS:129 decay scheme PlS:128 derived air concentration PlS:130 number of transformations PlS:129 specific effective energy PlS:lOB,

127, 128; PZs:163 weighted cmtd. dose equiv. PlS:30

Niobium-96 annual limits on intake PlS:l33 committed dose equivalent PlS:132 decay scheme PlS:131 derived air concentrations PlS:133 number of transformations PlS:132 specific effective energy PlS:131 weighted cmtd. dose equiv. PlS:133

Niobium-97m committed dose equivalent PlS:121 specific effective energy PlS:lll

Niobium-97 annual limits on intake PlS:135 committed dose equivalent PlS:134 decay scheme PlS:133 derived air concentrations PlS:135 number of transformations PlS:134 specific effective energy PlS:112,


Niobium-98 annual limits on intake PlS:136 committed dose equivalent PlS:136 decay scheme PlS:135 derived air concentrations PlS:136 number of transformations PlS:135 specific effective energy PlS:135 weighted cmtd. dose equiv. PlS:136

Noble gases derived air concentration P1:lO dose equivalent rate P1:48

Osmium annual limits on intake P2:53 classification of isotopes P2:52 derived air concentrations P2:53 distribution and retention P2:52 inhalation classes P2:52 metabolic data P2:52 metabolic model P2:52 metabolism P2:52 uptake to blood P2:52

Osmium-180 annual limits on intake P2S:448 committed dose equivalent P25:447 decay scheme P2S:446 derived air concentration P2S:448 number of transformations P25:447 specific effective energy P25:446 weighted cmtd. dose equiv. P2S:448

Osmium-181 annual limits on intake P2S:454 committed dose equivalent P2S:452 decay scheme P2S:449 derived air concentration P2S:454 number of transformations P2S:452 specific effective energy P2S:449 weighted cmtd. dose equiv. PZS:453

Osmium-182 annual limits on intake P2S:459 committed dose equivalent P2S:457 decav scheme P2S:455

INDEX 43

derived air concentration P2S:459 number of transformations P2S:457,

479 specific effective energy P2S:455 weighted cmtd. dose equiv. P2S:458

Osmium-185 annual limits on intake P2S:463 committed dose equivalent PZS:461 decay scheme P2S:460 derived air concentration P2S:463 number of transformations P2S:461 specific effective energy P2S:460,


Osmium-189m annual limits on intake P2S:465 committed dose equivalent P2S:464 decay scheme P25:464 derived air concentration P2S:465 number of transformations P2S:464 specific effective energy P2S:444,

464, 499; P3S:686 weighted cmtd. dose equiv. P2S:465

Osmium-191m annual limits on intake P25:469 committed dose equivalent P2S:468 decay scheme P2S:466 derived air concentration P2S:469 number of transformations P2S:468 specific effective energy P2S:466 weighted cmtd. dose equiv. P2S:469

Osmium-191 annual limits on intake P2S:472 committed dose equivalent P2S:471 decay scheme P2S:470 derived air concentration P29:472 number of transformations PZS:470 specific effective energy P2S:467,


Osmium-193 annual limits on intake P2S:475 committed dose equivalent P2S:474 decay scheme P2S:473 derived air concentration P2~:475 number of transformations P2S:474 specific effective energy P2S:473 weighted cmtd. dose equiv. P2S:475

Osmium-194 annual limits on intake P2S:478 committed dose equivalent P2S:477 decay scheme P2S:476 derived air concentration P2S:478 number of transformations P2S:477 specific effective energy P2S:476 weighted cmtd. dose equiv. P2S:478


Palladium annual limits on intake P3:42 classification of isotopes P3:42 derived air concentration P3:42 distribution and retention P3:41 inhalation classes ~3:41 metabolic data P3:41 metabolic model P3:41 metabolism P3:41 uptake to blood P3:41

Palladium-100 annual limits on intake P3S:70 committed dose equivalent P3S:168 decay scheme P3S:166 derived air concentration P3S:170 number of transformations P3S:168 specific effective energy P3S:166 weighted cmtd. dose equiv. P3S:169

Palladium-101 annual limits on intake P3S:175 committed dose equivalent P3S:174 decay scheme P3S:170 derived air concentration P3S:175 number of transformations P3S:173 specific effective energy P3S:170 weighted cmtd. dose equiv. P35:175

Palladium-103 annual limits on intake P3S:178 committed dose equivalent P3S:177 decay scheme P3S:176 derived air concentration P3S:178 number of transformations P3S:176 specific effective energy P2S:256;

P3S:176 weighted cmtd. dose P3S:l77

Palladium-107 annual limits on intake P3S:180 committed dose equivalent P3S:179 decay scheme P3S:178 derived air concentration P3S:180 number of transformations P3S:179 specific effective energy P3S:178 weighted cmtd. dose equiv. P3S:179

Palladium-109 annual limits on intake P3S:182 committed dose equivalent P3S:181 decay scheme P3S:180 derived air concentration P3S:182 number of transformations P3S:181 specific,effective energy P3S:180 weighted cmtd. dose equiv. P3S:182

Phosphorus annual limits on intake P1:70 classification of isotopes P1:70 derived air concentration P1:70 distribution and retention P1:69

RADIONLJCLIDES BY WORKERS

inhalation classes P1:69 metabolic data P1:69 metabolic model PI:69 metabolism P1:69 Reference Man data P1:69 uptake to blood P1:69

Phosphorus-J2 annual limits on intake PlS:9 committed dose equivalent PlS:8 decay scheme PlS:7 derived air concentration PlS:9 number of transformations PlS:7 specific effective energy PlS:7;


Phosphorus-33 annual limits on intake PlS:ll committed dose equivalent PlS:lO decay scheme PlS:9 derived air concentration PlS:ll number of transformations PlS:lO specific effective energy PlS:9 weighted cmtd. dose equiv. PlS:ll

Platinum annual limits on intake P3:98 classification of isotopes P3:97 derived air concentration P3:98 distribution and retention P3:96 inhalation classes P3:96 metabolic data P3:96 metabolic model P3:96 metabolism P3:96 uptake to blood P3:96

Platinum-186 annual limits on intake P3S:679 committed dose equivalent P3S:678 decay scheme P3S:676 derived air concentration P3S:679 number of transformations P3S:678 specific effective energy P35:676 weighted cmtd. dose equiv. P3S:679

Platinum-188 annual limits on intake P3S:683 committed dose equivalent P3S:682 decay scheme P3S:680 derived air concentration P3S:683 number of transformations P3S:682 specific effective energy P3S:680 weighted cmtd. dose equiv. P3S:683

Piatinum-189 annual limits on intake P3S:689 committed dose equivalent P3S:687 decay scheme P3S:684 derived air concentration P3S:689 number of transformations P3S:687 specific effective energy P3S:684

INDEX 45


Platinum-191








Platinum-193m








Platinum-193







564, 568; P3s:694, 924


Platinum-195m








Platinum-197m


commited dose equivalent P3S:701






Platinum-197


committed dose equivalent P35:703





703


Platinum199








Platinum-200







Plutonium




derived air concentration PI:107

distribution and retention Pl:lO5




metabolism P1:105


Plutonium-234







488


Plutonium-235








Plutonium-236







495, 528; P2S:724, 731


Plutonium-237






specific effective energy PlS:405, 440



Plutonium-238 Plutonium-244 annual limits on intake PlS:412 annual limits on intake Pls:435 committed dose equivalent PlS:410 committed dose equivalent ~1~:433 decay scheme PlS:409 decay scheme PlS:430 derived air concentration PlS:412 derived air concentration PlS:435 number of transformations PlS:410 number of transformations PlS:432 specific effective energy PlS:409,

444,458, 462, 487, 488, 506, 534; specific effective energy PlS:430 weighted cmtd. dose equiv. PlS:434

P25:741 Plutonium-245 weighted cmtd. dose equiv. PlS:411

Plutonium-239 annual limits on intake PlS:439 committed dose equivalent PlS:438

annual limits on intake PlS:416 decay scheme PlS:436 committed dose equivalent PlS:414 derived air concentration PlS:439 decay scheme PlS:413 number of transformations ~1~:437 derived air concentration PlS:416 specific effective energy PlS:436 number of transformations PlS:414 weighted cmtd. dose equiv. PlS:438 specific effective energy PlS:380, Polonium

413, 448; P2s:745 annual limits on intake P1:97 weighted cmtd. dose equiv. PlS:415

Plutonium-240 classification of isotopes P1:97 derived air concentration P1:97

annual limits on intake PlS:420 distribution and retention P1:96 committed dose equivalent PlS:418 inhalation classes P1:96 decay scheme PlS:417 metabolic data P1:96 derived air concentration PlS:420 metabolic model P1:96 number of transformations PlS:418 metabolism P1:96 specific effective energy PlS:384, Reference Man data P1:96

417, 432, 452, 469, 473, 510,537 uptake to blood P1:96 P2S:749 Polonium-203

weighted cmtd. dose equiv. PlS:419 Plutonium-241

annual limits on intake PlS:263 committed dose equivalent PlS:261

annual limits on intake PlS:422 decay scheme PlS:258 committed dose equivalent PlS:421 derived air concentration PlS:263 decay scheme PlS:420 number of transformations PlS:260 derived air concentration PlS:422 specific effective energy PlS:258 number of transformations PlS:421 weighted cmtd. dose equiv. PlS:262 specific effective energy PlS:420, Polonium-205

477, 513 annual limits on intake PlS:268 weighted cmtd. dose equiv. PlS:422

Plutonium-242 committed dose equivalent PlS:266 decay scheme PlS:263

annual limits on intake PlS:425 derived air concentration PlS:268 committed dose equivalent PlS:424 number of transformations PlS:265 decay scheme PlS:423 specific effective energy PlS:263 derived air concentration PlS:425. weighted cmtd. dose equiv. PlS:267 number of transformations, PlS:424 Polonium-207 specific effective energy PlS:423,

458, 462 annual limits on intake PlS:271 committed dose equivalent PlS:270

weighted cmtd. dose equiv. PlS:425 decay scheme PlS:268 Plutonium-243 derived air concentration PlS:271

annual limits on intake PlS:429 number of transformations PlS:270 committed dose equivalent FlS:428 decay scheme PlS:426

specific effective energy PlS:268; P3S:738

derived air concentration PlS:429 weighted cmtd. dose equiv. PlS:271 number of transformations PlS:428 Polonium-210 specific effective energy PlS:426,

517 annual limits on intake PlS:273 committed dose equivalent PlS:272

weighted cmtd. dose equiv. PlS:429 decay scheme PlS:272

INDEX 47

derived air concentration PlS:273 decay scheme P2S:31 number of transformations PlS:272 derived air concentration P2S:33 specific effective energy PlS:272, number of transformations P2S:32

288, 304, 321, 340, 390, 491; specific effective energy P2S:31 P2s:659, 672, 697; P3S:749, 781, weighted cmtd. dose equiv. P2S:32 821 Potassium-43

weighted cmtd. dose equiv. PlS:273 annual limits on intake ~2~:35 Polonium-211 committed dose equivalent P2S:34

specific effective energy PlS:275, decay scheme P2S:33 308, 327; ~2s:662; P3S:742 derived air concentration P2S:35

Polonium-212 number of transformations P2S:34 specific effective energy PlS:280, specific effective energy P2S:33

298, 312, 332, 354, 400, 497,530; weighted cmtd. dose equiv. P2S:35 P2s:666, 699, 709, 726, 733; Potassium-44 P3S:763, 799, 814, 831 annual limits on intake P2S:36

Polonium-213 committed dose equivalent PZS:36 specific effective energy PlS:284, decay scheme P29:35

316, 360; PZs:701; P3S:770 derived air concentration P2S:36 Polonium-214 number of transformations P2S:36

specific effective energy PlS:287, specific effective energy P2S:35 303, 321, 339, 389, 49O;PZs:671, weighted cmtd. dose equiv. P2S:36 704; P3S:748, 780, 820 Potassium-45

Polonium-215 annual limits on intake P2S:38 specific effective energy PlS:275, committed dose equivalent P2S:37

292, 307, 326, 347; P38:754,788, decay scheme P2S:37 806, 826 derived air concentration P2S:38

Polonium-216 number of transformations P2S:37 specific effective energy PlS:279, specific effective energy P2S:37

297, 311, 331, 353, 399, 496,529; weighted cmtd. dose equiv. P2S:38 P2s:708, 725, 733; P38:761,796, Praseodymium 812, 830 annual limits on intake P3:55

Polonium-218 classification of isotopes P3:54 specific effective energy PlS:286, derived air concentration P3:55

320; P3S:776 Potassium

annual limits on intake P2:12 classification of isotopes P2:ll derived air concentration P2:12 distribution and retention P2:ll inhalation classes P2:ll metabolic data P2:ll metabolic model P2:ll metabolism P2:ll Reference Man data P2:ll uptake to blood P2:ll

Potassium-40 annual limits on intake P2S:31 committed dose equivalent P2S:30 decay scheme P2S:29 derived air concentration P2S:31 number of transformations P2S:29 specific effective energy P2S:29 weighted cmtd. dose equiv. PZS:30

Potassium-42 annual limits on intake P25:33 committed dose equivalent P2S:32

distribution and retention P3:53 inhalation classes P3:53 metabolic data P3:53 metabolic model P3:53 metabolism P3:53 uptake to blood P3:53

Praseodymium-136 annual limits on intake P3S:300 committed dose equivalent P3S:299 decay scheme P3S:299 derived air concentration P3S:300 number of transformations P3S:299 specific effective energy P3S:299,


Praseodymium-137 annual limits on intake P3S:302 committed dose equivalent P3S:301 decay scheme P3S:300 derived air concentration P35:302 number of transformations P3S:301 specific effective energy P3S:300 weighted cmtd. dose equiv. P35:302


Praseodymium-138m annual limits on intake P3S:305 committed dose equivalent P3S:304 decay scheme P3S:303 derived air concentration P3S:.305 number of transformations P3S:303 specific effective energy P3S:303 weighted cmtd. dose equiv. P3S:304

Praseodymium-138 specific effective energy P3S:321



Praseodymium-142m annual limits on intake P3S:309 committed dose equivalent P3S:309 decay scheme P3S:308 derived air concentration P3S:309 number of transformations P3S:308 specific effective energy P3S:308 weighted cmtd. dose equiv. P3S:309



Praseodymium-143 annual limits on intake P3S:312 committed dose equivalent P3S:312 decay scheme P3S:311 derived air concentration P3~:312 number of transformations P3S:311 specific effective energy PlS:253;

P3s:297, 311 weighted cmtd. dose equiv. P3S:312

Praseodymium-144m specific effective energy PlS:255

Praseodymium-144 annual limits on intake P3S:313 committed dose equivalent P3S:313 decay scheme P3S:312 derived air concentration P3~:313 number of transformations ~3~:313 specific effective energy Pl~:255;


Praseodymium-145 annual limits on intake P3S:315 committed dose equivalent P3S:314 decay scheme P3S:314 derived air concentration P3S:315 number of transformations P3S:314 specific effective energy P3S:314 weighted cmtd. dose equiv. P3S:315

Praseodymium-147 annual limits on intake P3S:316 committed dose equivalent P3S:316 decay scheme P35:315 derived air concentration P3S:316 number of transformations P3S:316 specific effective energy P3S:315 weighted cmtd. dose equiv. P3S:316

Proctactinium annual limits on intake P3:llO classification of isotopes P3:iUY derived air concentration P3:llO distribution and retention P3:108 inhalation classes P3:108 metabolic data P3:108 metabolic model P3:108 metabolism P3:108 uptake to blood P3:108

Proctactinium-227 annual limits on intake P3S:809 committed dose equivalent P3S:808 decay scheme P3S:804 derived air concentration P3S:809 number of transformations P3S:807 specific effective energy P3S:804 weighted cmtd. dose equiv. P3S:809

Proctactinium-228 annual limits on intake P3S:817 committed dose equivalent P3S:816 decay scheme P3S:810 derived air concentration P3S:817 number of transformations P3S:814 specific effective energy P3S:810 weighted cmtd. dose equiv. P3S:816

Proctactinium-230 annual limits on intake P3S:823 committed dose equivalent P3S:822 decay scheme P3S:818 derived air concentration P35:823 number of transformations P3S:821 specific effective energy P3S:818 weighted cmtd. dose equiv. P3S:823

Proctactinium-231 annual limits on intake P3S:828 committed dose equivalent P3S:827 decay scheme P3S:824 derived air concentration P3S:828 number of transformations P3S:826

INDEX 49


344; P3s:824


Proctactinium-232








Proctactinium-233






specific effective energy PZS:738;

P3S:835


Proctactinium-234m


Proctactinium-234







377; P3S:838


Proctactinium-376


Promethium








metabolism P3:58


Promethium-141







363, 366

weighted cmtd. dose equiv. P3S:339 Promethium-142


Promethium-143



decay scheme P3S1340





Promethium-144








Promethium-145







370, 383


Promethium-146



decay scheme P3S:.348





Promethium-147







331, 350

weighted cmtd. dose equiv. P3S:351 Promethium-148m







weighted cmtd. dose equiv. P3S:354 Promethium-148








weighted cmtd. dose equiv. P3S:355 292, 306, 325, 346; P3S:753,787,

Promethium-149 806, 825

annual limits on intake P3S:357 weighted cmtd. dose equiv. plS:277 committed dose equivalent P3S:356 Radium-224 decay scheme P3S:356 annual limits on intake PlS:282 derived air concentration P3S:357 committed dose equivalent PlS:281 number of transformations P3S:356 decay scheme PlS:278 specific effective energy P3S:333, derived air concentration PlS:282

356 number of transformations PlS:280 weighted cmtd. dose equiv. P3S:357 specific effective energy PlS:278,

i-'romethium-150 297, 311, 331, 353, 398, 496,529; annual limits on intake P3S:359 PZS:70?, 725, 732; P3S:760, 794, committed dose equivalent P3S:358 811, 829 decay scheme P3S:357 weighted cmtd. dose equiv. PlS:282 derived air concentration P3S:359 Radium-225 number of transformations P3S:358 annual limits on intake PlS:285 specific effective energy P3S:357 committed dose equivalent PlS:285 weighted cmtd. dose equiv. P3S:358 decay scheme PlS:282

Promethium-151 derived air concentration PlS:285 annual limits on intake P3S:361 number of transformations PlS:284 committed dose equivalent P3S:360 specific effective energy PlS:282, decay scheme P3S:359 315, 359 derived air concentration P3S:361 weighted cmtd. dose equiv. PlS:285 number of transformations P3S:3%0 Radium-226 specific effective energy P35:335, annual limits on intake PlS:290

359 committed dose equivalent PlS:289 weighted cmtd. dose equiv. P3S:360 decay scheme PlS:286

derived air concentration PlS:290 number of transformations PlS:288 specific effective energy PlS:286,

319; P3S:775 weighted cmtd. dose equiv. PlS:290

Radium-227 annual limits on intake PlS:295

Radium committed dose equivalent PlS:295 annual limits on intake P1:99 decay scheme PlS:290 behaviour of daughters P1:98 derived air concentration PlS:295 classification of isotopes P1:99 number of transformations PlS:293 derived air concentration P1:99 distribution and retention P1:98


inhalation classes ~1:98 Radium-228 metabolic data P1:98 annual limits on intake PlS:301 metabolic model P1:98 committed dose equivalent PlS:300 metabolism P1:98 decay scheme PlS:296 Reference Man data P1:98 derived air concentration PlS:301 uptake to blood P1:98 number of transformations PlS:299

Radium-222 specific effective energy PlS:296, specific effective energy PlS:302, 330; P2S:724, 731

339, 389, 489; P3s:747, 779,819 weighted cmtd. dose equiv. PlS:300 Radium-223 Radon-218

annual limits on intake PlS:278 specific effective energy PlS:303, committed dose equivalent PlS:277 339, 389, 489; P3S:747, 779,820 decay scheme PlS:274 Radon-219 derived air concentration PlS:278 specific effective energy PlS:292, number of transformations PlS:276 307, 325, 346; P3S:753, 787,806, specific effective energy PlS:274, 825

INDEX 51

Radon -220 specific effective energy P2S:456, specific effective energy PlS:297, 479

311, 331, 353, 398, 496; PZs:708, Rhenium-182 (12.7h)

725, 732; P3s:760, 795, 812,830 annual limits on intake P2S:424 Radon-222 committed dose equivalent P2S:423

specific effective energy PiS:286, decay scheme P2S:422 319; P3S:775 derived air concentration P2S:424

Radon-223 number of transformations P2S:423 specific effective energy PlS:274 specific effective energy P2S:422

Rhenium weighted cmtd. dose equiv. PZS:424 annual limits on intake P2:51 Rhenium-182 (64.0h) classification of isotopes P2:50 annual limits on intake PZS:422 derived air concentration P2:51 committed dose equivalent P2S:420 distribution and retention P2:50 decay scheme P2S:419 inhalation classes P2:50 derived air concentration P2S:422 metabolic data P2:50 number of transformations P2S:420 metabolic model P2:50 specific effective energy P2S:419 metabolism P2:50 weighted cmtd. dose equiv. P2S:421 uptake to blood P2:50 Rhenium-184m

Rhenium-177 annual limits on intake P25:428 annual limits on intake P2S:411 committed dose equivalent P2S:427 committed dose equivalent P2S:410 decay scheme ~2~:~+25 decay scheme P2S:408 derived air concentration P25:428 derived air concentration P2S:411 number of transformations P2S:427 number of transformations P2S:410 specific effective energy PZS:425 specific effective energy P2S:408 weighted cmtd. dose equiv. P2S:428 weighted cmtd. dose equiv. P2S:411 Rhenium-184

Rhenium-178 annual limits on intake P2S:432

a.lnual limits on intake P2S:414; committed dose equivalent P2S:430

P3:123,124 Addendum; P3S:923 decay scheme P2S:429

Addendum derived air concentration P2S:432

committed dose equivalent P2S:413: number of transformations P25:430

P3S:922 Addendum specific effective energy P25:426,

"ecay scheme P2S:412 429

c'erived air concentration P2S:414: weighted cmtd. dose equiv. P2S:431

P3:123,124 Addendum; P3S:923 ’ Rhenium-186m

Addendum annual limits on intake P25:434

number of transformations P2S:413: committed dose equivalent P2S:433 1

P35:922Addendum decay scheme P2S:432

specific effective energy P2S:412; derived air concentration P2S:434

P3S:921Addendum number of transformations P2S:433

weighted cmtd. dose equiv. P2S:414; specific effective energy P2S:432

P3S:923 Addendum weighted cmtd. dose equiv. P2S:433

Rhenium-186 Rhenium-180 annual limits on intake P2S:435

specific effective energy P2S:446 committed dose equivalent P2S:435 Rhenium-181 decay scheme P2S:434

annual limits on intake P2S:418 derived air concentration P2S:435 committed dose equivalent P2S:417 number of transformations P2S:434 decay scheme P2S:415 specific effective energy P2S:432, derived air concentration P2S:418 434 number of transformations P2S:417 weighted cmtd. dose equiv. P2S:435 specific effective energy P2S:415, Rhenium-187

450 annual limits on intake P2S:437 weighted cmtd. dose equiv. P2S:418 committed dose equivalent P2S:436

Rhenium-182 decay scheme PZS:436


derived air concentration P2S:437 annual limits on intake P2S:227 number of transformations P2S:436 committed dose equivalent P2S:225 specific effective energy P2S:436 decay scheme P2S:224 weighted cmtd. dose equiv. P25:437 derived air concentration P2S:227

Rhenium-188m number of transformations PZS:224 annual limits on intake P2S:440 specific effective energy P2S:224; committed dose equivalent PZS:439 P3S:167 decay scheme P2S:438 weighted cmtd. dose equiv. P2S:226 derived air concentration P2S:440 Rhodium-1Olm number of transformations P2S:439 annual limits on intake P2S:231 specific effective energy P2S:438 committed dose equivalent P2S:229 weighted cmtd. dose equiv. P25:440 decay scheme P2S:228

Rhenium-188 derived air concentration P2S:231 annual limits on intake P2S:443 number of transformations P2S:229 committed dose equivalent P2S:442 specific effective energy P2S:228; decay scheme PZS:441 P3S:171 derived air concentration P2S:443 weighted cmtd. dose equiv. P2S:230 number of transformations P2S:442 Rhodium-101 specific effective energy P2S:438, annual limits on intake P2S:235

441; P3s:672 committed dose equivalent P2S:233 weighted cmtd. dose equiv. P2S:443 decay scheme P2S:232

Rhenium-189 derived air concentration P2S:235 annual limits on intake P2S:445 number of transformations P2S:232 committed dose equivalent P2S:445 specific effective energy P2S:228, decay scheme PZS:443 232; P3s:172 derived air concentration P2S:445 weighted cmtd. dose equiv. P25:234 number of transformations P2S:444 Rhodium-102m specific effective energy P2S:443 annual limits on intake P2S:239 weighted cmtd. dose equiv. P2S:445 committed dose equivalent P2S:237

Rhodium decay scheme P2~:236 annual limits on intake P2:38 derived air concentration P2S:239 classification of isotopes P2:37 number of transformations P2S:237 derived air concentration P2:38 specific effective energy P2S:236 distribution and retention P2:37 weighted cmtd. dose equiv. P2S:238

inhalation classes P2:37 Rhodium-102

metabolic data P2:37 annual limits on intake P2S:243

metabolic model P2:37 committed dose equivalent P2S:241

metabolism P2:37 decay scheme P2S:240

uptake to blood P2:37 derived air concentration PZS:243

Rhodium-9%n number of transformations P25:240

annual limits on intake P2S:220 specific effective energy P2S:236,

committed dose equivalent P2S:218 240

decay scheme P2S:217 weighted cmtd. dose equiv. P2S:242

derived air concentration P25:220 Rhodium_lO3m number of transformations P2S:217 annual limits on intake P2S:245 specific effective energy P2S:217 committed dose equivalent P2S:244 weighted cmtd. dose equiv. P2S:219 decay scheme P2S:244

Rhodium-99 derived air concentration P2S:245 annual limits on intake P2S:223 number of transformations P2S:244 committed dose equivalent P2S:222 specific effective energy P2S:206, decay scheme P2S:221 244, 257; P3S:176 derived air concentration P2S:223 weighted cmtd. dose equiv. PZS:245 number of transformations P2S:221 Rhodium-105 specific effective energy P2S:221 annual limits on intake P2S:248 weighted cmtd. dose equiv. P2S:222 committed dose equivalent P25:247

Rhodium-100 decay scheme P2S:246

INDEX 53




246


Rhodium-106m








Rhodium-106


Rhodium-107








Rubidium


behaviour of daughters P2:27







metabolism P2:27



Rubidium-79








Rubidium-80


Rubidium-81m

annual limits on intake P2S:llB







Rubidium-81



decay scheme P2S:llB




118

weighted cmtd. dose equiv. P2S:lZO

Rubidium-82m



decay scheme P2S:lZO


number of transformations P2S:lZl

specific effective energy P2S:lZO


Rubidium-83



decay scheme P2S:lZZ





Rubidium-84

annual limits on intake P2S:lZB







Rubidium-86




derived air conce.Ttration PZS:130



weighted cmtd. dose equiv. P2S:L30

Rubidium-87



decay scheme P2~:131





Rubidium-88







weighted cmtd. dose equiv. P2S:134 Rubidium-89



committed dose equivalent PZS:135 decay scheme P2S:135 derived air concentration P2S:136 number of transformations P2S:135 specific effective energy P2S:135 weighted cmtd. dose equiv. P2S:136

Ruthenium annual limits on intake P2:36 classification of isotopes P2:36 derived air concentration P2:36 distribution and retention P2:35 inhalation classes P2:35 metabolic data P2:35 metabolic model P2:35 metabolism P2:35 uptake to blood P2:35

Ruthenium-94 annual limits on intake P2S:201 committed dose equivalent P2S:200 decay scheme P2S:199 derived air concentration P2S:201 number of transformations P2S:200 specific effective energy P2S:199 weighted cmtd. dose equiv. P2S:201




Ruthenium-106 annual limits on intake P2S:216 committed dose equivalent P2S:214 decay scheme P2S:213

derived air concentration P2S:216 number of transformations P2S:216 specific effective energy P2S:213 weighted cmtd. dose equiv. P2S:215

Ruthenium-220 specific effective energy PlS:278

Samarium annual limits on intake P3:63 chelated compounds P3:61 classification of isotopes P3:63 derived air concentration P3:63 distribution and retention P3:61 inhalation classes P3:61 metabolic data P3:61 metabolic model P3:61 metabolism P3:61 uptake to blood P3:61

Samarium-141m annual limits on intake P3S:365 committed dose equivalent P3S:364 decay scheme P3S:362 derived air concentration P3S:365 number of transformations P3S:364 specific effective energy P3S:362 weighted cmtd. dose equiv. P3S:365

Samarium,141 annual limits on intake P3S:368 committed dose equivalent P3S:367 decay scheme P3S:366 derived air concentration P3S:368 number of transformations P3S:367 specific effective energy P3S:362,


Samarium-142 annual limits on intake P3S:370 committed dose equivalent P3S:369 decay scheme P3S:368 derived air concentration P3S:370 number of transformations P3S:369 specific effective energy P3S:368

weighted cmtd. dose equiv. P3S:369 Samarium-145


383, 417 weighted cmtd. dose equiv. P35:372

Samarium-146 annual limits on intake P3S:373 committed dose equivalent P3S:373 decay scheme P3S:372

INDEX 55




wei,ghted cmtd. dose equiv. P3S:373

Samarium-147








Samarium-151

annual limits on intake P3S:3 7

committed dose equivalent P3S


derived air concentration P3S

number of transformations P3S

specific effective energy P3S

375

7

376

377

376

359,


Semarium-153








Samarium-155








Samarium-156

annual limits on intnke P3S:381






weighted cmtd dose equiv. P3S:381

Scandium

annual limits on intake P3:19 * chelated compounds P3:18



distribution 2nd retention P3:17




metabolism P3:17


Scandium-43



decay scheme P3S:38



specific effective energy P35:38


Scandium-44m



decay scheme P3S:40





Scandium-44



decay scheme P3S:42


numb-r of transformations P3S:42


42, 51


Scandium-46

annual limits on -intake P3S:45


decay scheme P3S:43





Scandium-47 annual limits on intake P3S:46


decay scheme P3S:45




P3S:45


Scandium-48



decay scheme P3S:46




weighted cmtd. dose equiv. P3S:47 Scandium-49



decay scheme P3S:48

nerived air concentration P3S:49




Selenium annual limits on intake P3:40 classification of isotopes P3:39 derived air concentration P3:40 distribution and retention P3:38 inhalation classes P3:38 metabolic data P3:38 metabolic model P3:38 metabolism P3:38 Reference Man data P3:38 uptake to blood P3:38

Selenium- 70 annual limits on intake P3S:146 committed dose equivalent P3S:145 decay scheme P3S:144 derived air concentration P3S:146 number of transformations P3S:144 specific effective energy P3S:144 weighted cmtd. dose equiv. P3S:145

Selenium-73m annual 1Smits on intake P3S:149 committed dose equivalent P3S:149 decay scheme P3S:146 derived air concentration P3S:149 number of transformations P3S:148 specific effective energy P3S:146 weighted cmtd. dose equiv. P3S:149

Selenium-73 annual limits on intake P3S:153 committed dose equivalent P3S:152 decay scheme P3S:150 derived air concentration P3S:154 number of transformations P3S:152 specific effective energy P35:147,


Selenium-75 annual limits on intake P35:156 committed dose equivalent P3S:155 decay scheme P3S:154 derived air concentration P3S:156 number of transformations P3S:155 specific effective energy P2S:lOO;


Selenium-79 annual limits on intake P3S:159 committed dose equivalent P3S:158 decay scheme P3S:157 derived air concentration P3S:159 number of transformations P3S:1.58 specific effective energy P3S:157 weighted cmtd. dose equiv. P3S:159

Selenium-8lm

annual limits on intr'ce P3~:161 committed dose equivalent ~3~:161 decay scheme P3S:160 derived air concentration ~3~:161 number 02 transfum~~ions P3S:160 speciric effectiiie energy P3S:160 weighted cmtd. dose equiv. P3S:161

Selenium-81 annual limits on intake P3~:163 committed dose equivalent ~3~:162 decay scheme P3S:162 derived air concentration ~3S:163 number of transformations ~3~:162 specific effective energy ~3~:160,

162 weighted cmtd. dose equiv. ~3S:162

Selenium-83 annual limits on intake P3~:165 committed dose equivalent P3~:165 decay scheme ~3~:163 derived air concentration P3S:165 number of transformations P35:164 specific effective energy P3S:163 weighted cmtd. dose equiv. ~3S:165

Silicon annual limits on intake P3:16 classification of isotopes P3:15 derived air concentration P3:16 distribution and retention P3:15 inhalation classes P3:14 metabolic data P3:14 metabolic model P3:14 metabolism P3:14 Reference Man data P3:14 uptake to blood P3:14

Silicon-31 annual limits on intake P3S:33 committed dose equivalent P3S:32 decay scheme P3S:31 derived air concentration P3S:33 number of transformations P3S:31. specific effective energy P3S:31 weighted cmtd. dose equiv. ~3S:32

Silicon-32 annual limits on intake P3S:3? committed dose equivalent P3S:35 decay scheme P35:33 derived air concentration P3S:37 number of transformations P3S:34 specific effective energy P3S:33 weighted cmtd. dose equiv. P35:36

Silver annual limits on intake P2:41 classification of isotopes P2:40 derived air concentration ~2:41 distribution and retention P2:39

INDEX >




metabolism P2:39



Silver-102


committed aose equivalent PZS:254






Silver-i03

annuai limits on intake P2S:259


deca, scheme P2S:256





Silver-3.04m

annual limits on intake P2~:262







Silver-104







263, 292

weighted cmtd. dose equiv. P25:265 Silver-105







weighted cmtd. dose equiv. P2S:267 Silver-106m







weighted cmtd. dose equiv. PZS:271 Silver-106








Silver-108m


committ?,l dose equivalent P2S:275


derivec, air concentration P2S:277


specific effective energy P2S:27L


Silver-108


Silver-1lOm








Silver-110


Silver-111








Silver-112






specific effective energy P2S:284 weiohted cmtd. dose equiv. P2S:285

Silver-115








Sodium annual limits on intake P2:4




weighted cmtd. dose equiv. PlS:68 Strontium-83

annual limits on intake PlS:73 committed dose equivalent PlS:71 decay scheme PlS:69 derived air concentration PlS:73 number of transformations PlS:70 specific effective energy PlS:69,


Strontium-85m annual limits on intake PlS:76 committed dose equivalent PlS:75 decay scheme PlS:73 derived air concentration PlS:76 number of transformations PlS:75 specific effective energy PlS:73 weighted comtd. dose equiv. PlS:76

Strontium-85 annual limits on intake PlS:79 committed dose equivalent PlS:78 decay scheme PlS:77 derived air concentration PlS:79 number of transformations PlS:77 specific effective energy PlS:74,

77


inhalation classes P2:3 metabolic data P2:3 metabolic model P2:3 metabolism P2:3 Reference Man data P2:3 uptake to blood P2:3

Sodium-22 annual limits on intake P2S:lO committed dose equivalent P2S:9 decay scheme P2S:8 derived air concentration P2S:lO number of transformations P2S:8 specific effective energy P2S:8 weighted cmtd. dose equiv. P2S:9

Sodium-24 annual limits on intake P2S:12 committed dose equivalent P2S:ll decay scheme P2S:lO derived air concentration P2S:12 number of transformations P2S:ll specific effective energy P2S:lO weighted cmtd. dose equiv. P2S:12

Strontium annual limits on intake Pl:78 classification of isotopes Pl:77 derived air concentration Pl:78 distribution and retention Pl:77 inhalation classes P1:77 metabolic data P1:77 metabolic model P1:77 metabolism PI:77 Reference Man data P1:77 uptake to blood P1:77

Strontium-80 annual limits on intake PlS:66;

P3:121,122 Addendum;P3S:919. Addendum

committed dose equivalent PlS:66: P3S:918 Addendum

decayscheme PlS:65;P3S:917Addendum derived air concentration PlS:66;

P3:121,122 Addendum; P3S:919 Addendum

number of transformations PlS:65: P3S:918Addendum

SDecific effective enersv PlS:65: P3S:917Addendum I*

weiehted cmtd. dose eauiv. PlS:66: ;3S:919 Addendum f

Strontium-81 annual limits on intake PlS:69 committed dose equivalent PlS:68 decay scheme PlS:67 derived air concentration PlS:69 number of transformations PlS:67 _ specitic effective energy PlS:67 committed dose equivalent PlS:88

weighted cmtd. dose equiv. PlS:78 Strontium-87m

annual limits on intake PlS:81 committed dose equivalent PlS:80 decay scheme PlS:79 derived air concentration PlS:81 number of transformations PlS:80 specific effective energy PlS:79;

P2s:144 weighted cmtd. dose equiv. PlS:81

Strontium-89 annual limits on intake ~1~:83 committed dose equivalent PlS:82 decay scheme PlS:81 derived air concentration PlS:83 number of transformations PlS:82 specific effective energy PlS:81;

P2s:135 weighted cmtd. dose equiv. PlS:82

Strontium-90 annual limits on intake ~lS:85 committed dose equivalent PlS:84 decay scheme PlS:83 derived air concentration PlS:85 number of transformations PlS:84 specific effective energy PlS:83 weighted cmtd. dose equiv. PlS:85

Strontium-91 annual limits on intake ~lS:89

INDEX 59

decay scheme PlS:86



specific effective energy Pls:86


Strontium-92



decay scheme PlS:90





Sulphur






metabolic data P2:5


metabolism P2:5

organic compounds P2:6



Sulphur-35


committed dose equivalent P2S:l4

decay scheme P2S:13

derived air concentration P2S:l5




Sulphur-35 (vapour)




number of transformations ~2~:16

specific effective energy ~2S:15


Tantalum








metabolism P3:90


Tantalum-172








Tantalum-173








Tantalum-174








Tantalum-175








Tantalum-177







P3s:630, 654


Tantalum-176







651


Tantalum-178







specific effective energy P2S:413; P3S:632, 658, 922

weighted cmtd. dose equiv. P3S:634 Tantalum-179



Tantalum-18&n annual limits on intake P3S:638 committed dose equivalent P3S:638 decay scheme P3S:637 derived air concentration P3S:638 number of transformations P3S:637 specific effective energy P3S:637 weighted cmtd. dose equiv. P3S:638

Tantalum-180 annual limits on intake P3S:640 committed dose equivalent P3S:639 decay scheme P3S:639 derived air concentration P3S:640 number of transformations P3S:639 specific effective energy P3S:639 weighted cmtd. dose equiv. P3S:640

Tantalum-182m annual limits on intake P3S:642 committed dose equivalent P35:641 decay scheme P3S:640 derived air concentration P3S:642 number of transformations P3S:641 specific effective energy P3S:640 weighted cmtd. dose equiv. P3S:641

Tantalum-182 annual limits on intake P3S:643 committed dose equivalent P3S:643 decay scheme P3S:642 derived air concentration P3S:643 number of transformations P3$:642 specific effective energy P3S:606,

609, 641, 642 weighted cmtd. dose equiv. P3S:643

Tantalum-183 annual limits on intake P3S:645 committed dose equivalent P3S:644 decay scheme P3S:644 derived air concentration P3S:645 number of transformations P3S:644 specific effective energy P3S:612,


Tantalum-184 annual limits on intake P3S:647

committed dose equivalent P3S:646 decay scheme P3S:645 derived air concentration P3S:647 number of transformations P3S:646 specific effective energy P3S:615,


Tantalum-185 annual limits on intake P3S:649 committed dose equivalent P3S:648 decay scheme P3S:647 derived air concentration P3S:649 number of transformations P35:648 specific effective energy P3S:647 weighted cmtd. dose equiv. P3S:649

Tantalum-186 annual limits on intake P3S:650 committed Lose equivalent P3S:650 decay scheme P3S:649 derived air concentration P3S:650 number of transformations P3S:649 specific effective energy P3S:649 weighted cmtd. dose equiv. P3S:650

Technetium annual limits on intake P2:34 classification of isotopes P2:33 derived air concentration P2:34 distribution and retention P2:32 inhalation classes P2:32 metabolic data P2:32 metabolic model P2:32 metabolism P2:32 radiopharmaceuticals P2:33 uptake to blood P2:32

Technetium-93m annual limits on intake P2S:168 committed dose equivalent P2S:167 decay scheme P2S:165 derived air concentration P2S:168 number of transformations P2S:167 specific effective energy P2S:165 weighted cmtd. dose equiv. P2S:168

Technetium-93 annual limits on intake P2S:171 committed dose equivalent P2S:170 decay scheme P2S:169 derived air concentration P2~:171 number of transformations P2S:170 specific effective energy P2S:166,


Technetium-94m annual limits on intake P2S:173 committed dose equivalent P2S:173 decay scheme P2S:172 derived air concentration P25:173

INDEX 61

number of transformations P2S:172 committed dose equivalent P2S:192 specific effective energy P2S:172, decay scheme P2S:191

199 derived air concentration P2S:193 weighted cmtd. dose equiv. P2S:173 number of transformations P2S:192

Technetium-94 specific effective energy PlS:150; annual limits on intake P25:176 P2s:191 committed dose equivalent P2S:175 weighted cmtd. dose equiv. PZS:193 decay scheme P2S:174 Technetium-99 derived air concentration P2S:176 annual limits on intake P2S:195 number of transformations P2S:175 committed dose equivalent P2S:195 specific effective energy P2S:174 decay scheme P2S:194 weighted cmtd. dose equiv. P2S:176 derived air concentration P2S:195

Technetium-96m specific effective energy PlS:151; annual limits on intake P2S:180 P2S:194 committed dose equivalent P2S:179 weighted cmtd. dose equiv. P2S:195 decay scheme P2S:177 Technetium-101 derived air concentration P2S:180 annual limits on .intake P2S:197 number of transformations P2S:179 committed dose equivalent P2S:196 specific effective energy P2S:177 decay scheme P2S:196 weighted cmtd. dose equiv. P2S:180 derived air concentration P2S:197

Technetium-96 number of transformations P2S:196 annual limits on intake PZS:183 specific effective energy PlS:155; committed dose equivalent P2S:182 P2S:196 decay scheme PZS:181 weighted cmtd. dose equiv. PZS:196 derived air concentration P25:183 Technetium-104 number of transformations PZS:182 annual limits on intake P2S:198 specific effective energy P2S:178, committed dose equivalent P2S:197

181 decay scheme PZS:1.97 weighted cmtd. dose equiv. P2S:183 derived air concentration P2S:198

Technetium-97m number of transformations PZS:197 annual limits on intake P2S:185 specific effective energy P2S:197 committed dose equivalent PZS:185 weighted cmtd. dose equiv. P2S:198 decay scheme PZS:184 Tellurium derived air concentration P2S:185 annual limits on intake P1:86, 87; number of transformations P2S:184 P3:123 specific effective energy P2S:184, behaviour of daughters P1:85

202 classification of isotopes P1:86 weighted cmtd. dose equiv. P2S:185 derived air concentration P1:86,

Technetium-97 87; P3:123 annual limits on intake P2S:187 distribution and retention P1:85 committed dose equivalent P2S:187 inhalation classes P1:85 decay scheme P2S:186 metabolic data P1:85 derived air concentration P2S:187 metabolic model P1:85 number of transformations P2S:186 metabolism P1:85 specific effective energy P2S:i86 Reference Man data P1:85 weighted cmtd. dose equiv. P2S:187 uptake to blood P1:85

Technetium-98 Tellurium-116 annual limits on intake P2S:190 annual limits on intake PlS:159 committed dose equivalent PZS:1.89 committed dose equivalent PlS:l58 decay scheme PZS:188 decay scheme PlS:157 derived air concentration P2S:190 derived air concentration PlS:159 number of transformations P2S:189 number of transformations PIS:158 specific effective energy P2S:188 specific effective energy PlS:157 weighted cmtd. dose equiv. P2S:190 weighted cmtd. dose equiv. PlS:159

Technetium-99m Tellurium-121m annual limits on intake P2S:193 annual limits on intake PlS:161


decay scheme PlS:172 derived air concentration PlS:173 number of transformations PlS:172 specific effective energy PlS:170,

172; P3S:214, 259 weighted cmtd. dose equiv. PlS:173

Tellurium-129m annual limits on intake PlS:176 committed dose equivalent PlS:175 decay scheme PlS.174 derived air concentration PlS:176 number of transformations PlS:174 specific effective energy PlS:174;


Tellurium-129 annual limits on intake PlS:177 committed dose equivalent PlS:177 decay scheme PlS:176 derived air concentration PlS:177 number of transformations PlS:176 specific effective energy PlS:174,


Tellurium-13lm annual limits on intake PlS:180 committed dose equivalent PlS:179 decay scheme PlS:177 derived air concentration PlS:180 number of transformations PlS:179 specific effective energy PlS:178;


Tellurium-131 annual limits on intake ~lS:182 committed dose equivalent P1~:181 decay scheme PlS:180 derived air concentration PlS:182 number of transformations PlS:181 specific effective energy PlS:178

180; !?35:270 weighted cmtd. dose equiv. PlS:182

Tellurium-132 annual limits on intake PlS:184 committed dose equivalent PlS:183 decay scheme PlS:182 derived air concentration PlS:184 number of transformations PlS:183 specific effective energy PlS:183 weighted cmtd. dose equiv. PlS:184

Tellurium-133m annual limits on intake PlS:187 committed dose equivalent PlS:186 decay scheme PlS:184 derived air concentration PlS:187 number of transformations PlS:185


committed dose equivalent PlS:160 decay scheme PlS:159 derived air concentration PlS:161 number of transformations PlS:160 specific effective energy PlS:159 weighted cmtd. dose equiv. PlS:161



Tellurium-123m annual limits on intake PlS:166 committed dose equivalent PlS:166 decay scheme PlS:165 derived air concentration PlS:166 number of transformations PlS:165 specific effective energy PlS:165 weighted cmtd. dose equiv. PlS:166

Tellurium-123 annual limits on intake PlS:168;

P3:122,123 Addendum committed dose equivalent PlS:167 decay scheme PlS:167 derived air concentration PlS:168;

~3:122,123 Addendum half-life P3:122 Addendum number of transformations PlS:167 specific effective energy PlS:165,


Tellurium-125m annual limits on intake PlS:169 committed dose equivalent PlS:169 decay scheme PlS:168 derived air concentration PlS:169 number of transformations PlS:168 specific effective energy PlS:168;

P35:205, 250 weighted cmtd. dose equiv. PlS:169

Tellurium-127m annual limits on intake PlS:172 committed dose equivalent PlS:l71 decay scheme PlS:170 derived air concentration PlS:172 number of transformations PlS:170 specific effective energy PlS:170;

P3s:213, 259 weighted cmtd. dose equiv. PlS:171

Tellurium-127 annual limits on intake PlS:173 committed dose equivalent PlS:l73

INDEX 63



187 weighted cmtd. dose equiv. PlS:l88

Tellurium-134 annual limits on intake PlS:l91 committed dose equivalent PlS:190 decay scheme PlS:189 derived air concentration PlS:191 number of transformations PlS:189 specific effective energy PlS:189 weighted cmtd. dose equiv. PlS:190

Terbium annual limits on intake P3:72 classification of isotopes P3:71 derived air concentration P3:72 distribution and retention P3:70 inhalation classes P3:70 metabolic data P3:70 metabolic model P3:70 metabolism P3:70 uptake to blood P3:70

Terbium-147 annual limits on intake P3S:443 committed dose equivalent P3S:443 decay scheme P3S:441 derived air concentration P3S:443 number of transformations P3S:442 specific effective energy P3S:441 weighted cmtd. dose equiv. P3S:443

Terbium-149 annual limits on intake P3S:446 committed dose equivalent P3S:446 decay scheme P3S:444 derived air concentration P3S:446 number of transformations P3S:445 specific effective energy P3S:444 weighted cmtd. dose equiv. P3S:446

Terbium-150 annual limits on intake P3S:448 committed dose equivalent P3S:447 decay scheme P3S:447 derived air concentration P3S:448 number of transformations P3S:447 specific effective energy P35:447 weighted cmtd. dose equiv. P3S:448

Terbium-151 annual limits on intake P3S:452 committed dose equivalent P3S:451

decay scheme P3S:449 derived air concentration P3S:452 number of transformations P3S:451 specific effective energy P3S:449 weighted cmtd. dose equiv. P3S:452

Terbium-153 annual limits on intake P3S:455 committed dose equivalent P3S:454 decay scheme P35:452 derived air concentration P3S:455 number of transformations P3S:453 specific effective energy P35:452 weighted cmtd. dose equiv. P35:454

Terbium-154 annual limits on intake P3S:457 committed dose equivalent P35:456 decay scheme P3S:455 derived air concentration P35:457 number of transformations P3S:456 specific effective energy P35:455 weighted cmtd. dose equiv. P3S:457

Terbium-155 annual limits on intake P3S:459 committed dose equivalent P3S:458 decay scheme P3S:458 derived air concentration P3S:459 number of transformations P3S:458 specific effective energy P3S:458,


Terbium-156m (5.0h) annual limits on intake P3S:465 committed dose equivalent P3S:464 decay scheme P3S:463 derived air concentration P3S:465 number of transformations P3S:464 specific effective energy P3S:463 weighted cmtd. dose equiv. P35:465

Terbium-156m (24.4h) annual limits on intake P3S:461 committed dose equivalent P3S:461 decay scheme P3S:460 derived air concentration P3S:461 number of transformations P3S:461 specific effective energy P3S:460 weighted cmtd. dose equiv. P3S:461






Terbium-158 annual limits on intake P35:471 committed dose equivalent P3S:470 decay scheme P3S:469 derived air concentration P3~:471 number of transformations ~3~:470 specific effective energy P3S:469 weighted cmtd. dose equiv. P3S:471

Terbium-160 annual limits on intake P3S:473 committed dose equivalent P35:473 decay scheme P3S:472 derived air concentration P3S:473 number of transformations P3S:472 specific effective energy P3S:472 weighted cmtd. dose equiv. P3S:473

Terbium-161 annual limits on intake P3S:475 committed dose equivalent P3S:474 decay scheme P3S:474 derived air concentration P3S:475 number of transformations P3~:474 specific effective energy P3S:474 weighted cmtd. dose equiv. P3S:475

Thallium annual limits on intake P3:lOl classification of isotopes P3:lOO derived air concentration P3:lOl distribution and retention P3:99 inhalation classes P3:99 metabolic data P3:99

metabolic model P3:99 metabolism P3:99 uptake to blood P3:99

Thallium-194m annual limits on intake P3:7Il committed dose equivalent P3S:711 decay scheme P3S:710 derived air concentration P3S:711 number of transformations P3S:710 specific effective energy P3S:710 weighted cmtd. dose equiv. P3S:711

Thallium-194 annual limits on intake P3S:713 committed dose equivalent P3S:712 decay scheme P3S:712 derived air concentration P3S:713


Thallium-195 annual limits on intake P35:717 committed dose equivalent P3S:716 decay scheme P3S:714 derived air concentration P3S:717 number of transformations P3S:715 specific effective energy P2S:624;


Thallium-197 annual limits on intake P3S:719 committed dose equivalent P3S:718 decay scheme P3S:717 derived air concentration P3S:719 number of transformations P3S:718 specific effective energy P3S:717 weighted cmtd, dose equiv. P3S:719

Thallium-198m annual limits on intake P3S:722 committed dose equivalent P3S:721 decay scheme P3S:720 derived air concentration P3S:722 number of transformat'ons P3S:721 specific effective energy P3S:720 weighted cmtd. dose equiv. P3S:722

Thallium-198 annual limits on intake P3S:724 committed dose equivalent P3S:723 decay scheme P3S:722 derived air concentration P3S:724 number of transformations P3S:723 specific effective energy P2S:629;

P35:720, 722 weighted cmtd. dose equiv. P35:724

Thallium-199 annual limits on intake P35:727 committed dose equivalent P3S:726 decay scheme 73S;725 derived air concentration P3S:727 number of transformations P3S:725 specific effective energy P2S:633;

P3s:725


Thallium-200 annual limits on intake P35:729 committed dose equivalent P3S:728 decay scheme P3S:727 derived air concentration P3S:729 number of transformations P3S:727 specific effective energy P2S:637,


INDEX 65

Thallium-207 uptake to blood P1:lOO

annual limits on intake P3S:731 Thorium-226 committed dose equivalent P3S:730 annual limits on intake PlS:305 decay scheme P3S:729 committed dose equivalent PlS:305 derived air concentration P3S:731 decay scheme PlS:302 number of transformations P3S:730 derived air concentration PlS:305

specific effective energy P2S:641, number of transformations PlS:304

679; P35:729 specific effective energy PlS:302,

weighted cmtd. dose equiv. P3S:731 338, 489; P3S:778, 819

Thallium-202 weighted cmtd. dose equiv. PlS:305 annual limits on intake P3S:734 Thorium-227

committed dose equivalent P35:733 annual limits on intake PlS:310 decay scheme P3S:732 committed dose equivalent PlS:309

derived air concentration P3S:734 decay scheme PlS:306

number of transformations P3S:732 derived air concentration PlS:310

specific effective energy P2S:646, number of transformations PlS:3OS

649; P35:732 specific effective energy PlS:291,

weighted cmtd. dose equiv. P3S:733 306, 325, 345; P3s:787, 805, 825 Thallium-204 weighted cmtd. dose equiv. PlS:310

annual limits on intake P3S:736 Thorium-228

committed dose equivalent P3S:735 annual limits on intake PlS:314 decay scheme P3S:734 committed dose equivalent PlS:314 derived air concentration P3S:736 decay scheme PlS:310

number of transformations P3S:735 derived air concentration PlS:314

specific effective energy P3S:734 number of transformations PlS:313

weighted cmtd. dose equiv. P3S:736 specific effective energy PlS:296, Thallium-206 310, 331, 352, 495, 528;P3s:793,

specific effective energy P2S:695 811, 829 Thallium-207 weighted cmtd. dose equiv. PlS:314

specific effective energy PlS:276, Thorium-229

308; P2S:662; P3s:807 annual limits on intake PlS:318 Thallium-208 committed dose equivalent PlS:318

specific effective energy PlS:280, decay scheme PlS:315

298, 312, 332, 355, 401, 498,530; derived air concentration PlS:318

P2s:667, 699; P3S:764, 814 number of transformations PlS:317 Thallium-209 specific effective energy PlS:315,

specific effective energy PlS:316; 358 P2s:702; P?s:771 weighted cmtd. dose equiv. PlS:318

Thallium-228

specific effective

725, 732

Thallium-232

specific effective

730

Thallium-327

specific effective

Thorium

energy P2S:707,

energy P2S:723,

energy PlS:327

annual limits on intake P1:lOl

classification of isotopes Pl:lOO

derived air concentration P1:lOl

distribution and retention P1:lOO

inhalation classes Pl:lOO metabolic data Pl:lOtl

metabolic model Pl:lOO

metabolism Pl:lOO

Reference Man data Pl:lOO

Thorium-230








Thorium-231



decay scheme PlS:323 derived air concentration PlS:330




Thorium-232 Thulium-170 annual limits on intake PlS:334 annual limits on intake P3S:529 committed dose equivalent PlS:333 committed dose equivalent P3S:529 decay scheme PlS:330 decay scheme P3S:528 derived air concentration P1~:334 derived air concentration P3S:529 number of transformations P1~:333 number of transformations P3S:528 specific effective energy PlS:330 specific effective energy P3S:528 weighted cmtd. dose equiv. PIS:334 weighted cmtd. dose equiv. P3S:529

Thorium-234 Thulium-171 annual limits on intake PlS:337 annual limits on intake P3S:531 committed dose equivalent P1~:336 committed dose equivalent P35:530 decay scheme PlS:334 decay scheme P3S:530 derived air concentration PlS:337 derived air concentration P3S:531 number of transformations PlS:336 number of transformations P3S:530 specific effective energy PlS:335, specific effective energy P3S:518,

376 530 weighted cmtd. dose equiv. PlS:336 weighted cmtd. dose equiv. P3S:531

Thorium-297 Thulium-172 specific effective energy PlS:397 annual limits on intake P3S:532

Thulium committed dose equivalent P35:532 annual limits on intake ~3:81 classification of isotopes P3:8b

decay scheme P3S:531 derived air concentration P3S:532

derived air concentration P3:81 number of transformations P3S:531 distribution and retention P3:79 specific effective energy P3S:520, inhalation classes P3:79 531 metabolic data P3:79 weighted cmtd. dose equiv. P3S:532 metabolic model P3:79 Thulium-173 metabolism P3:79 annual limits on intake P3S:534 uptake to blood P3:79 committed dose equivalent P3S:534

Thulium-162 decay scheme P3S:533 annual limits on intake P3S:523 derived air concentration P3S:534 committed dose equivalent P3S:523 number of transformations P3S:533 decay scheme P3S:522 specific effective energy P3S:533 derived air concentration P3S:523 weighted cmtd. dose equiv. P3S:534 number of transformations P3S:522 Thulium-175 specific effective energy P3~:522, annual limits on intake P3S:536

537 committed dose equivalent P3S:535 weighted cmtd. dose equiv. P3S:523 decay scheme P3S:535

Thulium-166 derived air concentration P3S:536 annual limits on intake P3S:526 number of transformations P3S:535 committed dose equivalent P3S:525 specific effective energy P3S:535 decay scheme P3S:524 weighted cmtd. dose equiv. P35:536 derived air concentration P3S:526 Tin number of transformations P3~:525 annual limits on intake P3:45 specific effective energy P3S:524, classification of isotopes P3:44

540 derived air concentration P3:45 weighted cmtd. dose equiv. P3S:526 distribution and retention P3:43

Thulium-167 inhalation classes P3:43 annual limits on intake P3S:528 metabolic data P3:43 committed dose equivalent P3S:527 metabolic model P3:43 decay scheme P3S:526 metabolism P3:43 derived air concentration P3S:528 Reference Man data P3:43 number of transformations P3S:527 uptake to blood P3:43 specific effective energy P3S:526, Tin-110

542 annual limits on intake P3S:185 weighted cmtd. dose equiv. P3S:527 coannitted dose equivalent P3S:184


INDEX 67

decay scheme P3S:183 derived air concentration P3S:185 number of transformations P3S:184 specific effective energy P3S:183 weighted cmtd. dose equiv. P3S:185

Tin-111 annual limits on intake P3S:i88 committed dose equivalent P3S:187 decay scheme P3S:186 derived air concentration P3S:188 number of transformations P3S:187 specific effective energy P3S:186 weighted cmtd. dose equiv. P3S:188

Tin-113 annual limits on intake P3S:191 committed dose equivalent P3S:190 decay scheme P3S:189 derived air concentration P3S:191 number of transformations P3S:190 specific effective energy P3S:189 weighted cmtd. dose equiv. P3S:191

Tin-117m annual limits on intake P3S:193 committed dose equivalent P3S:193 decay scheme P3S:192 derived air concentration P3S:193 number of transformations P3S:192 specific effective energy P2S:313,

318; P3S:192 weighred cmtd. dose equiv. P3S.193

Tin-119m annual limits on intake P3S:196 committed dose equivalent P3S:195 decay scheme P3S:l94 derived air concentration P3S:196 number of transformations P3S:194 specific effective energy P3S:194 weighted cmtd. dose equiv. P3S:195

Tin-12lm annual limits on intake P3S:198 committed dose equivalent P3S:197 decay.scheme P3S.196 derived air concentration P3S:198 number of transformations P3S:197 specific effective energy P3S:196 weighted cmtd. dose equiv. P3S:198

Tin-121 annual limits on intake ~3~:200 committed dose equivalent P3S:199 decay scheme P3S:198 derived air concentration P3S:ZOO number of transformations P3S:199 specific effective energy P3S:196,


Tin-123m

annual limits on intake P3S:202 committed dose equivalent P3S:201 decay scheme P3S:200 derived air concentration P3~:202 number of transformations P3S:201 specific effective energy P3S:200 weighted cmtd. dose equiv. P3S:201

Tin-123 annual limits on intake P3S:204 committed dose equivalent P3S:203 decay scheme P3S:202 derived air concentration P3S:204 number of transformations P3S:202 specific effective energy P3S:202 weighted cmtd. dose equiv. P35:203

Tin-125 annual limits on intake P3S:207 committed dose equivalent P3S:206 decay scheme P3S:204 derived air concentration P3S:207 number of transformations P3S:205 specific effective energy P35:204 weighted cmtd. dose equiv. P35:206

Tin-126 annual limits on intake P3S:211 committed dose equivalent P3~:210 decay scheme P3S:207 derived air concentration P3S:211 number of transformations P3S:210 specific effective energy P3S:207 weighted cmtd. dose equiv. P3S:211

Tin-127 annual limits on intake P3S:217 committed dose equivalent P3S:216 decay scheme P3S:212 derived air concrntration P3S:217 number of transformations P3S:215 specific effective energy P3S:212 weighted cmtd. dose equiv. P3S:216

Tin-128 annual limits on intake P3S:219 committed dose equivalent ~3S:218 decay scheme P3S:217 derived air concentration P3S:219 number of transformations P3S:218 specific effective energy ~3S:217 weighted cmtd. dose equiv. P3S:219

Titanium annual limits on intake P3:21 classification of isotopes P3:21 derived air concentration ~3:21 distribution and retention P3:20 inhalation classes ~3:20 metabolic data P3:20 metabolic model P3:20 metabolism P3:20


weighted cmtd. dose equiv. P35:660 Tungsten-179


Tungsten-181 annual limits on intake P3S:665 committed dose equivalent P3S:664 decay scheme P3S:663 derived air concentration P3S:665 number of transformations P3S:664 specific effective energy P2S:416,


Tungsten-185 annual limits on intake P3~:668 committed dose equivalent P3S:667 decay scheme P3S:666 derived air concentration P3S:668 number of transformations P3S:667 specific effective energy P35:648,

666

Reference Man data P3:20 uptake to blood P3:20

Titanium-44 annual limits on intake P3S:54 committed dose equivalent P3S:52 decay scheme P3S:50 derived air concentration P3S:54 number of transformations P3S:51 specific effective energy P3S:50 weighted cmtd. dose equiv. P3S:53

Titanium-45 annual limits on intake P3S:56 committed dose equivalent P3S:55 decay scheme P3S:54 derived air concentration P3S:56 number of transformations P3S:55 specific effective energy P35:54 weighted cmtd. dose equiv. P3S:56

Tritium derived air concentration Pl:lO dose equivalent rate PI:48

Tungsten annual limits on intake P3:95 classification of isotopes P3:94 derived air concentration P3:95 distribution and retention P3:93 inhalation classes P3:93 metabolic data P3:93 metabolic model P3:93 metabolism P3:93 uptake to blood P3:93

Tungsten-176 annual limits on intake P3S:653 committed dose equivalent P3S:652 decay scheme P3S:651 derived air concentration P3S:653 number of transformations P3S:652 specific effective energy P3~:651 weighted cmtd. dose equiv. P3S:653

Tungsten-177 annual limits on intake P3S:656 committed dose equivalent P3S:655 decay scheme P3S:653 derived air concentration P3S:656 number of transformations P3S:654 specific effective energy P2S:409;


Tungsten-178 annual limits on intake P3S:660 committed dose equivalent P3S:659 decay scheme P3S:657 derived air concentration P3S:660 number of transformations P3S:659 specific effective energy P2S:412;

P3S:657, 921 metabolic data PI:102

weighted cmtd. dose equiv. P3S:668 Tungsten-187


Tungsten-188 annual limits on intake P3S:675 committed dose equivalent P3S:673 decay scheme P3S:671 derived air concentration P3S:675 number of transformations P3S:673 specific effective energy P3S:671 weighted cmtd. dose equiv. P3S:674

Uranium annual limits on intake P1:104 classification of isotopes P1:103 derived air concentration PI:104 distribution and retention PI:102 inhalation classes P1:102

INDEX 69

metabolic model P1:lOZ weighted cmtd. dose equiv. PlS:369 metabolism P1:102 Uranium-236 Reference Man data P1:102 annual limits on intake PlS:372 uptake to blood Pl:102 committed dose equivalent PlS:371

Uranium-230 decay scheme PlS:370 annual limits on intake PlS:343 derived air concentration PlS:372 committed dose equivalent P1~:342 number of transformations PlS:370 decay scheme PlS:338 specific effective energy PlS:370; derived air concentration ~1~:343 ~2s:723, 730 number of transformations ~1~:341 weighted cmtd. dose equiv. PlS:371 specific effective energy PlS:338, Uranium-237

488; P3s:819 annual limits on intake PlS:375 weighted cmtd. dose equiv. PlS:342 committed dose equivalent PlS:373

Uranium-231 decay scheme PlS:372 annual limits on intake PlS:351 derived air concentration PlS:375 committed dose equivalent P1~:350 number of transformations PlS:373 decay scheme PlS:343 specific effective energy PlS:372 derived air concentration P1~:351 weighted cmtd. dose equiv. PlS:374 number of transformations ~1~:349 Uranium-238 specific effective energy PlS:343 annual limits on intake PlS:379 weighted cmtd. dose equiv. PlS:351 committed dose equivalent PlS:378

Uranium-232 decay scheme PlS:375 annual limits on intake PlS:357 derived air concentrations PlS:379 committed dose equivalent PlS:356 number of transformations PlS:377 decay scheme PlS:352 specific effective energy P1S:375 derived air concentration ~1~:357 weighted cmtd. dose equiv. PlS:378 number of transformations P1~:355 Uranium-239 specific effective energy PlS:352, annual limits on intake PlS:382

397, 495, 528; P2S:707, 724, 731; committed dose equivalent PlS:381 P3s:829

weighted cmtd. dose equiv. PlS:357 Uranium-233

annual limits on intake P13:363 committed dose equivalent PlS:362 decay scheme PlS:358 derived air concentration PlS:363 number of transformations PlS:361 specific effective energy PlS:358;

decay scheme PlS:379 derived air concentration PlS:382 number of transformations PlS:381 specific effective energy PlS:379 weighted cmtd. dose equiv. PlS:382

Uranium-240

P2s:712; P3s:836 weighted cmtd. dose equiv. PlS:362

Uranium-234 annual limits on intake PlS:366 committed dose equivalent PlS:364 decay scheme PlS:363 derived air concentration PlS:366 number of transformations PlS:364 specific effective energy PlS:335,

363; P2S:716; P3S:839 weighted cmtd. dose equiv. PlS:365

Uranium-235 annual limits on intake PlS:369 committed dose equivalent PlS:368 decay scheme PlS:367 derived air concentration PlS:369 number of transformations PlS:368 specific effective energy PlS:367

annual limits on intake PlS:386 committed dose equivalent PlS:385 decay scheme Pl~:383 derived air concentration PlS:386 number of transformations PlS:384 specific effective energy PlS:383,

431 rreighted cmtd. dose equiv. PlS:385

Vanadium annual limits on intake P3:24 classification of isotopes P3:23 derived air concentration P3:24 distribution and retention P3:22 inhalation classes P3:22 metabolic data P3:22


metabolic model P3:22 metabolism P3:22 Reference Man data P3:22 uptake to blood P3:22

Vanadium-47 annual limits on intake P3S:58 conrsitted dose equivalent P3S:58 decay scheme P3S:5? derived air concentration P3~:58 number of transformations P3S:5? specific effective energy P3S:5? weighted cmtd. dose equiv. P3S:SB

Vanadium-48 annual limits on intake P3S:61 committed dose equivalent P3~:60 decay scheme P3S:59 derived air concentration P3~:61 number of transformations P3S:59 specific effective energy P2~:46;


Vanadium-49 annual limits on intake P3S:63 committed dose equivalent P3S:63 decay scheme P38:62 derived air concentration P3~:63 number of transformations P3~:62 specific effective energy P2~:50;

P3s:62 weighted cmtd. dose equiv. P3S:63

Xenon derived air concentration P2:4? dose equivalent rate P1:48 metabolic data P2:4?

Xenon-120 decay scheme P2S:354 derived air concentration P2S:356 dose equivalent rate P2S:354 specific effective energy P2~:354 weighted dose equiv. rate P2~:355

Xenon-121 decay scheme P2S:356 derived air concentration P2~:358 dose equivalent rate P2S:356 specific effective energy P2~:356 weighted dose equiv. rate P2S:35?

Xenon-122 decay scheme P2S:358 derived air concentration P2S:360 dose equivalent rate P2S:358

specific effective energy P2S:358 weighted dose equiv. rate P2S:359

Xenon-123 decay scheme P2~:360 derived air concentration P2S:362 dose equivalent rate P2S:360 specific effective energy P2S:360 weighted dose equiv. rate ~2S:361

Xenon-125 decay scheme P2~:362 derived air concentration P2S:364 dose equivalent rate P2S:362 specific effective energy P2S:362 weighted dose equiv. rate ~2S:363

Xenon-127 decay scheme P2S:364 derived air concentration P25:366 dose equivalent rate P2S:364 specific effective energy P25:364 weighted dose equiv. rate ~2S:365

Xenon-129m decay scheme P2S:366 derived air concentration P2S:36? dose equivalent rate P2S:366 specific effective energy ~2S:366 weighted dose equiv. rate P2S:36?

Xenon-131m decay scheme P2S:368 derived air concentration P2S:369 dose equivalent rate P2S:368 specific effective energy P2S:368 weighted dose equiv. rate P25:369

Xenon-133m decay scheme P2S:3?0 derived air concentration P2S:3?2 dose equivalent rate P2S:3?0 specific effective energy P2S:3?0 weighted dose equiv. rate P2S:3?1

Xenon-133 decay scheme P2S:3?2 derived air concentration P2S:3?4 dose equivalent rate P2Sr372 specific effective energy P2SI372 weighted dose equiv. rate P25:3?3

Xenon-135m decay scheme P2S:3?4 derived air concentration ~2S:376 dose equivalent rate P2S:3?5 specific effective energy P2S:3?4 weighted dose equiv. rate P2S:375

Xenon-135 decay scheme P2S:3?6 derived air concentration P2S:3?8 dose equivalent rate P2S:3?? specific effective energy PES:3?6 weighted dose equiv. rate P2S:3?7

INDEX 7

Xenon-138 decay scheme P2S:378 derived air concentration P2S:380 dose equivalent rate P2S:379 specific effective energy P2S:378 weighted dose equiv. rate P2S:379

Ytterbium annual limits on intake P3:84 chelated compounds P3:83 classification of isotopes P3:83 derived air concentration P3:84 distribution and retention P3:82 inhalation classes P3:82 metabolic data P3:82 metabolic model P3:82 metabolism P3:82 uptake to blood P3:82

Ytterbium-162 annual limits on intake P3S:539 committed dose equivalent P3S:538 decay scheme P3S:537 derived air concentration P3S:539 number of transformations P3S:538 specific effective energy P3S:537 weighted cmtd. dose equiv. P3S:539

Ytterbium-166 annual limits on intake P3S:542 committed dose equivalent P3S:541 decay scheme P3S:539 derived air concentration P3S:542 number of transformations P3S:540 specific effective energy P3S:539 weighted cmtd. dose equiv. P3S:541

Ytterbium-167 annual limits on intake P3S:544 committed dose equivalent P35:543 decay scheme P3S:542 derived air concentration P3S:544 number of transformations P3S:543 specific effective energy P3S:542 weighted cmtd. dose equiv. P3S:544

Ytterbium-169 annual limits on intake P35:546 committed dose equivalent P3S:545 decay scheme P3S:544 derived air concentration P3S:546 number of transformations P35:545 specific effective energy P3S:544,


Ytterbium-175 annual limits on intake P3S:547 committed dose equivalent P3S:547 decay scheme P3S:546 derived air concentration P3S:547 number of transformations P3S:546 specific effective energy P3S:535,


Ytterbium-177 annual limits on intake P3S:549 committed dose equivalent P3S:549 decay scheme P35:548 derived air concentration P3S:549 number of transformations P3S:548 specific effective energy P3S:548 weighted cmtd. dose equiv. P3S:549

Ytterbium-178 annual limits on intake P3S:551 committed dose equivalent P3S:551 decay scheme P3S:550 derived air concentration P3S:551 number of transformations P35:550 specific effective energy P3S:550 weighted cmtd. dose equiv. P3S:551

Yttrium annual limits on intake P2:31 cIassification of isotopes P2:30 derived air concentration P2:31 distribution and retention P2:30 inhalation classes P2:30 metabolic data P2:30 metabolic model P2:30 metabolism P2:30 uptake to blood P2:30

yttrium-86m annual limits on intake P2S:140 committed dose equivalent P2S:139 decay scheme P2S:137 derived air concentration P2S:140 number of transformations P2S:139 specific effective energy P2S:137 weighted cmtd. dose equiv. P2S:140

yttrium-86 annual limits on intake P2S:143 committed dose equivalent P2S:142 decay scheme P2S:141 derived air concentration P2S:143 numoer of transformations P2S:142 specific effective energy PlS:94;

P2S:138, 141 weighted cmtd. dose equiv. P2S:143

Yttrium-87 annual limits on intake P2S:146 committed dose equivalent P25:145 decay scheme P2S:144


derived air concentration P2S:146 weighted cmtd. dose equiv. P25:158 number of transformations P2S:145 Yttrium-93 specific effective energy P2S:144 annual limcts on intake P2S:160 weighted zmtd. dose equiv. P2S:146

Yttrium-88 committed dose equivalent P2S:160 decay scheme P2S:l.59

annual limits on intake P2S:149 derived air concentration P2S:160 committed dose equivalent P2S:148 number of transformations PZS:159 decay schemn P2S:147 derivedair concentration P2S:149

specific effective energy P2S:159 weighted cmtd. nose .equi-1. P2S:lSO

number of transformations P2S:148 yttrium-94 specific effective energy PlS:98, annual limits on intake P2S:162

115; P25:147 weighted cmtd. dose equiv. P2S:149

committed dose equivalent P2S:16l

Yttrium-90m decay scheme P2S:161 derived air concentration P2s:i62

annual limits on intake P2S:151 number of transformations P2S:161 committed dose equivalent PZS:150 decayscheme P2S:149;P3S:921Addendum



Yttrium-95 number of transformations P2S:150 annual limits on intake P2S:164 specific effective energy P2S:149 weighted cmtd. dose equiv. P2S:151


l'ttrium-90 decay scheme P2S:162 derived air concentration P2S:164

annual limits on intake P2S:152 number of transformations P2S:163 committed dose equivalent P2S:152 decay scheme PZS:151



Zinc number of transformations P2S:lSl annual limits on intake P2:23 specific effective energy PlS:83;

P2s:150, 151 classification of isotopes P2:22 derived air concentration P2:23

weighted cmtd. dose equiv. P2S:152 distribution and retention P2:21 Yttrium-9lm inhalation classes P2:21

annual limits on intake P2S:155 metabolic data P2:21 committed dose equivalent P2S:154 metabolic model P2:21 decay scheme P2S:153 metabolism P2:21 derived air concentration P2S:155 Reference Man data P2:21 number of transformations P2S:154 uptake to blood P2:21 specific effective energy PlS:86; zinc-62

P2s:153 annual limits on intake P2S:84 weighted cmtd. dose equiv. P2S:155 committed dose equivalent P2S:83

Yttrium-91 decay scheme P2S:82 annual limits on intake P2S:157 derived air concentration P2S:84 committed dose equivalent P2S:156 number of transformations P2S:83 decay scheme P2S:E5 specific effective energy P2S:82 derived air concentration P2S:157 weighted cmtd. dose equiv. P2S:84 number of transformations P2S:156 Zinc-63 specific effective energy PlS:87; annual limits on intake P2S:85

P2s:153, 155 committed dose equivalent P2S:85 weighted cmtd. dose equiv. PZS:156 decay scheme P2S:84

Yttrium-92 derived air concentration P2S:85 annual limits on intake P23:158 number of transformations P2S:85 committed dose equiva1e.t P2S:158 specific effective energy P2S:84 decay scheme P2S:157 weighted cmtd. dose equiv. P2S:S5 derived air concentration P2S:158 zinc-65 number of transformations P2S:157 annual limits on intake P2S:88 specific effective energy PlS:90; committed dose equivalent P2S:87

P2s:157 decay scheme P2S:86

INDEX 73

derived air concentration P2S:gg


specific effective energy P25:86;

P3S:93


Zinc-69m


committed dose equivalent P2S:S9

decay scheme P2S:gg



specific effective energy P2s:aa


Zinc-69



decay scheme PZS:90




90


Zinc-7lm



dzcay scheme P2S:92



specific effective energy P2S:9?


Zinc-72



decay scheme PZS:94





Zirconium

annual limits on intake Pl:SO

classification of isotopes PI:80

derived air concentration P1:gO





metabolism P1:79



Zirconium-86



decay scheme PlS:93





Zirconium-88

annual limits on intake PlS:lOl


decay scheme PlS:97

derived air concentration P1S:lOl



115

weighted cmtd. dose equiv. PlS:lOO

Zirconium-S9

annual limits on intake_PlS:104

committed dose equivalent PlS:lOZ

decay scheme PlS:lOl

derived air concentration PlS:iO4

number of transformations PlS:lOZ


117, 119

weighted cmtd. dose equi-?? PlS:103

Zirccn:um-93

annual :jr;lits on int:,'te PlS:107




number of transformations PlS:lO5

specific effective energ:' PlS:104

weighted cmtd. dose equiv. PlS:?O6

Zirconium-95

annual limits on intake PlS:llO

committed dose equivalent PlS:lOi:


derived air concentration PlS:llO



P2S:162

weighted cmtd. dose equiv. PlS:llO Zirconium-97



decay scheme PlS:ill

derived air concentration ~1~:114

number of transformations ~1~:112

specific effective energy PlS:lll

iqeighted cmtd. dose equiv. P7S:Il4

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