neutrino physics with penning traps at mpi-k
DESCRIPTION
Neutrino Physics with Penning Traps at MPI-K. Sergey Eliseev Group of Prof. K. Blaum “Trapped and Cooled Ions“ MPI-K, Heidelberg. SFB-Meeting, 9.07.2009. B. q / m. f z. Confinement Volume DTRANSCRIPT
Neutrino Physics with Penning TrapsNeutrino Physics with Penning Trapsat MPI-Kat MPI-K
Sergey EliseevSergey EliseevGroup of Prof K BlaumGroup of Prof K Blaum
ldquoldquoTrapped and Cooled IonsldquoTrapped and Cooled Ionsldquo MPI-K HeidelbergMPI-K Heidelberg
SFB-Meeting 9072009SFB-Meeting 9072009
z0
r0
ring electrode
end cap
f-
f+
fz
2z
222c ffff - invariance theorem
Principle of Penning trap mass spectrometryPrinciple of Penning trap mass spectrometry
Sergey Eliseev SFB-Meeting 9072009
Cyclotron frequency Bm
q21fc π
B
qm
B
qm
Confinement VolumeDlt10 m
very precise measurements of fcare possible
Detection techniques Detection techniques
Sergey Eliseev SFB-Meeting 9072009
Narrow-band FT-Narrow-band FT-ICRICR
42 K
Q ~ 15 000 voltage noise ~ 700 pVHz12 current noise ~ 3fAHz12
High-precision mass measurementsHigh-precision mass measurements
Single ion sensitivitySingle ion sensitivity
mm lt 10mm lt 10-11-11
Penning TrapsPenning Traps
with an accuracy up to 10-11
Determination ofneutrino amp anti-neutrino
mass
Q-value of a decay (Q=Mi-Mk)
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Mass of neutrino Mass of neutrino ampamp anti-neutrino anti-neutrino
1940 1950 1960 1970 1980 1990 2000 20101
10
100
1000
10000
Year
Lim
it on
m
eV from - decay from decay
3 H
35S
3 H3 H
37A
r amp 22
Na
3 H
3 H16
3 Ho
193 P
t16
3 Ho
3 H
187 R
e
163 H
o
Sergey Eliseev SFB-Meeting 9072009
Mass of anti-neutrino Mass of anti-neutrino 33TT 33He -decayHe -decay
18 575
18 580
18 585
18 590
18 595
18 600
18 605
18 610
18 615
Q-V
alue
[eV]
-Spectrometers(Curie plots)
FTICR
PenningTraps
SMILETRAP(Q=12 eV)
VanDyck
2
2
KATRIN aims for mKATRIN aims for m lt 02 eV lt 02 eV
Independent measurement of Q-value of Independent measurement of Q-value of 33T-decayT-decaybull gives a check on systematic errorsgives a check on systematic errors
bull can remove a free parameter from KATRIN data analysiscan remove a free parameter from KATRIN data analysis
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr1 (THe) at MPI-K in new lab Nr1 (THe) at MPI-K
We aim for Q (3T rarr 3He) =20 meV (mm)= 7middot10-12
Dr David Pinegar et al
Vibration lsquofreelsquo floor x lt 01 m
plusmn01 K LaboratoryLaboratoryTemperature stabilization 01Kday Pressure stabilization Vibration lsquofreelsquo floor lt01 m Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
MagnetMagnet 6 Tesla 42 K-bore magnet Magnetic field stability BB lt 17 ppth
04062009 12C4+
Sergey Eliseev SFB-Meeting 9072009
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
z0
r0
ring electrode
end cap
f-
f+
fz
2z
222c ffff - invariance theorem
Principle of Penning trap mass spectrometryPrinciple of Penning trap mass spectrometry
Sergey Eliseev SFB-Meeting 9072009
Cyclotron frequency Bm
q21fc π
B
qm
B
qm
Confinement VolumeDlt10 m
very precise measurements of fcare possible
Detection techniques Detection techniques
Sergey Eliseev SFB-Meeting 9072009
Narrow-band FT-Narrow-band FT-ICRICR
42 K
Q ~ 15 000 voltage noise ~ 700 pVHz12 current noise ~ 3fAHz12
High-precision mass measurementsHigh-precision mass measurements
Single ion sensitivitySingle ion sensitivity
mm lt 10mm lt 10-11-11
Penning TrapsPenning Traps
with an accuracy up to 10-11
Determination ofneutrino amp anti-neutrino
mass
Q-value of a decay (Q=Mi-Mk)
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Mass of neutrino Mass of neutrino ampamp anti-neutrino anti-neutrino
1940 1950 1960 1970 1980 1990 2000 20101
10
100
1000
10000
Year
Lim
it on
m
eV from - decay from decay
3 H
35S
3 H3 H
37A
r amp 22
Na
3 H
3 H16
3 Ho
193 P
t16
3 Ho
3 H
187 R
e
163 H
o
Sergey Eliseev SFB-Meeting 9072009
Mass of anti-neutrino Mass of anti-neutrino 33TT 33He -decayHe -decay
18 575
18 580
18 585
18 590
18 595
18 600
18 605
18 610
18 615
Q-V
alue
[eV]
-Spectrometers(Curie plots)
FTICR
PenningTraps
SMILETRAP(Q=12 eV)
VanDyck
2
2
KATRIN aims for mKATRIN aims for m lt 02 eV lt 02 eV
Independent measurement of Q-value of Independent measurement of Q-value of 33T-decayT-decaybull gives a check on systematic errorsgives a check on systematic errors
bull can remove a free parameter from KATRIN data analysiscan remove a free parameter from KATRIN data analysis
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr1 (THe) at MPI-K in new lab Nr1 (THe) at MPI-K
We aim for Q (3T rarr 3He) =20 meV (mm)= 7middot10-12
Dr David Pinegar et al
Vibration lsquofreelsquo floor x lt 01 m
plusmn01 K LaboratoryLaboratoryTemperature stabilization 01Kday Pressure stabilization Vibration lsquofreelsquo floor lt01 m Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
MagnetMagnet 6 Tesla 42 K-bore magnet Magnetic field stability BB lt 17 ppth
04062009 12C4+
Sergey Eliseev SFB-Meeting 9072009
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Detection techniques Detection techniques
Sergey Eliseev SFB-Meeting 9072009
Narrow-band FT-Narrow-band FT-ICRICR
42 K
Q ~ 15 000 voltage noise ~ 700 pVHz12 current noise ~ 3fAHz12
High-precision mass measurementsHigh-precision mass measurements
Single ion sensitivitySingle ion sensitivity
mm lt 10mm lt 10-11-11
Penning TrapsPenning Traps
with an accuracy up to 10-11
Determination ofneutrino amp anti-neutrino
mass
Q-value of a decay (Q=Mi-Mk)
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Mass of neutrino Mass of neutrino ampamp anti-neutrino anti-neutrino
1940 1950 1960 1970 1980 1990 2000 20101
10
100
1000
10000
Year
Lim
it on
m
eV from - decay from decay
3 H
35S
3 H3 H
37A
r amp 22
Na
3 H
3 H16
3 Ho
193 P
t16
3 Ho
3 H
187 R
e
163 H
o
Sergey Eliseev SFB-Meeting 9072009
Mass of anti-neutrino Mass of anti-neutrino 33TT 33He -decayHe -decay
18 575
18 580
18 585
18 590
18 595
18 600
18 605
18 610
18 615
Q-V
alue
[eV]
-Spectrometers(Curie plots)
FTICR
PenningTraps
SMILETRAP(Q=12 eV)
VanDyck
2
2
KATRIN aims for mKATRIN aims for m lt 02 eV lt 02 eV
Independent measurement of Q-value of Independent measurement of Q-value of 33T-decayT-decaybull gives a check on systematic errorsgives a check on systematic errors
bull can remove a free parameter from KATRIN data analysiscan remove a free parameter from KATRIN data analysis
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr1 (THe) at MPI-K in new lab Nr1 (THe) at MPI-K
We aim for Q (3T rarr 3He) =20 meV (mm)= 7middot10-12
Dr David Pinegar et al
Vibration lsquofreelsquo floor x lt 01 m
plusmn01 K LaboratoryLaboratoryTemperature stabilization 01Kday Pressure stabilization Vibration lsquofreelsquo floor lt01 m Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
MagnetMagnet 6 Tesla 42 K-bore magnet Magnetic field stability BB lt 17 ppth
04062009 12C4+
Sergey Eliseev SFB-Meeting 9072009
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Penning TrapsPenning Traps
with an accuracy up to 10-11
Determination ofneutrino amp anti-neutrino
mass
Q-value of a decay (Q=Mi-Mk)
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Mass of neutrino Mass of neutrino ampamp anti-neutrino anti-neutrino
1940 1950 1960 1970 1980 1990 2000 20101
10
100
1000
10000
Year
Lim
it on
m
eV from - decay from decay
3 H
35S
3 H3 H
37A
r amp 22
Na
3 H
3 H16
3 Ho
193 P
t16
3 Ho
3 H
187 R
e
163 H
o
Sergey Eliseev SFB-Meeting 9072009
Mass of anti-neutrino Mass of anti-neutrino 33TT 33He -decayHe -decay
18 575
18 580
18 585
18 590
18 595
18 600
18 605
18 610
18 615
Q-V
alue
[eV]
-Spectrometers(Curie plots)
FTICR
PenningTraps
SMILETRAP(Q=12 eV)
VanDyck
2
2
KATRIN aims for mKATRIN aims for m lt 02 eV lt 02 eV
Independent measurement of Q-value of Independent measurement of Q-value of 33T-decayT-decaybull gives a check on systematic errorsgives a check on systematic errors
bull can remove a free parameter from KATRIN data analysiscan remove a free parameter from KATRIN data analysis
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr1 (THe) at MPI-K in new lab Nr1 (THe) at MPI-K
We aim for Q (3T rarr 3He) =20 meV (mm)= 7middot10-12
Dr David Pinegar et al
Vibration lsquofreelsquo floor x lt 01 m
plusmn01 K LaboratoryLaboratoryTemperature stabilization 01Kday Pressure stabilization Vibration lsquofreelsquo floor lt01 m Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
MagnetMagnet 6 Tesla 42 K-bore magnet Magnetic field stability BB lt 17 ppth
04062009 12C4+
Sergey Eliseev SFB-Meeting 9072009
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Mass of neutrino Mass of neutrino ampamp anti-neutrino anti-neutrino
1940 1950 1960 1970 1980 1990 2000 20101
10
100
1000
10000
Year
Lim
it on
m
eV from - decay from decay
3 H
35S
3 H3 H
37A
r amp 22
Na
3 H
3 H16
3 Ho
193 P
t16
3 Ho
3 H
187 R
e
163 H
o
Sergey Eliseev SFB-Meeting 9072009
Mass of anti-neutrino Mass of anti-neutrino 33TT 33He -decayHe -decay
18 575
18 580
18 585
18 590
18 595
18 600
18 605
18 610
18 615
Q-V
alue
[eV]
-Spectrometers(Curie plots)
FTICR
PenningTraps
SMILETRAP(Q=12 eV)
VanDyck
2
2
KATRIN aims for mKATRIN aims for m lt 02 eV lt 02 eV
Independent measurement of Q-value of Independent measurement of Q-value of 33T-decayT-decaybull gives a check on systematic errorsgives a check on systematic errors
bull can remove a free parameter from KATRIN data analysiscan remove a free parameter from KATRIN data analysis
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr1 (THe) at MPI-K in new lab Nr1 (THe) at MPI-K
We aim for Q (3T rarr 3He) =20 meV (mm)= 7middot10-12
Dr David Pinegar et al
Vibration lsquofreelsquo floor x lt 01 m
plusmn01 K LaboratoryLaboratoryTemperature stabilization 01Kday Pressure stabilization Vibration lsquofreelsquo floor lt01 m Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
MagnetMagnet 6 Tesla 42 K-bore magnet Magnetic field stability BB lt 17 ppth
04062009 12C4+
Sergey Eliseev SFB-Meeting 9072009
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Mass of anti-neutrino Mass of anti-neutrino 33TT 33He -decayHe -decay
18 575
18 580
18 585
18 590
18 595
18 600
18 605
18 610
18 615
Q-V
alue
[eV]
-Spectrometers(Curie plots)
FTICR
PenningTraps
SMILETRAP(Q=12 eV)
VanDyck
2
2
KATRIN aims for mKATRIN aims for m lt 02 eV lt 02 eV
Independent measurement of Q-value of Independent measurement of Q-value of 33T-decayT-decaybull gives a check on systematic errorsgives a check on systematic errors
bull can remove a free parameter from KATRIN data analysiscan remove a free parameter from KATRIN data analysis
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr1 (THe) at MPI-K in new lab Nr1 (THe) at MPI-K
We aim for Q (3T rarr 3He) =20 meV (mm)= 7middot10-12
Dr David Pinegar et al
Vibration lsquofreelsquo floor x lt 01 m
plusmn01 K LaboratoryLaboratoryTemperature stabilization 01Kday Pressure stabilization Vibration lsquofreelsquo floor lt01 m Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
MagnetMagnet 6 Tesla 42 K-bore magnet Magnetic field stability BB lt 17 ppth
04062009 12C4+
Sergey Eliseev SFB-Meeting 9072009
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
hellip hellip in new lab Nr1 (THe) at MPI-K in new lab Nr1 (THe) at MPI-K
We aim for Q (3T rarr 3He) =20 meV (mm)= 7middot10-12
Dr David Pinegar et al
Vibration lsquofreelsquo floor x lt 01 m
plusmn01 K LaboratoryLaboratoryTemperature stabilization 01Kday Pressure stabilization Vibration lsquofreelsquo floor lt01 m Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
MagnetMagnet 6 Tesla 42 K-bore magnet Magnetic field stability BB lt 17 ppth
04062009 12C4+
Sergey Eliseev SFB-Meeting 9072009
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
A Broad-Band FT-ICR Penning Trap System for KATRINA Broad-Band FT-ICR Penning Trap System for KATRINM Ubieto-Diacuteaz et al
Formation of ion clusters (Formation of ion clusters (33TT2n+12n+1))++ which decay with which decay with different end point than different end point than 33TT22 Presence of other species (contaminants)Presence of other species (contaminants)
Resolving Power ~10Resolving Power ~1044
PerformancePerformance
Sensetivity lt1000 ionsSensetivity lt1000 ions
Sergey Eliseev SFB-Meeting 9072009
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Mass of NeutrinoMass of Neutrino
Sergey Eliseev SFB-Meeting 9072009
Atomic Orbital Electron Capture Atomic Orbital Electron Capture
(ZA) (ZA) ++ e e (Z-1A)(Z-1A)h h ++ Q Q
(Z-1A)(Z-1A)g g ++ B Bii
(Z-1A)(Z-1A)gg
(Z-1A)(Z-1A)hh
(ZA)(ZA)
QEC Bi
Q
neutrino is monoenergetic Q can be as small as ~ 05 keV
Q = E + mc2 = QEC ndash Bi
(Q(QEC EC ndash Bndash Bii)) should be as small as possible
smaller Q rarr higher contribution of m
QQECEC should be as small as possible
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Mass of NeutrinoMass of Neutrino
Do we need to measure the neutrino mass since the antineutrino mass limit is known
Sergey Eliseev SFB-Meeting 9072009
Yes bull to confirm the results taken from tritium measurements
(with completely different systematic uncertainties)
bull hopefully can be useful for a check of CPT-conservation for neutrinos
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
analysis of calorimetric spectrum
mm
163163Ho Ho 163163DyDyhh + + ee (E (E))163163Dy + EDy + Ecc
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Mass of Neutrino electron-capture in Mass of Neutrino electron-capture in 163163HoHo
QECm
Typical Typical -calorimetric de-excitation spectrum of EC in -calorimetric de-excitation spectrum of EC in 163163HoHo
Sergey Eliseev SFB-Meeting 9072009
end point with accuracy ~ 1 eV end point with accuracy ~ 1 eV
QQECEC--valuevalue with accuracy ~ 1 eVwith accuracy ~ 1 eV
Cryogenic -calorimeters (Group of Prof Enss KIP Uni Heidelberg)
PENTATRAP (Group of ProfK Blaum MPI-K HD) mm ~ 1 eV ~ 1 eV
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
We aim for Q (163Ho rarr 163Dy) asymp1 eV (mm) lt 10-11
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Nuclide Relative uncertainty Reference
4He 1610-11 RS Van Dyck et al Phys Rev Lett 92 (2004) 220802
13C2H2 ndash 14N2 710-12 S Rainville et al Science 303 (2004) 33432S 5010-11 W Shi et al Phys Rev A 72 (2005) 02251016O 1110-11 RS Van Dyck et al Int J Mass Spectrom 251 (2006)
23128Si 2210-11 M Redshaw et al Phys Rev Lett 100 (2008)
093002129132Xe ~10-10 M Redshaw et al Phys Rev A 79 (2009) 012506Existing Penning Traps PENTATRAP
stable nuclides
light masses
closed systems
radiactive highly charged nuclides
masses up to Uranium
open system
Improvement of accuracy by more than one order of magnitude Improvement of accuracy by more than one order of magnitude
Sergey Eliseev SFB-Meeting 9072009
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Accelerator Hall of MPI-K (Heidelberg)
PENTATRAP Lab (basement)
Temperature stabilization 01Kday Pressure stabilization Damping of vibrations lt1 m (active amp passive) Screening from E-fields Al-walls Active compensation of B-fields Helmholtz coils
EBIT
highly charged ions
~34
met
ers
3He4He ion source
EBIT ion source
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
MagnetMagnet MagnetMagnet InsertInsert
Tower ofTower offive trapsfive traps
Sergey Eliseev SFB-Meeting 9072009
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
hellip hellip in new lab Nr2 (PENTATRAP) at MPI-K in new lab Nr2 (PENTATRAP) at MPI-K
Monitor trap
Preparation trap
Precision trap
112
2mm
Preparation trap
Monitor trap
monitoring of B-Field flactuations over the measurement cycle
storagecooling of reference ion ion of interest
substantial reduction of cycle time
reduction of systematics due to temporal B-field flactuations
high precision mass measurements
accuracy ~10-11 eV-level
Sergey Eliseev SFB-Meeting 9072009
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Mass of Neutrino search for new candidatesMass of Neutrino search for new candidates
Proposal IS473 to the ISOLDE Committee CERN (2008)ldquoSEARCH FOR NEW CANDIDATES FOR THE
NEUTRINO-ORIENTED MASS DETERMINATION
BY ELECTRON-CAPTUREldquoYu Novikov K Blaum S Eliseev et Al
Qε=
(69plusmn
14)
keV
T12=444 y
EE=(-12plusmn14) keV=(-12plusmn14) keV
194Hg0+
194Au
80725 K
1-
Qε=
(50plusmn
15)
keV
T12=50 ky
EEasympasymp(-35plusmn15) keV(-35plusmn15) keV
202Pb0+
202Tl
1535 L1
2-
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Type of neutrinoMajorana or Dirac
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellipDetermination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Type of Neutrino Majorana or DiracType of Neutrino Majorana or Dirac
neutrinoless double beta decay
neutrinoless double EC decay
Sergey Eliseev SFB-Meeting 9072009
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
ResonantResonant-less double EC decay-less double EC decay
(ZA)
(Z-1A)
(Z-2A)
ГГεεεε
QQεεεε
BBii(2)(2)
BBjj(1)(1)
22)2()1(
2221
200
41)0()0(
ji
eeres
BBQmMc
Sergey Eliseev SFB-Meeting 9072009
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
εε- transition Qεε (keV) E=Eγ+B1+B2 (keV) Δ=Qεε-E (keV) First prediction
74Se+74Ge 12097(6) 120714(1)(γ+L1+L2) 26plusmn06 D Frekers (2005)
112Sn+112Сd 1919(4) 19256(2)(γ+K+K) -66plusmn40 J Bernabeu et al (1983)
152Gd+152Sm 546(12)5626(K+L1)5428(L1+K)
-16plusmn12-032plusmn120
Z Sujkowski andS Wycech (2004)
164Er+164Dy 237(21) 1901(L1+L1) 47plusmn21 ldquomdashmdashmdashmdashmdashrdquo
Candidates for resonant neutrinoless double-Candidates for resonant neutrinoless double-capturecapture
Starting Project for PENTATRAP Starting Project for PENTATRAP
Sergey Eliseev SFB-Meeting 9072009
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Penning TrapsPenning Traps
with an accuracy up to 10-11
Q-value of a decay
Determination ofneutrino amp anti-neutrino
mass
helliphelliphelliphelliphelliphelliphelliphellip
Type of neutrinoMajorana or Dirac
Determination ofmixing angle 13
Sergey Eliseev SFB-Meeting 9072009
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
)LL(sin2θsin)L
LΔmΔm(sin2θsin1)P(
32
213
2
32221
2322
122
ee ππυυ
Probability of electron-neutrino Probability of electron-neutrino e e disappearance disappearance
meters tens few akeVEmL32 υ
Sergey Eliseev SFB-Meeting 9072009
L32
10 m
eter
s
Liquid Argon
EC-Nuclidesource of monoenergetic e
Proposal NeOsProposal NeOs YN Novikov A Vasiljev Y Giomataris S Eliseev amp JD Vergados
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
Nuclide Produced amount (g)
T12 Eυ =Qε-Bi (keV) L32 (m) Neutrino Flux (s-1)
157Tb 0003 70 y 98(3) ge52 hellip 10 2109
163Ho 0004 4500 y asymp05 asymp08 asymp22 23 26 05-26 109
178W 216 d 239(20) ge803 hellip 24
179Ta 00004 665 d 403 943 40 94 1010
193Pt 100 50 y 438(3) 538(3)hellip 44 54 21014
194Hg 440 y 14(3) 25(3) hellip 14(3) 25(3)
202Pb 5104 y 35(15) 46(15) 35(15) 46(15)
205Pb 200 107 y 35(1) 35(1) 109
Sergey Eliseev SFB-Meeting 9072009
Possible candidates for the neutrino source Possible candidates for the neutrino source
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
Neutrino oscillation length LNeutrino oscillation length L32 32 amp amp mixing angle mixing angle 1313
10 m
eter
s
Liquid ArgonnatPt
Neutrino source Neutrino source 100 kg of natPt contains 01 kg of 193Pt after
1 year of irradiation at a reactor
Count rate Count rate e ndash flux from 01 kg of 193Pt ~ 2middot1014 1s
number of e ndash e interactions ~ 100 eventsyear
Detection of 10 keV recoil electronsDetection of 10 keV recoil electronsChallengeChallenge
1 meter
LAr
Ar-gas
Vee
e
MicromegasMicromegas
Porous shell
Sergey Eliseev SFB-Meeting 9072009
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-
SummarySummary
Sergey Eliseev SFB-Meeting 9072009
Penning traps can have a significant contribution to the neutrino physicsPenning traps can have a significant contribution to the neutrino physics
bull At MPI-K two Penning trap mass spectrometers are set up At MPI-K two Penning trap mass spectrometers are set up to assist the KATRIN ndash experiment (determination of mto assist the KATRIN ndash experiment (determination of m--))
bull We are reviving the neutrino physics in the EC ndash sector byWe are reviving the neutrino physics in the EC ndash sector by contributing to determination of neutrino mass contributing to determination of neutrino mass (PENTATRAP(PENTATRAP 163163Ho) Ho)
determination of mixing angle determination of mixing angle 3232 (PENTATRAP(PENTATRAP NeOs NeOs 193193Pt)Pt)
contributing to neutrinoless double EC decaycontributing to neutrinoless double EC decay (type of the neutrino) (type of the neutrino)
- Folie 1
- Folie 2
- Folie 3
- Folie 4
- Folie 5
- Folie 6
- Folie 7
- Folie 8
- Folie 9
- Do we need to measure the neutrino mass since the antineutrino mass limit is known
- Folie 11
- Folie 12
- Folie 13
- Folie 14
- Folie 15
- Folie 16
- Folie 17
- Folie 18
- Folie 19
- Folie 20
- Folie 21
- Folie 22
- Folie 23
- Folie 24
- Folie 25
- Folie 26
-