muon campus beam transport january 23, 2013 j. morgan 1
TRANSCRIPT
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Muon Campus Beam TransportJanuary 23, 2013
J. Morgan
J. Morgan 2
What we have now – the Pbar source
1/23/2013
J. Morgan 3R. Ray - Director's CD-1 ReviewR. Ray - Mu2e Collaboration Meeting
Recycler Ring
Delivery Ring
Muon Campus
AP-30
AP-10
AP-50
P1 - P2 - M1
M3
MI-8 Line
1/23/2013
TheMuon
Campus
J. Morgan 4
Antiproton SourceBeam lines
AP30
AP50
AP10
AP-1
AP-2 AP-3
Accumulator
Debuncher
D/A
AP0
• A 120 GeV/c proton beam is transported to the Target Station via AP-1 every 2.2 seconds• An 8.89 GeV/c negative secondary beam travels down AP-2 and is injected into the Debuncher• 8.89 GeV/c antiprotons are bunch rotated
and stochastically cooled in the Debuncher, then transferred to the Accumulator via the D/A line
• Antiprotons are accumulated over hours, then transferred to MI via the AP-3 and AP-1 lines
• 8.89 GeV/c protons can be “reverse injected” or sent in the reciprocal direction of the antiprotons for tune-up
0.4 0.2 0 0.2 0.4
0.1
0
0.1
x [cm]dx
/ds
1/23/2013
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Muon Campus Configuration• The Accumulator and D/A line are no longer needed
and will be used for beamline components• M1 is the new name for AP-1, apertures will be
improved to accommodate the larger 8.89 GeV/c primary beam
• AP-2 will be renamed M2 and will be a dedicated beam line for g-2
• The M3 line will connect to the Delivery Ring (Debuncher) in the D30 straight section
• Both the g-2 secondary beam and Mu2e proton beam will be transported to the Ring via M3
• M2 and M3 will have a higher quadrupole density than AP-2 did (~4.4 m vs. ~13.0 m) for g-2
• Extraction, both single turn for g-2 and resonant for Mu2e, are also in the D30 straight section
• The old injection region for AP-2 will become an abort for Mu2e and could be used for proton removal for g-2
• The new extraction line will be called M4• The g-2 line connects M4 to the g-2 Storage Ring
1/23/2013
AP30
AP50
AP10
M1
Protonremoval
M3
Delivery Ring
AP0
g-2
M2
M4
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Repurposing Pbar
AP30
AP50
AP10
AP-1
AP-2 AP-3
Accumulator
Debuncher
D/A
AP0
Antiprotonproduction
AP30
AP50
AP10
M1
Protonremoval
M3
Delivery Ring
AP0
g-2
M2
M4
Muon Campus
1/23/2013
J. Morgan 7
Challenges and Technical Risks• High intensity 8 GeV proton beam in M1 (and M3 for Mu2e)
• Much larger beam size in beamlines upstream of AP0• Beam loss must be kept extremely low• Much higher intensity for Mu2e in Rings enclosure
• Bunch formation takes place in Recycler• Incoming beam has increased momentum spread
• Average cycle time is much faster than for Pbar• Factor of 13 for Mu2e, 26 for g-2• New kicker power supplies needed• Pulsed septum based on Booster BSE
• AP-3 beam line will be reconfigured for compatibility with g-2• Secondary beam line for g-2 (M2) connects to M3 • g-2 requires dense quadrupole spacing to minimize beta functions• Old upstream AP-3 lattice must be matched to downstream M3 lattice for Mu2e
• Beam is injected and extracted into the Delivery (Debuncher) Ring in D30• New M3 to Delivery Ring connection faces logistical challenges• g-2 fast extraction as well as Mu2e resonant extraction must be supported• Mu2e will require substantial radiation shielding for injection and extraction devices
• M4 line must transport both Mu2e and g-2 beams to their experimental halls
Delivery Ring Future injection region
1/23/2013
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AP30
AP50
AP10
M1
Protonremoval
M3
Delivery Ring
AP0
g-2
M2
M4
Muon g-2Beam lines
• The P1, P2 and M1 lines will transport an 8.89 GeV/c proton bunch, 120 ns long, to the Target Station at an average rate of 12 Hz, with 100 Hz bursts (16 bunches, 10 ms interval)
• Downstream of the Target Station, the M2 line will carry the 3.1 GeV/c secondary beam 150 m until it connects with M3
•Some of the pions decay into 3.09 GeV/c muons as they travel down M2/M3•The M2 and M3 lines have an increased quadrupole density to improve muon yield
• The M3 line connects to the Delivery Ring after an additional 130 m and is injected in the 30 straight section
• Muons can circle the 505 meter Delivery Ring as many times as desired
• The abort located in the 50 straight section can be used to remove protons (requires multiple turns)
• 3.09 GeV/c muons are extracted into the M4 line, then bent into the g-2 line for transport to the Storage Ring in the MC-1 building
1/23/2013
Target Station
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• An 8.89 GeV/c proton bunch, 120 ns long, is transported to the Delivery Ring via M1 and M3 (bypassing the Target Station) at an average rate of 6 Hz with 18 Hz bursts
• The 8.89 GeV/c bunch is injected into the Delivery Ring in the 30 straight section with a pulsed septum and kicker
• A 2.5 MHz RF system maintains the short bunch as it circulates in the Delivery Ring
• The proton bunch is resonantly extracted with electrostatic septa and a Lambertson into the M4 line
• The M4 line transports short proton “micro-bunches” to an external Target Station to produce an intense muon beam
• The remaining proton beam that is not resonantly extracted is aborted in the 50 straight section and transported to the abort dump
AP30
AP50
AP10
M1
Abort
M3
Delivery Ring
AP0
g-2
M2
M4
1/23/2013
Mu2eBeam lines
J. Morgan 101/23/2013
Description Project CommentRecycler injection kicker NOvA
Recycler RF upgrade RR AIPRecycler Extraction Kickers RR AIPRecycler extraction/beamline stub RR AIP M1 Final Focus g-2P1,P2 and M1 aperture upgrade DR AIPReconfigure AP-2 and AP-3 g-2 New lines are called M2 and M3Beam transport instrumentation DR AIP Beam transport controls Mu2e Beam transport infrastructure DR AIP Delivery Ring injection DR AIP Delivery Ring modification DR AIP D.R. abort/proton removal DR AIP Delivery Ring RF system Mu2eDelivery Ring controls Mu2e Delivery Ring instrumentation DR AIPResonant extraction from D.R. Mu2e Fast extraction from D.R. g-2 Delivery Ring infrastructure DR AIP Extraction line to split g-2 Upstream M4 lineExtraction line from split to Mu2e Mu2e Downstream M4Extraction line from split to g-2 g-2 Beamline to MC-1 building
Possible Beamline Project Responsibility
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8 GeV protons to the Target Station
•RR to P1 stub line optics has been being integrated into entire line• Needed to reconcile different MAD and OPTIM files• Optimization of optics underway to reduce beam size through lines
•Magnet choices for aperture improvements has been refined• Surplus Tevatron B2 magnets will be used at V714
• Lower beam momentum for g-2 allows the use of weaker and/or shorter magnets in M1, but will limit the peak beam energy to about 40 GeV
• A CDA Cooling Ring dipole will be used at F-17 in place of the C-magnets• Pbar MDC magnets will be used in the HV100 and HV102 bend strings• Smaller aperture trims will be replaced with Pbar NDA and NDB trims
•Beam spot size specification has been reduced• Spot size requirements has been reduced from σxy = 0.55 mm to 0.15 mm
•Final Focus region will incorporate a quadrupole triplet• Final 3Q120 quadrupole will be replaced by three Pbar SQx quads• Triplet configuration will greatly reduce the peak β functions in the M1 line• SQx quadrupoles will have a large enough aperture for high efficiency transmission and small spot
size at the Target•Instrumentation
• Existing BPM, Toroid and SEM/Multiwire systems can be used with minimal modification• Tevatron BLM electronics will be repurposed to upgrade legacy equipment
1/23/2013
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RR to Target MAD file
Meiqin XiaoJim Budlong
120 GeV Pbar production MI to Target Station
8 GeV Muon production RR to Target Station
J. Morgan
Planned improvements
MI-52 Lam. / V701 C-magnets
V714 C-magnets
Tev. F0 Lambertsons removed F-17 C-Magnets
HV100 dipoles
HV102 dipoles
Larger trims
Quad triplet1/23/2013 14
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Final focus region in M1
Valeri Lebedev
1/23/2013
SQx triplet
Vault Wall
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•Target Station to M3 line (M2)• Four magnet quadrupole “triplet” remains at beginning of line
• β functions peak around 80 - 100 m in IQ2 and IQ3 (limiting aperture)• Junction between lines is located 100 – 125 m from Target Vault wall• 4.4 m Quadrupole spacing with 90 phase advance• Power supply requirements and magnet busing yet to be done
•M2 to M3 connection• Original optics plan required the removal of a 20 ton dipole magnet in Right Bends to switch between g-2
and Mu2e•Present design does not require magnet removal, but has six dipole magnets which adds considerable cost•Power supply requirements and magnet busing yet to be done
•M3 line to Delivery Ring•Challenging design constraints to match optics and trajectory into Ring
• Optics design has two elevation changes and a 5 horizontal bend• Confined area for magnet supports in area over Delivery Ring
• Need >30 inches between Delivery Ring and M3 to allow use of existing pbar magnets•Must be compatible with injection scheme into Delivery Ring
• Optics must match and acceptance must be at least 40 pi-mm-mr for g-2•Power supply requirements and magnet busing yet to be done
•Instrumentation•g-2 will use upgraded SEM’s and new ion chambers, possibly wall current monitors•Mu2e will use existing BPM and SEM systems, plus upgraded toroid electronics
Injection lines to Delivery Ring – M2 & M3
1/23/2013
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AP30
AP50
AP10
M1
Protonremoval
M3
Delivery Ring
AP0
g-2
M2
M4
IQ07 → IQ13Remain In Situ
~13.33m separation
M2 M3M2→M3 18.5o Bend
Target Station to Delivery Ring (g-2)AP-2 removed and replaced by M2 line,
which connects to M3 line
1/23/2013
John Johnstone
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M2 to M3 Line Cross-over
1/23/2013
M3
M2
Mod B1 “Switch”
g-2 beam offset ~3.75”
C-magSDE
SDE
5’ somethings
John Johnstone
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AP30
AP50
AP10
M1
Protonremoval
M3
Delivery Ring
AP0
g-2
M2
M4
M2 to M3 Line Cross-overalternative scheme
1/23/2013
John Johnstone
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M3 line into Delivery Ring
1/23/2013
John JohnstoneContinuation of earlier slide
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AP30
AP50
AP10
M1
Abort
M3
Delivery Ring
AP0
g-2
M2
M4
Target Station bypass
Mu2e beam pathto Delivery Ring
1/23/2013
• M3 line will branch from M1 (AP-1) line and bypass Target Station as AP-3 line does now
• M3 line between the Target Station bypass and the M2/M3 line merge needs to be reconfigured to match new downstream lattice (140 m), has not been done yet
• M3 line downstream of M2/M3 line merge must have optics designed to accommodate both g-2 and Mu2e beams
• High intensity 8.89 GeV/c protons instead of 3.1 GeV/c secondary beam, radiation shielding will be required at loss points under service buildings
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•Injection from M3 line• All injection bends are vertical – mature design completed
• Modified Main Injector C-Magnet for initial bend• Injected beam passes through Pbar LQ magnet ~130 mm above centerline• Modified Booster septum magnet provides the greatest bend• Two module injection kicker system puts beam on D.R. closed orbit
• Injection scheme preserves 40 pi-mm-mr acceptance or greater• Is also compatible with Mu2e 8.89 GeV/c protons, except optics match not done
•30 straight section reconfiguration• Cable trays must be relocated to provide room for new beamlines and radiation shielding
•Most Delivery Ring magnets will need to be temporarily removed to facilitate beamline installation
•Logistics are very challenging, work is very time-intensive and involves outside labor•Mu2e Abort and g-2 Proton Removal
•Shared system in the 50 straight section (old AP-2 injection)•Multiple D.R. revolutions required to adequately separate protons from muons
•Extraction to M4 line•Lambertson magnet required to accommodate Mu2e resonant extraction
• Either modified NOvA design (MLAW) or new design•8Q32 quadrupole (from BNL?) at D2Q5•C-Magnet follows quadrupole, identical to what will be used for injection•Dual kicker schemes for both dedicated g-2 running and Mu2e/g-2 running
Delivery Ring
1/23/2013
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Delivery Ring Lattice30 straight section
1/23/2013
g-2/Pbar Debuncher lattice
Mu2e lattice
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•Mu2e• Existing BPMs pick-ups will be reused
• Electronics from both Tevatron and Recycler Ring will be repurposed• Existing DCCT will be used with minor modifications• Tevatron BLM ion chambers and electronics will be repurposed• Existing SEMs will be located in straight sections
•g-2• New Wall Current Monitors
•Pbar BLM’s will be repurposed•Would like to use same cables as Mu2e BLM’s to save money
•Existing SEMs will be located in straight sections
Delivery Ring Instrumentation
1/23/2013
Brian Drendel
Tevatron BLMPbar ion chamber
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Injection line layout – horizontal bend in D30
D30, AP-3 lineCrossover area
D30, AP-3 line above Debuncher, D3Q6 on left
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Delivery Ring Kickers
1/23/2013
• Reuse existing Debuncher kicker magnets• Reduced cost and labor effort• Best combination of size and strength• Power supplies can’t be reused due to fast cycle time
• Kickers rise and fall times do not need to be particularly fast• Single 120 ns bunch in Delivery Ring• 450 ns rise and fall times typical for three kicker magnets in series
• Single power supply can power magnets in series• Keep power supply costs as low as possible• Limited space available in service buildings
• Two Fluorinert skids in AP-30 and AP-50• AP-30 system can be shared by injection and extraction kickers• May be possible to use single AP-30 system to save costs• Magnet loads located in service buildings to avoid radiation problems
• Power supplies based on NOvA design• May be able to reuse some RG-220 cable, PFN spools
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AP30
AP50
AP10
Protonremoval
Delivery Ring
g-2
M4
Kicker locations and rates
Kicker rates InstantaneousMuon g-2/Mu2e
AverageMuon g-2/Mu2e
Delivery Ring Injection 100/17 Hz 12/6 Hz
Abort/proton removal 100/17 Hz 12/6 Hz
Delivery Ring extraction 100/n/a Hz 12/n/a Hz
Abort/proton removal kicker
Injection kicker
Extraction kicker
1/23/2013
Pbar extraction kickers
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Kicker rise and fall times
1/23/2013
Kicker System (modules)Integrated
Field g-2/Mu2e
(Kg-m)
Kick Angleg-2/Mu2e
(mrad)
Rise Time95%/5%
(nsec)
Fall Time95%/5%
(nsec)Flat Top(nsec)
Debuncher Extraction (3) 1.34 4.6 150 140 1,700
Debuncher Injection (3) 1.81 6.1 180 150 1,700
Delivery Ring Injection (2) 0.64/1.31 6.2/4.4 n/a 300 400
Delivery Ring Extraction (2) 0.72/2.8 7.0 300 n/a 400
Delivery Ring Abort (3) 0.63/1.81 6.1 450 n/a 1,700
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Injection Region
Bend angles of Septum, LQ and C-Magnet
Injection regionJohn Johnstone – M3 line optics
1/23/2013
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D30Q D3Q2 D3Q3 D3Q4
3.1 mr QFQF
QD QD
Magnetic SeptumD2Q2QD
Inj. Kicker
25
0
-25
displacement (mm)
C-magnet
50
75
100
3.1 mr
Inj. Kicker
QuadrupoleOffset
125
150
175
200
54.5 mmseparation
136.7 mmseparation
Closed orbit bump
Extraction trajectorywithout bump
Extraction trajectorywith bump
+9.1 mm+12.8 mm -4.2 mm
36.6 mr
29.5mr 37.6 mr
1/23/2013
g-2 vertical injection trajectory(with and without vertical bump)
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Mu2e vertical injection trajectory
1/23/2013
D30Q D3Q2 D3Q3 D3Q4
2.2 mr QFQF
QD QD
Magnetic SeptumD2Q2QD
Inj. Kicker
25
0
-25
displacement (mm)
C-magnet
50
75
100
2.2 mr
Inj. Kicker
QuadrupoleOffset
125
150
175
200
42.2 mmseparation
133.4 mmseparation
+9.1 mm+12.8 mm -4.2 mm
41.7 mr
29.5mr 32.8 mr
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Delivery Ring Mu2e Abort(repurposing and shared-use)
1/23/2013
• Former downstream section of AP-2 used for abort line
• Abort absorber located in Transport tunnel (using existing E760 collimator)
• Relatively low beam power (0.40 kW – designed for 5% of 8 kW beam power) so cooling water system is not needed
• Requires one new Vertical bending magnet and trims
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Proton Removal for g-2•Target Station to Delivery Ring distance will be about 290 meters
• Muon and proton centroids separate by about 40 ns•Injection kickers and abort at D4Q5 is 352 meters (50 ns)•Delivery Ring circumference is 505 meters
• Muon and proton centroids separate by about 70 ns per turn• Bunch length is about 120 ns (possibly with satellites)• Centroid separation to abort on first turn is 91 ns, second turn 161 ns, etc.
•Mu2e abort can be used for g-2 proton removal• Multiple turns required to create a large enough gap between protons and muons
•Mu2e abort has a 450 ns rise time “as is”• Mu2e has a 120 ns bunch length, Delivery Ring revolution period is ~ 1,700 ns• Around 7 turns in the Delivery Ring to remove protons completely• 6 turns to eliminate 90% of protons without disturbing muons
•Existing kickers could rise in 200 ns with a power supply upgrade• Around 5 turns in the Delivery Ring to remove protons completely• Would require 2 power supplies operating in parallel instead of 1, at a cost of about 700 k$
•“Straight through” distance to g-2 is about 425 meters• 90% of the pions will decay “straight through”, >99% after one turn in Delivery Ring
1/23/2013
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Protons slipping in time
1/23/2013
Muon vs. Proton Centroid time difference
(ns)Gap size
(ns)Injection 40 None1st turn at Abort 91 None2nd turn at Abort 161 413rd turn at Abort 231 1114th turn at Abort 301 1815th turn at Abort 371 2516th turn at Abort 441 3217th turn at Abort 511 3918th turn at Abort 581 461
Drawing by T. Leveling
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Delivery Ring Extraction
•Extraction layout is driven by resonantly extracted beam for Mu2e• Electrostatic septa surrounding D2Q3 bend beam horizontally ~1 mr each• Mu2e resonantly extracted protons have much smaller emittance than g-2 muons• Lambertson is required for Mu2e to work with electrostatic septa
• A large aperture quadrupole is required at D2Q5, larger than Pbar LQx• An 8Q32 quadrupole and C-Magnet both provide additional vertical bends
• Mu2e has Delivery Ring optics that are unfavorable for maximizing g-2 Ring acceptance• Different optics and different horizontal trajectories are needed for g-2 and Mu2e
• A large horizontal bump across the extraction region is used for g-2•g-2 needs an extraction kicker for beam to enter the M4 line
• Best location for kickers is where Mu2e septa will eventually reside• A two kicker system will be used for g-2 dedicated running
• Existing Pbar kickers can be used as-is• Two kicker layouts are planned for g-2 dedicated running vs. “dual mode”
•For dual mode, a single module can be used(a benefit of the 3.09 GeV/c momentum) with a altered impedance to increase strength
•Extraction scheme provides 40 pi-mm-mr acceptance for g-2 and a common extraction channel for both experiments
1/23/2013
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g-2 extraction trajectoriesHorizontal bump across extraction region
(note different scales)
Bump created by motorized quadrupoles at 203, 204, 206 and 207
1/23/2013
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Mu2e extraction trajectory(horizontal bump removed)
1/23/2013
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Extraction kicker layouts
g-2 operation and Mu2e beamline commissioning(uses Pbar EKIK modules with 12.5Ω impedance)
Dual mode – either g-2 or Mu2e can run(uses Pbar IKIK modules with 8.33Ω impedance)
1/23/2013
39g-2 operation and Mu2e commissioning
Horizontal bend (5)Injection kickers
Injection Septumand C-magnet
Extraction Lambertsonand C-magnet
Extraction kickers
Vertical bends
Vertical bend
1/23/2013
40
Horizontal bend (5)Injection kickers
Injection Septumand C-magnet
Extraction Lambertsonand C-magnet
Vertical bends
Vertical bend
1/23/2013
Extraction septa (Mu2e)
Extraction kicker (g-2)
Dual running mode configuration
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Extraction Region
Bend angles of Lambertson, LQ and C-Magnet
Extraction regionCarol Johnstone – M4 line optics
D2Q4LambertsonD2Q5
56.3 mr 17.3 mr 38.0 mr
SQC8Q32
Modified ILA D2Q8
SQC
D2Q6SQD
CMAGModified ICA
EDWA
D2Q7SQC
EQ1SQA
NDA
D2Q9SQC
MDC
EVT1NDA
EHT2NDA
D2Q10SQC
D2Q11SQC
D2Q12SQC
111.6 mr65.5 mr
65.5 mr
EHT1
SQD
EQ3SQD
EQ4SQD EV1EV2MDC
EV3
EQ5SQD SQC
EQ2EQ7
SQD
StubWall
EQ6
D2B8SDD
D2B7SDDSDD
D2B11
1/23/2013
8Qx
circulating beam
upstream
downstream
8Q32 40 pi-mm-mr beam envelopes
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Extraction beamlines (M4 and g-2)•M4 Line
• First 20 m of line must fit above Delivery Ring, requiring at least 30” separation• Elevation change to 48” above Delivery Ring is completed before Left Bend• Location of Left Bend is critical to location of MC-1 (g-2) and Mu2e buildings
• MC-1 building is highly constrained by road and utility corridors• Mu2e building also constrained to east and north (wetlands)
•Process of eliminating mechanical conflicts and using available pbar magnets of known designs has shifted bend downstream from what was shown for Mu2e CD-1 Review
•Left Bend dipole configuration has been changed to increase total bend to ~40°•Original concept of “split” between M4 and g-2 now more difficult to design
•M4 line from Left Bend to Mu2e must incorporate several features•Extinction•Diagnostic dump•Final Focus, 2.4° downward slope and 2 foot elevation change to target
•Has not been demonstrated that 40 pi-mm-mr acceptance will be preserved for g-2•Instrumentation: Wall Current Monitors and new SWICs
•g-2 Line•Optics design is conceptual, less mature than other lines•Geometry of “split” between M4 and g-2 lines is still conceptual•Momentum collimation needs to be incorporated into bend region•An additional elevation change of 5 feet is required to get to g-2 Storage Ring level•“Match” into Storage Ring will drive design of downstream part of line…need flexibility•Instrumentation: Ion Chambers and SWICs from BNL
1/23/2013
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External beam lines
1/23/2013
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M4 line opticsDelivery Ring through Mu2e collimation section
1/23/2013
J. Morgan
Carol Johnstone
Split between the M4 and g-2 lines
• g-2 line splits from M4 line in the middle of the left bends
• Bend angle of third dipole is 6° for Mu2e and 3° for g-2
• Both beams pass through large aperture quadrupole after third dipole (“D” quadrupole)
• Separation angle between beamlines is 4.5°
• BNL quadrupole can be inserted in g-2 line upstream of Mu2e SQC
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J. Morgan
Carol Johnstone
New concept for split between M4 and g-2
• g-2 line separates from M4 vertically upstream of Left Bend
• Elevation change to Storage Ring height is done in one step
• Has implications for tunnel geometry and radiation shielding in Left Bend region
• Simplifies optics design because of increased length
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g-2 Line
1/23/2013
• g-2 line splits from M4 line in the middle of the left bends
• Mu2e Left Bend is 40°, g-2 is 28°
• Momentum collimation will be integrated into Left Bend
• g-2 line is roughly 50 m long (longer with vertical split scenario)
• BNL 4Q24 quadrupoles and 4D16 trims will be used in the line
• Vertical dogleg for elevation change to experiment
• Final focus and matching to Storage Ring will be designed in collaboration with Ring Team
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g-2 Storage Ring
10 cm beam access port
1/23/2013
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Storage Ring lattice functions and dispersion
1/23/2013
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Small Quadrupoles (SQ)
SQA SQB SQC SQD SQE
Total Magnets (129) 46 14 42 19 8
Accumulator and beam line magnets by family
SQ LQ SD LD MDC/CDC 6-x-120/SDE
Accumulator 54 30 16 12 2 0
D/A line 7 0 0 0 2 0
AP-2 (except 3 for abort) 30 0 0 0 2 6
AP-3 (after Vault) 26 0 4 0 2 0
Magnet Storage 12 4 4 0 2 5
Total 129 34 20 12 8 11
Large Quadrupoles (LQ)
LQA LQB LQC LQD LQE LQF
Total Magnets (34) 6 4 12 0 6 6
Magnets made available by reconfiguration of Rings and beam lines
1/23/2013
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Small aperture Quadrupoles
SQA SQB SQC SQD SQE 4Q16 4Q24 5Q36
Available Magnets (152) 46 14 42 19 8 3 18 2
Estimated needs (~128)
Injection line needs (~65) In Development – approximately 65
Extraction line needs (48) 15 2 14 6 1
Muon g-2 line (~15) In Development – approximately 15
Large aperture Quadrupoles
LQA LQB LQC LQD LQE LQF 8Q24 8Q32
Available Magnets (40) 6 4 12 6 0 6 4 2
Extraction line needs (11) 0 0 5 5 0 0 0 1
Other beam lines In Development – Unknown, but likely <5
FNAL and BNL Quadrupole availability and needs for beam lines
SQ LQ 4Q24
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Dipoles
B2 CDA MDC EDWA SDESDEW/SDFx
SDB SDC CMAG
Available Magnets (43) 4 8 8 0 3 10 6 4 0
Estimated needs (46) 1 9 22 1 2 6 2 1 2
P1/P2/AP-1 1 1 8
M2 5 2
M3 4 2 1 1
M4 8 1 6 1
g-2 line 5
FNAL dipole availability and needs for beam lines
1/23/2013
Trim dipoles
NDA NDB 4D16 LEP
Available Magnets (92) 36 34 12 10
Extraction line needs (80) 34 31 9 6
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Accelerator Controls
• The communications duct that carries all Ethernet and Controls signals between the Muon service buildings and the control system will be dug up during extraction beamline construction.
• New fiber optic cable will be pulled to AP-30 to reestablish Ethernet connectivity and replace the functionality of the controls links heliax cables.
• Cost for this ($70K M&S plus labor) should be absorbed by g-2 or FESS GPP.
• Fiber optic and heliax cable provide controls connectivity between the three Delivery Ring service buildings via cable pulls that go through the accelerator tunnel.
• Careful assessment of radiation levels where fiber optic controls cables exist must be taken into account.
• Single mode fiber optic cable pulled on the Accumulator side of the enclosure should provide the necessary functionality at a minimal cost.
• More robust radiation hardened upgrade options are available ($45K - 90K M&S plus labor).
• Controls Ethernet that runs to the AP-0, F23 and F27 buildings use legacy systems that will be asked to perform at the peak of their abilities.
• It is assumed the existing networks will function at an adequate level.
• Upgrade options ($50K - $100K M&S plus labor) are available.• Fiber optic cables will be pulled to the Mu2e and MC-1
service building to provide controls connectivity.• Cost ($35K M&S plus labor) for this will be covered in the
Mu2e External Beamlines Controls BoE.
X
Communications Duct bank to be replaced
No fiber to AP0 (Legacy Thickwire)
No fiber to F23 & F27 (wireless)
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AP30
AP50
AP10
M1
Protonremoval
M3
Delivery Ring
AP0
g-2
M2
M4
Coordinating AIP tasks with Mu2e and g-2
• Project management of the AIP shares the same personnel with L3 managers in the Mu2e and g-2 projects• Improvements to transport lines and Ring can
be made with the interests of both experiments in mind
• Weekly L3 meetings provide an opportunity to communicate directly with stakeholders in the Mu2e and g-2 projects
• Milestones for AIP tasks can be built into the g-2 and Mu2e WBS
• AD Muon Department has responsibility for making Muon Campus concept work
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Present status of beamlines•Recycler to Target Station line (P1 stub, P1, P2 and M1)
• RR to Target MAD file has been built, optics optimization in progress• Aperture improvement design has matured• g-2 final focus will incorporate a quadrupole triplet to achieve desired beam spot size
•Injection line (M2/3 and new Delivery Ring connection)• Current design has small β functions after initial quadrupole triplet in M2• M2/M3 line connection design needs to be refined to reduce costs• Design of downstream end of M3 line has eliminated most mechanical conflicts• Upstream M3 match for Mu2e is yet to be done
•Delivery Ring• Injection design scheme can accommodate both g-2 and Mu2e• Mu2e abort can also be used for g-2 proton removal• 30 straight section reconfiguration has project leader due to its complexity• Extraction design driven by Mu2e, but preserves 40 pi-mm-mr acceptance for g-2
•Extraction beamlines (M4 and g-2)• Upstream section of line has mature design with no known mechanical conflicts• Left Bend location and strength has been finalized – important for buildings• g-2 line “split” from M4 line is being redesigned to simplify g-2 line design• g-2 line optics design is at the concept level• Completing the initial optics design for the g-2 line will follow finishing the M4 line
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Summary
• Antiproton Source will be substantially modified to support Mu2e and g-2• The Accumulator Ring and D/A line will no longer be needed, providing components for the
newly configured beamlines• 8.89 GeV/c primary beam will require aperture improvements in the beamlines between the
Recycler and g-2 Target Station to keep losses low• The Debuncher will become the Delivery Ring, operating at a much faster cycle time with
greatly increased intensity during Mu2e operation• A significant amount of the beamline upgrades will be managed as an AIP
• Mu2e and g-2 Accelerator L2 manager must track AIP project progress• Some tasks on g-2 project are also needed for Mu2e
• Communication between AIP, g-2 and Mu2e project is a high priority• Management structure set up to facilitate communication and creating an integrated plan for
the Muon transport lines and Delivery Ring• Overall, there is a sound plan in place for the Muon Campus
• Initial optics work has not been completed for M3 match and g-2 line• M2, M3 and g-2 lines only have very preliminary cost estimates• Primary beamlines, Delivery Ring and M4 lines have gone through value engineering, others
have not
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