Positron Source General Update M. Kuriki(Hiroshima U./KEK) ALCW2015, 20-24 April 2015,Tsukuba/Tokyo,...
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Transcript of Positron Source General Update M. Kuriki(Hiroshima U./KEK) ALCW2015, 20-24 April 2015,Tsukuba/Tokyo,...
![Page 1: Positron Source General Update M. Kuriki(Hiroshima U./KEK) ALCW2015, 20-24 April 2015,Tsukuba/Tokyo, Japan.](https://reader035.fdocuments.net/reader035/viewer/2022070410/56649f165503460f94c2cc68/html5/thumbnails/1.jpg)
Positron Source General Update
M. Kuriki(Hiroshima U./KEK)
ALCW2015, 20-24 April 2015,Tsukuba/Tokyo, Japan
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ILC Positron Source
6GeV Electron Lianc Positron Capture & Booster
Rotating Target
To DR
Undulator e+ source (Baseline)
E-driven e+ source (Technical backup)
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Undulator Positron Source
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Undulator Positron Source Positron can be polarized (30-60%). Relatively less heat load on target. Require >100GeV drive beam. Share the e- beam
for collision. The pulse structure is fixed, 1ms. Need physical path length adjustment. Undulator section is up to 230m. System demonstration prior to the construction is
difficult.
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Positron Yield TDR parameter (150 GeV drive beam) gives
1.5~Ne+/Ne-. 240 GeV CME (120GeV drive beam) gives much
less e+. Undulator extension (192.5m) and parameter re-
optimization recover the yield. (LC-REP-2013-019, A. Ushakov) Parameter Value
Length 147m
Period 11.5mm
K 0.92
Peak field 0.86T
1st Harm. 10.1 MeV
Driver Beam 150 GeV
A. Ushakov
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Positron Yield TDR parameter (150 GeV drive beam) gives
1.5~Ne+/Ne-. 240 GeV CME (120GeV drive beam) gives much
less e+. Undulator extension (192.5m) and parameter re-
optimization recover the yield. (LC-REP-2013-019, A. Ushakov)
Parameter Value
Length 147m
Period 11.5mm
K 0.92
Peak field 0.86T
1st Harm. 10.1 MeV
Driver Beam 150 GeV
A. Ushakov
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Target Prototype (Undulator) High speed rotation (2000rpm) with 1m radius makes 100 m/s. The water-cooled high-speed rotating wheel in a high vacuum is
not fully technically demonstrated. Ferro-flulid seal test is not very successful in LLNL. Need a full scale prototype:
Same weight Water cooling
Alternative proposals: Radiation cooling Friction cooling
J. Gronberg
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Target Prototype (Undulator) High speed rotation (2000rpm) with 1m radius makes 100 m/s. The water-cooled high-speed rotating wheel in a high vacuum is
not fully technically demonstrated. Ferro-flulid seal test is not very successful in LLNL. Need a full scale prototype:
Same weight Water cooling
Alternative proposals: Radiation cooling Contact cooling
![Page 9: Positron Source General Update M. Kuriki(Hiroshima U./KEK) ALCW2015, 20-24 April 2015,Tsukuba/Tokyo, Japan.](https://reader035.fdocuments.net/reader035/viewer/2022070410/56649f165503460f94c2cc68/html5/thumbnails/9.jpg)
Radiation cooling for Undulator e+ source2-7 kW from Beam
44coolTTAGW
Radiation cooling
• Heat transfer• thermal contact target and
radiator material• Mechanical stability of the
system.
Rotation target
Stationarycooler
P. Sievers, S. Riemann, A. Ushakov ,and F. Dietrich
5kW average cooling
Radiator temp. 250 deg.C
Cooler temp. 20 deg. C
Surface area 1.65m2
etarget0.25
eCu0.70
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Flux Concentrator Sandwich structure of coils and concentrator plates. LLNL experiment shows 1ms flat top. Things to do;
Improve the pulse-shape quality (PFN). Install ceramic spacer. Full power 5Hz operation with cooling.
J. Gronberg
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E-driven Positron Source
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E-Driven ILC Positron SourceThe conventional way to generate e+ :
6 GeV electron with W-Re target. Manipulating the pulse structure(2700/64ms);
The heat load on the target is manageable < 26 J/g.Tangential speed is <5 m/s.
13
Electron Lianc
Positron Booster
Positron Capture
Rotating Target
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E-Driven ILC Positron SourceThe conventional way to generate e+ :
6 GeV electron with W-Re target. Manipulating the pulse structure(2700/64ms);
The heat load on the target is manageable < 26 J/g.Tangential speed is <5 m/s.
14
Electron Lianc
Positron Booster
Positron Capture
Rotating Target
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Positron YieldYield was evaluated with simulations.By optimizing the parameters, 3.0x1010 e+ (50% margin) is obtained in DR acceptance.
8mm, 5T
After ECSDR acceptance
Y. Seimiya, M. Kuriki
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Target R&D (300Hz e-driven)
A seal running test of 1 week at 417rpm: No problem at all.Another test of the seal after 3.2 MGy irradiation: Viscosity is changed, but no vacuum problem. Expected radiation dose at the seal is 1.5 MGy/year.With a carefully designed shield, the radiation damage on the seal is manageable .The prototype which is reasonably compatible to the real one, will be manufactured in two years.
ferromagneticfluid seal
air vacuum
T. Omori, T. Takahashi
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Ar purge seal test
The seal dosed 3.2 MGy is examined with Ar purged chamber.
Rotation : 0-600 rpm.
No leak was found. (m/q=28 and 32 are N2 and O2 from air)
FF seal
Ar Vac.
Air atmospher
RGA
Ar(40)
O2(32)
N2(28)
T. Omori
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Pulse Structure and Beam-loading Positrons are accelerated by triplet multi-bunch pulse. Transient beam-loading should be compensated, otherwise,
the beam is not accepted by DR. Compensation with AM is proposed by J. Urakawa. A proof-of-principle experiment was carried out at LUCX/ATF.
It works!
44 bunches6.15ns spacing0.55A
44 bunches6.15ns spacing0.55A
100nsRF Voltage
RF pulse RF pulse
J. Urakawa, M. Fukuda
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Footprint Compatibility
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■Conventional ■ Undulator
Distance from IP (km) 2.1 1.5 1.3 1.1 0.9 0.7 1.9 1.7 2.5 2.3 0.5 0.3 2.9 2.73.13.3
•
Footprint Compatibility Accommodate both
sources. Maximize the flexibility. Minimize additional
engineering works.
T. Omori
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Conclusion Status of ILC positron source (Baseline:
Undulator, Technical backup : E-driven) is presented.
Undulator positron source can provide enough e+, even at 240 GeV CME by optimizations.
There is some progress on the fast rotating target for the undulator: water, radiation, and friction cooling.
300Hz e-driven can provide enough e+. A slow rotating target looks promising. A proof of principle experiment of AM
beam-loading compensation was done. Footprint compatibility is under
consideration to minimize the additional works on the engineering.
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