VELA and CLARA Vacuum System DesignsAllow development of new accelerator technologies within ASTeC...
Transcript of VELA and CLARA Vacuum System DesignsAllow development of new accelerator technologies within ASTeC...
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VELA and CLARA
Vacuum System Designs
Keith Middleman
Vacuum Science Group
ASTeC, Daresbury
UK
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Introduction • VELA – Versatile Electron Linear Accelerator
• CLARA – Compact Linear Accelerator for Research and
Applications
• VELA Overview
• 3 main areas of vacuum design:
– VELA Modelling + Results
– Differential Pumping system for Laser Transport
– Shielding of total pressure gauges
• CLARA plans and latest design
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The Versatile Electron Linear Accelerator Beam Energy 4 - 6 MeV
Bunch Charge 10 - 250 pC
Bunch length (σt,rms) 1 - 10 ps
Normalised emittance 1 - 4 m
Beam size (σx,y,rms) 1 - 5 mm
Energy spread (σe,rms) 1 - 5 %
Bunch repetition rate
1 - 10 Hz (ALPHA-X gun)
1 - 400 Hz (with high rep. rate gun in the future;
klystron and laser specified for 400 Hz)
£2.5 million capital investment from
UK government
S-band RF Photoinjector using a Cu
photocathode
Allow development of new
accelerator technologies within
ASTeC
Available for industry to test their
technologies and take them from
prototypes into market products
Industrial and Scientific support
(e2v, Rapiscan, Strathclyde University
etc)
1st industrial users September 2013
– Rapiscan
Further industrial use this year –
Siemens, AWE and Rapiscan
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Versatile Electron Linear Accelerator
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VELA conductance limited
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VELA Modelling
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VELA Injector Pictures
Reality of seeing the photoinjector was different to the drawings supplied.
Injector area had to be remodelled and an additional SIP added due to the trapped volumes
and conductance limitations.
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Laser Transport Path
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Initial Design
Boundary Conditions:
• 1E-5 mbar for Mirror Box. Sticking Coefficient = 1
• VELA Lightbox – Sticking Coefficient = 1
• 10mm tube diameter
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Pressure at VELA Lightbox for Initial
Design
10-8
10-7
10-6
0 0.2 0.4 0.6 0.8 1
Pressure at EBTF Lightbox for Initial Design
Sticking Coefficient
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2nd Design
Boundary Conditions:
• 1E-5 mbar for Mirror Box. Sticking Coefficient = 1
• VELA Lightbox – Sticking Coefficient = 1
• 10mm tube diameter
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Pressure at VELA Lightbox for 2nd
Design
10-9
10-8
10-7
10-6
0 0.2 0.4 0.6 0.8 1
Pressure at EBTF Lightbox for 2nd Design
Sticking Coefficient
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3rd Design
Boundary Conditions:
• 1E-5 mbar for Mirror Box. Sticking Coefficient = 1
• VELA Lightbox – Sticking Coefficient = 1
• 10mm tube diameter
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Pressure at VELA Lightbox for 3rd
Design
10-9
10-8
10-7
10-6
0 0.2 0.4 0.6 0.8 1
Pressure at EBTF Lightbox for 3rd Design
Sticking Coefficient
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4th Design
Boundary Conditions:
• 1E-5 mbar for Mirror Box. Sticking Coefficient = 1
• VELA Lightbox – Sticking Coefficient = 1
• 8mm tube diameter
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Pressure at VELA Lightbox for 4th
Design
10-9
10-8
10-7
10-6
0 0.2 0.4 0.6 0.8 1
Pressure at EBTF Lightbox for 4th Design
Sticking Coefficient
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Pressure at VELA Lightbox
Compared for all Designs
10-9
10-8
10-7
10-6
0 0.2 0.4 0.6 0.8 1
Pressure at EBTF Lightbox Compared for all Designs
Initial Design2nd Design3rd Design4th Design
Sticking Coefficient
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Results and Recommendations
• Maximum pressure difference achievable between Mirror Box and
VELA is just under 4 orders of magnitude.
• Further improvement only possible if we can increase the distance
between the Mirror Box and VELA or further reduce the laser
aperture requirement down from 10mm.
• Recommendation would be to improve the vacuum in the Mirror Box
down to 1E-6 mbar. This should allow us to achieve E-10 mbar in
the VELA lightbox and give us some contingency.
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Total Pressure Gauge Shielding
• Given the low energy of the electron beam there was some concern about the impact of stray magnetic fields
• Vacuum equipment involves SIP’s and IMG’s both of which have stray fields.
• Testing done on items of vacuum equipment to verify whether there was a problem. Items tested include: – 400 l/s Sputter Ion Pump (SIP) – used in various locations
– 40 l/s Sputter Ion Pump (SIP) – used in one location, on the waveguide connected to the RF photoinjector
– Inverted Magnetron Gauge (IMG) – used in various locations
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Total Pressure Gauge Shielding
•The shielding is 6mm thick
•The downside of such a large piece of magnetic shielding is that it has an
impact on gauge performance and affects pressure readings
•Unfortunately the effect is non linear across the pressure range, as a result
calibration of the IMG gauges with the shields on has been done.
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Calibration Run for IMG + Shielding
• Results for the calibration of multiple gauges with shielding.
PTB IMG_1 IMG_1 C/F IMG_2 IMG_2 C/F IMG_3 IMG_3 C/F
2.98E-09 1.14E-08 3.82 3.70E-08 7.42 2.40E-08 8.05
5.07E-09 1.84E-08 3.62 5.59E-08 7.02 3.38E-08 6.67
9.14E-09 3.21E-08 3.52 8.35E-08 6.14 5.22E-08 5.71
3.01E-08 1.15E-07 3.81 1.81E-07 6.02 1.81E-07 6.02
5.20E-08 1.59E-07 3.06 2.82E-07 5.42 3.18E-07 6.12
9.09E-08 2.67E-07 2.93 4.35E-07 4.78 4.35E-07 4.78
3.14E-07 7.58E-07 2.42 8.96E-07 2.85 8.96E-07 2.85
5.06E-07 1.16E-06 2.30 1.42E-06 2.81 1.42E-06 2.81
9.15E-07 1.95E-06 2.13 2.33E-06 2.54 2.46E-06 2.69
2.78E-06 5.52E-06 1.99 6.44E-06 2.32 6.44E-06 2.32
5.04E-06 1.02E-05 2.02 1.15E-05 2.29 1.15E-05 2.29
9.00E-06 1.80E-05 2.00 2.08E-05 2.31 2.08E-05 2.31
2.00E-05 4.08E-05 2.04 4.35E-05 2.17 4.65E-05 2.33
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CLARA
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CLARA front end terminating
module – to be discussed
New CLARA Service trays
VELA ….existing New laser extended
from existing VELA
CLARA Front End Overview
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MODULE 1 RF screen Bellows
~5mm squeezed too
tight – but note valve!? LINAC1
draft model received
from R.I. 02-03-14
LINAC 1 support
design?
Solenoids… no input or
guidance on requirements so
far…assume VELA gun type
YAG screen
New design – or
alternate VELA
design to be decided
RF screen Bellows
Waveguide coupler
…to be designed
BPM
Stripline
VELA type
WCM
VELA type
HV Corrector
Type 1
HRR Gun
(with DLS solenoid)
Photocathode
loadlock
RF Screen
Valve HV Corrector
Type 1
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HRRG Modelling
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HRRG Model – NEG coating
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CLARA NEG coating
140 160 180 200 220 240 260 280 300 3200.01
0.1
1
CO
stic
king
pro
babi
lity
140 160 180 200 220 240 260 280 300 3201 10
4
1 103
0.01
0.1
Ti-Zr-Hf-V
Hf-Zr-V
Ti-Zr-Hf
Ti-Hf-V
Ti-Zr-V
Ti-Zr
Zr-V
Zr
Activation temperature [ C]
H2
stic
king
pro
babi
lity
140 160 180 200 220 240 260 280 300 3200.01
0.1
1
10
CO
pum
ping
cap
acity
• Ti-Zr-Hf-V is the best
• Hf-Zr-V, Ti-Zr-Hf, Ti-Hf-V and
Zr are comparable
• Ti-Zr-V is lower
• Zr-V (best binary alloy) has the
lowest activation temperature
O.B. Malyshev et al Vacuum 100 (2014) p26-28
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Conflat space savings
U Slots – for each flange
reduce by 1 flange length
(12mm)
U Slots Vacom QCF
ISO standard CF knife edge UHV
flange but no bolt extraction – uses
chain ring clamp system instead.
Uses annealed copper CF gaskets.
Tested at CERN & Frascati
What are people’s experiences? A good solution?
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New heater coating development for bakeout
Any other such solutions, experiences?
• Developed by 2D heat
• Partial oxidation of Ni-
Cr-Fe alloy
• Advantages over
conventional
techniques
• Permanently in place
• Coating 0.3mm thick
• Intimately bonded