The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

28
The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005

Transcript of The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Page 1: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

The CLIC accelerating structure development program

Walter WuenschCARE0523 November 2005

Page 2: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

The CLIC design gradient of 150 MV/m was first achieved in a CLIC built structure tested at SLAC in 1994. Pulse length 150 ns.

11.424 GHz0.114 a/λ 0.011 vg/c CopperDiamond turnedVacuum brazedPeak Eacc 153 MV/m150 ns69 MWPeak Es 326 MV/m46 hr conditioning

Page 3: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

So why does CLIC still have a high-gradient development program?

The a/λ=0.114 of this structure is low compared to accelerating structures in linear collider parameter lists

so if you used it you would expect to get

higher wakes, higher emittance growth and consequently an inefficient machine

but raising the a/λ immediately lowers achievable gradient (NLC structures)on the other hand

shortening the pulse length increases achievable gradient (CTF2 structures) but this again is inefficient

Page 4: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

The other big high-gradient effect we face is pulsed surface heating:Here again we face a compromise between gradient and efficiency especially through damping features.

Our development program seeks to establish solutions for

high gradient combined with

high efficiency

Page 5: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

New materials for higher gradient for fixed geometry and pulse parameters – for both rf breakdown and pulsed surface heating. We need to generate our own rf breakdown and fatigue data. Many many technological issues.

rf design for low surface field, E and H, structures – fully three dimensional geometries. Demanding computation and fully 3-d micron-precision machining.

rf design for short pulses – Very strong damping. Demanding time domain computation and fully 3-d micron-precision machining.

Fully integrated optimization procedure – optimization of structures and linac made together because the interplay of rf efficiency and emittance growth is not trivial.

Our main lines of attack

Page 6: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

rf design for low surface field structuresand

short pulses

Page 7: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Hybrid Damped Structure (HDS)Combination of slotted iris and radial waveguide (hybrid) damping

results in low Q-factor of the first dipole mode: ~ 10

Page 8: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

HDS cell designSurface magnetic field Surface electric field

Page 9: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

HDS 60-cells Cu prototypeHigh speed 3D-milling with 10 μm precision

Page 10: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

New materials for rf breakdown and pulsed surface heating

Page 11: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

30 GHz testing results: Cu, Mo and W iris

0 0.5 1 1.5 2 2.5 3

x 106

0

50

100

150

200

No. of shots

Pe

ak

Ac

ce

lera

tin

g f

ield

(M

V/m

)

3.5 mm tungsten iris3.5 mm tungsten iris after ventilation3.5 mm copper structure3.5 mm molybdenum structureCLIC goal loadedCLIC goal unloaded

16 ns pulse length in CTF2

Breaking news! Longer pulses are being achieved in a new Mo iris test! Progress report next week in the CTF3 collaboration meeting!

Page 12: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

30 GHz accelerating structure testing area in CTF

Page 13: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Circular structures:Mo iris – under testCu 2π/3Cu π/2W iris

HDS60, 60, Cu

HDS11, 60:Cu,Mo,stainless steel,Ti, Al

53 mm

30 GHz testing program in CTF3

Page 14: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

CLIC X-band testing at NLCTA

W, 93 MV/m 70 ns,ongoing

Mo, 87 MV/m, 30 ns,conditioning strategy?

Planned, Cu and Mo HDS

Page 15: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Sphere / Plane geometry

HV supply

0 to + 12 kV

UHV

Sample

Tip

A-meter

Field Emission Measurements

HV supply

0 to + 12 kV

UHV

Sample

Tip

Q-meter

Scope

CSwitch

Breakdown MeasurementsSwitch

dc spark: materials, preparation techniques, breakdown physics

Page 16: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

A B

0 200 400 6000

100

200

300

400

500

600

Number of Sparks

10-910-810-710-6

0 200 400 600 800 1000 1200 1400 16000

100

200

300

400

500

600

Ebr

eakd

own [M

V/m

]

Number of Sparks

10-910-810-710-6

Pre

ssur

e [m

bar]

(b)(a)

0 20 40 60 80 100 120 1400

50

100

150

200

250

300

Ebr

eakd

own [M

V/m

]

Number of Sparks

1E-10

1E-8

1E-6

1E-4

P [m

bar]

0 50 100 150 200 2500

50

100

150

200

250

300

Ebr

eakd

own [M

V/m

]

Number of Sparks

1E-10

1E-8

1E-6

1E-4

P [m

bar]

1E-9 1E-8 1E-7 1E-6 1E-5200

250

300

350

400

450

500

Air Oxygen "Free" Air CO Argon

Ebr

eakd

own [

MV

/m]

Pressure [mbar]

MoCu

Mo CO

air

dc spark example: effect of vacuum level on breakdown level

Page 17: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Fatigue strength of materials

Page 18: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Pulsed Laser Fatigue Tests

Ø50mm

Diamond turned test sample, Ra 0.025µm

• Surface of test sample is heated with pulsed laser. Between the pulses the heat will be conducted into the bulk.

• The Laser fatigue phenomenon is close to RF fatigue.

• The operating frequency of the pulsed laser is 20 Hz -> low cycle tests.

• Observation of surface damage with electron microscope and by measuring the change in surface roughness.

• Tests for CuZr & GlidCop in different states under way.

Laser test setupRed curve – CLIC RF pulseBlue curve – Laser pulse

Page 19: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Pulsed Laser Fatigue Tests

Cu-OFE at 106 cycles, ΔT=90ºCFatigued surface

CuZr at 106 cycles, ΔT=90ºCNo fatigue.

Page 20: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Ultrasound Fatigue Tests

• Cyclic mechanical stressing of material at frequency of 24 kHz.

• High cycle fatigue data within a reasonable testing time. 1010 cycles in 5 days.

• Will be used to extend the laser fatigue data up to high cycle region.

• Tests for Cu-OFE, CuZr & GlidCop under way.

Ultrasound fatigue test samples

Ultrasound fatigue test setupAir Cooling

Fatigue test specimen

Calibration cardmeasures the displacement amplitude of the specimen’s tip

Page 21: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Diamond turned specimen before cyclic loading The same specimen after 3*106 cycles, crack initiated

at the region of the maximum stress

Ultrasound Fatigue Tests

Applied Stress is calculated in Ansys

Maximum stress 200 MPa

Page 22: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Putting it all together: investigation of HIP,Hot Isostatic Pressing of Mo with CuZr

Page 23: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Fully integrated optimization procedure

Page 24: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

OptimizationAccelerating structure parameters:fixed: <Eacc>= 150MV/m, f= 30GHz,

varied: δφ = 50o - 130o,

a/= 0.1 - 0.25, d/ = 0.025 - 0.1, Nb, Ncells, Ncycles

Beam dynamics input:Wt,2 = 20V/pC/mm/m for N=4x109

N, Lbx dependencies of a/

rf breakdown and pulsed surface heating (rf) constrains:Esurf < 378 MV/m, T < 56 K, Pintp

1/2 < 1225 MWns1/2

Optimization criterionLuminosity per linac input power:

∫Ldt/∫Pdt ~ Lb×η/N

Several million structures considered in the optimization

Page 25: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Parameters versus maximum Pin

Δφ = 60o

Ncycles = 8

Page 26: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Parameters of HDS140-Mo

154

190

363 360

43.555.4

172

Page 27: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

Dipole mode wakes in hds140

Page 28: The CLIC accelerating structure development program Walter Wuensch CARE05 23 November 2005.

acknowledgements

Claude Achard

Chris Adolphsen

Husnu Aksakal

Daniel Allard

GonzaloArnau-Izquerdo

Hans Braun

Sergio Calatroni

Georges Carron

Ahmed Cherif

Roberto Corsini

Stephane Deghaye

Jean-Pierre Delahaye

Steffen Doebert

Alexej Dubrovski

Raquel Fandos

Gunther Geschonke

Alexej Grudiev

Jan Hansen

Samuli Heikkinen

Erk Jensen

Thibault Lefevre

Marina Maliabaila

Serge Mathot

Oznur Mete

Holger Neupert

Jukka Parro

Trond Ramsvik

AlbertoRodriguez

Daniel Schulte

Jonathan Sladen

Igor Syrachev

Mauro Taborelli

Frank Tecker

Peter Urschutz

Ian Wilson

Guy Yvon