Progress and Plans on Warm Cavity Technology Sergio Calatroni – CERN On behalf of the CLIC Structures Team.

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Presentation transcript:

Progress and Plans on Warm Cavity Technology Sergio Calatroni – CERN On behalf of the CLIC Structures Team

ELAN - Orsay Sergio Calatroni - CERN2 Outline: four main lines of development RF design optimisation for low E surf, H surf and short pulses : –Present design: HDS and its rationale Material optimisation to withstand pulsed heating and repeated RF breakdown : –Pulsed heating & fatigue –Laser testing, ultrasound testing, CuZr and other candidate materials –CTF2 high gradient tests and comparison with DC spark tests –Search for optimum material and treatments –CTF3 tests: ultimate gradient and study of breakdown rate – Mo vs Cu –Best conditioning strategy? Integrated parameter optimisation –Scaling of breakdown limit –Parameter optimization How to make a structure?

ELAN - Orsay Sergio Calatroni - CERN3 Hybrid Damped Structure (HDS) structures: to be tested soon High-speed 3D milling of the fully profiled surface with 10-µm precision HDS mm

ELAN - Orsay Sergio Calatroni - CERN4 HDS: RF design Combination of slotted iris and radial waveguide (hybrid) damping results in low Q-factor of the first dipole mode: ~ 10. Damping by more than a factor 100 is achieved after only eight RF periods

ELAN - Orsay Sergio Calatroni - CERN5 HDS: cell RF design Surface magnetic field Surface electric field

ELAN - Orsay Sergio Calatroni - CERN6 Material research: surface heating High peak surface magnetic field  High thermo-mechanical stress over the ~10 11 RF pulses foreseen in the CLIC lifetime  Breakup by “fatigue” Stress [Pa] Surface heating during 68 ns pulse (HDS140, CuZr C15000) Fully compressive cyclic stress Cyclic peak-to-peak stress 155 MPa Cyclic Stress Amplitude 77.5 MPa Surface  T = 56 K

ELAN - Orsay Sergio Calatroni - CERN7 Fatigue resistance: literature data & choice of material candidates Bending stress not comparable to the surface stress we have in CLIC structures We need data up to cycles

ELAN - Orsay Sergio Calatroni - CERN8 Low cycle fatigue: UV excimer laser (308 nm) pulsed heating RF pulse   Laser pulse The pulse shapes correspond. In particular the temperature profile at the peak is very similar, and results in similar stress level.

ELAN - Orsay Sergio Calatroni - CERN9 Laser fatigue: surface modification (  roughness change) CuZr C15000, 10 Mshots, 0.15 J/cm 2,  T = 120 K,  = 170 MPa CuZr C15000 reference surface

ELAN - Orsay Sergio Calatroni - CERN10 Surface roughness as a function of fluence and number of shots: CuZr The value of 0.02 µm has been chosen as the first measurable departure from the reference surface (flat, diamond turned). This is thought to be the most important phenomenon. The further increase of roughness is only crack propagation. Wöhler plot

ELAN - Orsay Sergio Calatroni - CERN11 High cycle fatigue data: ultrasonic testing Cyclic mechanical stressing of material at frequency of 24 kHz. High cycle fatigue data within a reasonable testing time. CLIC lifetime 7x10 10 cycles in 30 days. Will be used to extend the laser fatigue data up to high cycle region. Tests for Cu-OFE, CuZr, CuCr1Zr & GlidCop Al-15 under way. Ultrasound fatigue test samples Ultrasound fatigue test setup Air Cooling Fatigue test specimen Calibration card measures the displacement amplitude of the specimen’s tip + - Reversed stress condition

ELAN - Orsay Sergio Calatroni - CERN12 Ultrasonic fatigue: surface crack initiation Diamond turned specimen before After 3*10 6 cycles at stress amplitude 200 MPa Stess Amplitude N 3x MPa CuZr

ELAN - Orsay Sergio Calatroni - CERN13 Fatigue limit: laser & ultrasound data for CuZr C % cold worked

ELAN - Orsay Sergio Calatroni - CERN14 Laser & Ultrasound fatigue data combined Copper, Dubna RF-fatigue test Annealed Copper, SLAC RF-fatigue test, Pritzkau - Reversed bending -fatigue test - Ultrasound fatigue test - Pulsed laser fatigue test - Pulsed RF fatigue test RF testing at high pulse number in order to validate these data is of the highest priority. Operating at 50 Hz, it would allow 10 7 cycles in less than 2.5 days RF design of a dedicated test structure is done, and mechanical design and fabrication are under way. It is hoped to get it operational by end 2006 – early 2007, operating in parallel with the existing high-gradient test stand.

ELAN - Orsay Sergio Calatroni - CERN15 High gradient testing in CTF2 for iris material selection/characterisation Circular structures, 30 GHz, 2/3 , clamped irises, 16 ns pulse length in CTF2 Tested materials: Cu, Mo and W iris (longer pulses available now with CTF3) The aim is to select the iris material which offers the best compromise among: resistance to breakdown, rapidity of conditioning, breakdown rate, RF losses, easiness of machining and structure fabrication, etc. etc. etc.…

ELAN - Orsay Sergio Calatroni - CERN16 DC spark testing: comparison of selected materials Molybdenum Tungsten Copper Decrease! Mo W Cu Max. surface field in RF [MV/m] (DC)E breakd sat DC and RF breakdown measurements give similar breakdown fields for Mo and W Superior behavior of both Mo and W with respect to Cu.

ELAN - Orsay Sergio Calatroni - CERN17 Improving conditioning rate: DC spark tests The understanding of the underlying mechanism is in progress, as well as possible implementations in a real RF device conditioning rate of standard sample conditioning rate of high-temperature vacuum treated sample

ELAN - Orsay Sergio Calatroni - CERN18 30 GHz Mo-iris (30 cells) structure in CTF3: RF conditioning rate

ELAN - Orsay Sergio Calatroni - CERN19 30 GHz Mo-Iris structure (30 cells): breakdown limit and scaling E acc =150 MV/m, 70 ns

ELAN - Orsay Sergio Calatroni - CERN20 LATEST NEWS! Breakdown rate of Mo vs. Cu at 30 GHz One slope for Mo = 1/(0.088*E[bdr=10 -1 ]) CLIC would operate safely (99% duty time) with a breakdown rate of Need data!

ELAN - Orsay Sergio Calatroni - CERN21 All structure parameters are variable: = 90 – 150 MV/m, f = 12 – 30 GHz,  = o, / = ,  a/ = 0.01 – 0.6, d 1 / = , d 2 > d 1 N cells = 15 – 300. N structures: Structure optimisation

ELAN - Orsay Sergio Calatroni - CERN22 Optimisation of working parameters Beam dynamics constraints: N, L b× depend on /,  a/, f and and come from D. Schulte N cycles is determined by condition: W t,2 = 10 V/pC/mm/m for N = 4x10 9 rf breakdown and pulsed surface heating (rf) constraints: E surf max < 380MV/m &  T max < 56K & P in t p 1/2 < 1200 MWns 1/2 or P in t p 1/3 < 442 MWns 1/3 or 40K or P in t p 1/3 /C < 20 MWns 1/3 /mm or P in t p 1/3 /C < 16 MWns 1/3 /mm or P in t p 1/2 /C < 42 MWns 1/2 /mm or P in t p 1/2 /C < 30 MWns 1/2 /mm Optimization figure of merit Luminosity per linac input power:  Ldt/  Pdt ~ L b× /N  Cost is not taken into account… yet!

ELAN - Orsay Sergio Calatroni - CERN23 Optimisation of working parameters: there are no sacred cows… P in t p 1/3 /C < 20 MWns 1/3 /mm  T max < 56K CTF3 ( ): ~ 20 MWns 1/3 /mm

ELAN - Orsay Sergio Calatroni - CERN24 How to make a bi-metal HDS structure with Mo iris and CuZr body? Structure assembly Mo: high E-field CuZr C15000: Pulsed currents Aim: +/- 1µm accuracy, 0.05µm Ra close to the beam region

ELAN - Orsay Sergio Calatroni - CERN25 CuZr-Mo bimetal – possible manufacturing techniques Prototype by HIP (Hot Isostatic Pressing): -CuZr C15000, Mo (fully dense, fine grained, stress-relieved, 99.97% purity molybdenum) -No cold working, nor proper quenching is possible -Minor improvement of CuZr properties with post-HIP treatment is possible From Metso Powdermet Explosion bonding: 0.2 mm Minsk, R.Stefanovich

ELAN - Orsay Sergio Calatroni - CERN26 HDS: testing program in CTF3 of single-metal structures HDS60 (60 cells),  /3, Cu-OFE: RF test foreseen in June 2006 Next: HDS11 (11 cells),  /3: Cu-OFE, Mo, stainless steel, Ti, Al (bulk pieces) 53 mm

ELAN - Orsay Sergio Calatroni - CERN27 Conclusions Fatigue problem can probably be overcome, but more data are needed Breakdown problem (ultimate gradient, breakdown rate) needs lots of experimental data, both RF and DC, in order to validate material choices and to refine the scaling laws, which are used as an input to the optimisation procedure Optimisation is regularly updated with new results, costs need to be implemented HDS design is sound, experimental validation in a few days Manufacturing techniques for bi-metals are being audited, for the moment no clear winner is very close! Run, run, run!

ELAN - Orsay Sergio Calatroni - CERN28 Acknowledgements Special thanks to: Gonzalo Arnau-Izquerdo, Steffen Doebert, Alexej Grudiev, Samuli Heikkinen, Holger Neupert, Trond Ramsvik, Jose Alberto Rodriguez, Mauro Taborelli, Walter Wuensch Who directly provided a lot of material for this presentation