Annual Meeting CERN - November 2005 Bernard V ISENTIN.

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Presentation transcript:

Annual Meeting CERN - November 2005 Bernard V ISENTIN

Bernard Visentin Annual Meeting CERN – 23/11/ Eventful Year for SRF R & D Fast Baking : experimental show of O role Single Crystal & Large Grain Cavities E acc Records mono-cell Cavities new shape ( LL & RE ) Manufacturing multi-cell Cavities ( LL shape) 2005

Bernard Visentin Annual Meeting CERN – 23/11/ High Gradients  S-LINAC Cost C. Adolphsen 1 st ILC Workshop E acc (MV/m) Relative Cost ( €/$/¥ ) Baseline Configuration Document for ILC (500 GeV) 31.5 MV/m recommendation E acc  35 MV/m (including fabrication scatter 5%)  37 MV/m

Bernard Visentin Annual Meeting CERN – 23/11/ Recipe for High Gradients Electropolishing + Baking Electropolishing + Baking ( E Quench ) ( Q-slope ) ( E Quench ) ( Q-slope ) 40 MV/m K. Saito - SRF Workshop 1997 B. Visentin - EPAC 1998

Bernard Visentin Annual Meeting CERN – 23/11/ where do we stand with ?

Bernard Visentin Annual Meeting CERN – 23/11/ Electropolishing Chemistry : Nb Surface Renewal Rotating Anode (+) : Nb cavity Cathode (-) : Al FS ( 1:9 ) V ( 17 volt ) – J ( 60 mA/cm 2 ) plateau Nb oxidation : Electrochemistry Standard Chemistry Standard Chemistry (BCP) Dunked cavity FNP ( 1:1:2 ) Nb oxidation : Hypothesis: Surface roughness ( better water rinse – lower H field enhancement ) Oxide attack by HydroFluoric acid : re-oxidation

Bernard Visentin Annual Meeting CERN – 23/11/ Electropolishing at DESY L. Lilje - SRF Workshop 2005 Faced to this superiority  To set up an EP facility for 9-cell cavity Electropolishing

Bernard Visentin Annual Meeting CERN – 23/11/ Electropolishing at DESY RF tests results on 9-cell cavities 120 MeV 4 MeV 400 MeV 800 MeV 1 GeV ACC6 module with 8 EP 35 MV/m ( Summer 2006 ) TTF Linac Electropolishing

Bernard Visentin Annual Meeting CERN – 23/11/ Reproducibility - Field Emission Electropolishing Unfortunately, in spite of the EP success a large spread exists in the cavity production compare to standard chemistry

Bernard Visentin Annual Meeting CERN – 23/11/ Optimization of EP Treatment F. Eozénou - SRF Workshop 2005 EP test bench for mono-cell EP bath impurities Cathode corrosion (Al) and Sulphur deposition solution  alcohol rinse EP bath ageing ( Nb dissolved ):  HF concentration F:S concentration 1:9 (9 g/l)  4:9 (23 g/l) Optimize parameters ( V-I ) Explore different working zones ( plateau, …) Electropolishing JRA1 - SRF Nb sample  mono-cell cavity  9-cell

Bernard Visentin Annual Meeting CERN – 23/11/ Large Grain Cavity Electropolishing P. Kneisel PAC 2005 & SRF Workshop 2005 High Gradient shape 1.5 GHz with Standard Chemistry « BCP » Very smooth surface ( EP not necessary ) RMS surface roughness: fine grain (BCP): 1274 nm fine grain (EP): 251 nm large grain (BCP): 27 nm

Bernard Visentin Annual Meeting CERN – 23/11/ Potential Advantages of Large Grain Nb Electropolishing Niobium discs sliced directly from ingots ( saw cut or electrical discharge machining : no forging, no rolling ) Reduced cost Less impurities Quality control more easy BCP large grain cavity  BCP fine grain cavity ( 30 MV/m ) with better surface roughness than EP fine grain 40 MV/m Open Question High 40 MV/m are they linked to Electro-Polishing (surface roughness) or just to Electro-Chemistry ? adopted as : Alternative Option for ILC 500 GeV WG 5 Report - 2 nd ILC Workshop ( Snowmass 2005 )

Bernard Visentin Annual Meeting CERN – 23/11/ EP Large Grain Cavities at DESY Electropolishing first test (before baking) : Q-slope - 28 MV/m TESLA Shape (1.3 GHz) – Electropolishing

Bernard Visentin Annual Meeting CERN – 23/11/ Where do we stand with ?

Bernard Visentin Annual Meeting CERN – 23/11/ Baking  Wide Application Area in-situ (UHV) T = °C t = 1 – 2 days TTF 1.3 GHz - Saclay / KEK Polycrystalline No Thermal Treatment Electropolishing TTF 1.3 GHz - Saclay Polycrystalline 1300°C / Ti Chemical Etching 1:1:2 LL 2.2 GHz - JLab Single crystal 800°C – 1250°C / Ti Chemical Etching 1:1:1 Whatever the chemical treatment… ( Electropolishing or Standard Chemistry ) Whatever the niobium structure… ( Single or Poly-crystal,) & Cavity Shape ( HG,LL,RE ) Whatever the fabrication method… ( EB Welding or Hydroforming, bulk Nb or clad Nb/Cu) Whatever the thermal treatment… (nothing, 800°C, 1300°C/Ti ) Baking

Bernard Visentin Annual Meeting CERN – 23/11/ Baking  Permanent Treatment T = 120 °C / 2 days + Air exposure -for 4 years – without any particular precautions Hydrofluoric Treatment High Pressure Rinse Baking

Bernard Visentin Annual Meeting CERN – 23/11/ Baking  Diffusion 110 °C 60 hours in-situ ( UHV ) interstitial oxygen R S Change through electron Mean Free Path (  ) decrease Baking

Bernard Visentin Annual Meeting CERN – 23/11/ Q-slope Baking Diffusion of Interstitial Oxygen Doping Effect in Niobium Explanation of Q-slope Improvement by Baking B. Visentin SRF Workshop 2005 Baking

Bernard Visentin Annual Meeting CERN – 23/11/ Baking Parameters ( T, t ) with Unchanged Oxygen Penetration 110 °C / 60 hours equivalence 145 °C / 3 hours thin oxide layer : C(x,0) = Q  (x) semi infinite solid : C(0,t) = C S  analytic solutions 2 nd Fick's law Baking

Bernard Visentin Annual Meeting CERN – 23/11/ « Fast » Baking ( UHV ) Infra-Red emitters (short T rise time) Cavity pumped out ( Ultra High Vacuum ) 145 °C - 3 hours Similarities with Standard Baking Baking

Bernard Visentin Annual Meeting CERN – 23/11/ °C 3 h 110 °C 60 h ( Standard ) 145 °C 3 h ( Fast ) 145 °C 60 h under vacuum = ++- O % from interface Nb 2 O 5 – NbO X / Nb Baking Control oxygen penetration in niobium 

Bernard Visentin Annual Meeting CERN – 23/11/ RF Test Bed ( Cryostat ) (RF Test ) RF Test Baking Ultra High Vacuum 110 °C / 2 days  145 °C / 3 hours Air Drying : 3 hours High Pressure Rinse - 85 bars (FE) Assembly + Helium Test Clean Room ( Class 100 ) Fast Baking : Improvement for Cavity Mass Production Electropolishing + Ultra Pure Water Rinse Baking Air Baking : T °C / t hours Save time & Possibility to simplify the cavity preparation RF Test High Pressure Rinse - 85 bars (FE) Assembly + Helium Test Electropolishing + Ultra Pure Water Rinse

Bernard Visentin Annual Meeting CERN – 23/11/ « Air - Baking » in Clean Room Fast Air-Baking on Wet Cavity under Laminar Flow (FE) OK (UHV) Temp. / Time Turbulences adopted to substitute the “in-situ” baking Alternative Configuration Document ( ILC 500 GeV ) WG 5 Report - 2 nd ILC Workshop ( Snowmass 2005 )

Bernard Visentin Annual Meeting CERN – 23/11/ Overcome ?

Bernard Visentin Annual Meeting CERN – 23/11/ Nb Cavity Performances ( ) Continuous improvements with Heat 800 and 1400°C, High Pressure Rinse, Baking & ElectroPolishing. 42 MV/m hard barrier (  2004 )

Bernard Visentin Annual Meeting CERN – 23/11/ New Shape to Reduce H p / E acc TTF : Optimized to reduce field emission & multipacting ( iris rounded – cell rounded far from pill-box geometry) TTF LLRE DESY / JLab.Cornell Ø iris (mm) / 60 Ep / Eacc / 2.28 Hp / Eacc (Oe/MV/m) / 35.4 New shape : decrease surface H field  increase magnetic volume (for lower P dissipation  small Ø iris & maximize R/Q*G parameter) Critical Points : cleaning and preparation (Ep/Eacc increase) - stiffness J. Sekutowicz SLAC Talk 2005 Quench (SC Breakdown) : thermal effect on local defect if T >Tc (9.2K) or surface peak magnetic field Hp>Hc (2000 Oe) Experimental e Reduce Hp Ratio Hp/Eacc (determined by geometry) K. Saito - SRF %

Bernard Visentin Annual Meeting CERN – 23/11/ Single Cell LL 45 MV/m P. Kneisel – PAC 2005 Single Crystal ( 2.2 GHz ) Standard chemistry

Bernard Visentin Annual Meeting CERN – 23/11/ Single Cell RE 52 MV/m courtesy of Kenji Saito Fine Grain ( 1.3 GHz ) Electropolishing + Baking R.L. Geng – SRF Workshop 2005

Bernard Visentin Annual Meeting CERN – 23/11/ Single Cell LL or RE Cavities E acc > 40 MV/m Obviously new step is crossed with cavity shape modification adopted as : Alternative option for ILC 500 GeV ( Baseline for 1 TeV upgrade ) E acc > 40 MV/m ( including fabrication scatter )  42 MV/m WG 5 Report - 2 nd ILC Workshop ( Snowmass 2005 ) from Kenji Saito

Bernard Visentin Annual Meeting CERN – 23/11/ Multi Cell LL Cavities C. Reece – SRF Workshop 2005 T. Saeki – SRF Workshop 2005 Four 1.5 GHz installed in “Renascence” 3 rd prototype CW cryomodule - CEBAF upgrade 12 GeV Vertical tests – Q slope - 25 MV/m “ICHIRO” cavities Goal : 51 MV/m Four 9-Cell ( 1.3 GHz )

Bernard Visentin Annual Meeting CERN – 23/11/ Conclusions High gradients required for future e - linear accelerators : within reach, at least for single cell cavities Physical explanations ( EP and Baking ) are not well understood : Fundamental R&D goes on Main goal : Technical R&D to optimize and simplify the preparation process  decrease in field emission  better reproducibility of EP ( scatter in performances )  performing « fast air-baking » in clean room

Bernard Visentin Annual Meeting CERN – 23/11/ Acknowledgements Thank you to my colleagues for providing information and documents to prepare this presentation DESY :L. Lilje – J. Sekutowicz JLab :P. Kneisel – C. Reece KEK :K. Saito – T. Saeki Cornell :H. Padamsee – R.L. Geng