1. Coupler without copper coating S. Kazakov 11/13/2013

2. Coupler for SRF cavity has to provide low RF loss and low heat flow from room temperature to cryo-temperatures. These are contradictory requirements. Traditional solutions is thin SS coated with thin Cu. Problem with Cu coating still exists: difficult to get a durable coating, difficult to get a good reproducible RRR, cupper coating increase thermo-conductivity (requires accurate control of copper layer. We would like to suggest new approach which solves this problem: without copper coating a coupler has RF loss as a pure copper and thermal conductivity as a pure SS.

3. Idea: No thermal contact between copper parts SS Low fields chamber Heat flows through SS only, RF loss in SS < loss in Cu Holes for pumping and washing

4. With some combinations of dimensions of slot and chamber: 1)RF reflections < -35 dB 2)Н-filed at SS surface < 0.25 of H-fild at Cu surface (losses at SS will be < losses at Cu) One possible configuration:

5. Requirements to slot, chamber dimensions: Requirements is not so strict: Slot should be small and long enough, chamber should be big enough. Examples: Rout = 20mm Rin = 4.76mm There is no multipactor for copper slot < 0.5 mm for any fields (1.3 GHz) There is no multipactor in chamber (low fields) in operating power range.

6. dRdZPSRbHLRefН1H2H2/H1 4101.50.55701030-28.050.850.210.247 4101.50.55701040-29.00.8540.1430.167 4101.50.55701050-29.50.8540.1070.125 4102.00.74301050-26.40.8530.1530.179 4152.00.51501050-33.70.8550.070.082 4152.00.5150550-32.70.8560.1650.196 4152.00.5150.5550-25.80.8550.3740.437 4152.00.5150.2550-30.60.8550.2100.246 4151.50.3860.2550-34.00.8520.1450.170 4151.50.3860.5550-29.70.8530.2400.281 51510.3160.2550-37.10.8530.10.117 51510.3160.2530-35.80.8530.1920.225 51510.3160.2830-36.80.8530.1050.123 51510.3160.2820-35.80.8530.1720.202 51510.3160.21020-36.30.8530.1270.149 51510.3160.210 -33.70.8530.3330.390 Loss in SS will be ~ (0.2)^2 *7 ~ 0.3 of loss in copper

7. Preliminary mechanical analyses shows that this configuration is possible. We cannot ‘close’ the slot by bending - plastic deformations start first.

8. T2 K10 K100 K Static, W0.0170.903.2 Total (RF = 6kW, TW), W0.121.053.5 Static One-window 1.3 GHz coupler configuration Cryo-loads, RRR = 10:

9. 1.3 GHz coupler configurations with cold window

10. Main question: can we clean/wash this assembly? FNAL experts opinions: there is no problem to prepare initially clean assembly. Problem is to re-clean the chamber after first test / conditionings. May be it will be difficult to blow out particles from chamber.

11. Demountable configuration allows to do a re-cleaning: One warm window Temperature, K2 K10 K100 K Static load, W0.0180.652.4 Total (RF=6 kW, TW)0.1340.663.0 Cryo-loads, RRR = 10: Brazed or bolted

12. Temperature2 K10 K100 K Static load, W0.0180.652.4 Total (RF = 6 kW, TW)0.570.668.8 Cryo-loads, RRR = 10: Cold window, adjustable coupling

13. Double bellows: Or no copper bellows : Problem – multipactor in slot. CST copper (max SE ~ 2.1), multipactor range ~ 10 kW - 2 MW, TW ‘Clean’ copper (max SE ~1.4), multipactor range ~ 25 kW – 800 kW, TW 2 K load ~ 0.1 W for 6 kW RF

14. Sensitivity to slot size: Optimal size – 0.82mm. Simulated +- 0.1mm Slot matches the window and thermally decouples cold and warm parts of antenna. window Slot We can avoid SS bellows Multipactor in 0.82mm slot: CST copper (max SE ~ 2.1), multipactor range ~ 20 W - 800 W, TW ‘ Clean’ copper (max SE ~1.4), multipatir range ~ 160 W – 250 W, TW Out of operating range E-field ~ 0.18 kV/(cm*W⁰∙⁵) 400 kW -> 114 kV/cm

15. Adjustable coupler with cold window Compact adjustable coupler with cold window

16. Compact adjustable coupler with warm window(s)

17. “ Realistic” conceptual designs (very preliminary) Double bellows Cylindrical capacitor

18. Conclusions: Pros: allow to avoid copper coating of SS. Reproducibility of RRR, low static and dynamic loss (high RRR). Cons: requires high mechanical accuracy (~ +- 0.2mm concentricity). Cost?