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Managed by UT-Battelle for the Department of Energy SNS Ring TiN Coating Experience CERN Anti E-Cloud Coating Workshop Oct 12-13, 2009 by M. Plum, Ring.

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Presentation on theme: "Managed by UT-Battelle for the Department of Energy SNS Ring TiN Coating Experience CERN Anti E-Cloud Coating Workshop Oct 12-13, 2009 by M. Plum, Ring."— Presentation transcript:

1 Managed by UT-Battelle for the Department of Energy SNS Ring TiN Coating Experience CERN Anti E-Cloud Coating Workshop Oct 12-13, 2009 by M. Plum, Ring Area Manager

2 2/20 Managed by UT-Battelle for the Department of Energy M. Plum -- AEC'09 -- Oct. 12-13, 2009 SNS Accelerator Complex Front-End: Produce a 1-msec long, chopped, H - beam 1 GeV LINAC Accumulator Ring: Compress 1 msec long pulse to 700 nsec 2.5 MeV LINAC Front-End Accumulator Ring RTBT HEBT Injection Extraction RF Collimators 945 ns 1 ms macropulse Current mini-pulse Chopper system makes gaps Current 1ms Liquid Hg Target 1000 MeV

3 3/20 Managed by UT-Battelle for the Department of Energy Beam power ramp up M. Plum -- AEC'09 -- Oct. 12-13, 2009 October 1, 2006 to October 5, 2009 Status: Production beam with up to ~1.1e14 ppp (18 uC). Full design intensity demonstrated at 1 Hz.

4 4/20 Managed by UT-Battelle for the Department of Energy M. Plum -- AEC'09 -- Oct. 12-13, 2009 The SNS Accumulator Ring e-p mitigating features at SNS: Vacuum chambers coated with TiN to reduce secondary electron yield Solenoids in the collimation region Clearing electrode near the stripper foil BPMs can be biased to use as clearing electrodes Robust dual harmonic RF system which can help keep the gap clean Beam in gap kicker Active damping system Design ring parameters: 1 GeV beam Intensity: 1.5  10 14 ppp (24 uC) Working point (6.23,6.20) Ring circumference – 248 m Space charge tune shift – 0.15

5 5/20 Managed by UT-Battelle for the Department of Energy Status of electron control and measurement in the SNS Ring All vacuum chambers TiN coated except: –~7.1 m in RF straight for IPM and electron beam profile monitor development –~2.2 m in collimation straight for active damping system development –~2 m in vicinity of primary stripper foil, due to Al over- coating Clearing electrode by primary foil –Powered for first time on Oct. 6, 2009 Solenoid winding in collimation straight –Not powered M. Plum -- AEC'09 -- Oct. 12-13, 2009

6 6/20 Managed by UT-Battelle for the Department of Energy Status of electron control and measurement in the SNS Ring (cont.) BPM electrodes that can be biased –Present electronics do not allow biasing Beam in gap kicker system –Not installed Active damping system –Under development RFA electron detectors –Have some very preliminary data M. Plum -- AEC'09 -- Oct. 12-13, 2009

7 7/20 Managed by UT-Battelle for the Department of Energy M. Plum -- AEC'09 -- Oct. 12-13, 2009 Hseuh et al., Ecloud04 workshop

8 8/20 Managed by UT-Battelle for the Department of Energy M. Plum -- AEC'09 -- Oct. 12-13, 2009 Example of e-p instability data gap high freq. oscillation near tail of bunch 700 turns gap BPM sum BPM signal (mm) (From S. Cousineau et al., HB2008)

9 9/20 Managed by UT-Battelle for the Department of Energy M. Plum -- AEC'09 -- Oct. 12-13, 2009 Instability frequency: 60 – 100 MHz. Vertical preceded horizontal by ~200 turns. Example of instability frequency Horizontal Vertical (From S. Cousineau et al., HB2008)

10 10/20 Managed by UT-Battelle for the Department of Energy Summary of 2008 e-p data M. Plum -- AEC'09 -- Oct. 12-13, 2009 (From S. Cousineau et al., HB2008)

11 11/20 Managed by UT-Battelle for the Department of Energy Experiment vs theory Measurements show that the e-p instability is present at charge intensities as low as 3e13 ppp (one fifth full design intensity, 24 kV of h=1 and 16 kV of h=2 RF) On one occasion so far at full design intensity (1.5e14 ppp), measurements showed that instability can be controlled with Ring RF. (42 kV of h=1, 20 kV of h=2 RF). Note that ~4.6% of Ring is uncoated. Based on analytical and computational studies, and comparisons with LANL’s PSR, with no TiN coating –Stable up to 2e14 ppp for h=1 RF of 15 kV [Blaskiewicz et al., PRSTAB 2003] Computational simulation including effects of TiN coating –Stable up to 2e14 ppp for h=1 RF of 13 kV [Shishlo et al., EPAC06] M. Plum -- AEC'09 -- Oct. 12-13, 2009

12 12/20 Managed by UT-Battelle for the Department of Energy SEY of st. steel and TiN vs. scrubbing M. Plum -- AEC'09 -- Oct. 12-13, 2009 SEY max of TiNSEY max of St. St. Unscrubbed2.21.8 Scrubbed1.051.1 Copied from M. Nishiwaki and S. Kato, ECLOUD’07 SNS Ring beam pipes are 316L or 316LN stainless steel, bellows are Inconel 625

13 13/20 Managed by UT-Battelle for the Department of Energy TiN summary M. Plum -- AEC'09 -- Oct. 12-13, 2009 With ~95.4% of our ring coated with TiN, we have seen the instability at about one fifth of design intensity Theory predicts no e-p instability up to 30% greater than design intensity PSR experience: TiN coatings sometimes help, sometimes not until after scrubbing [R. Macek et al., ECLOUD ’04 & PAC03] SNS vacuum chambers were exposed to air for months prior to installation, so our TiN started out unscrubbed, and may still be unscrubbed Secondary emission yields of stainless steel and TiN seem to be about the same, before and after scrubbing Is TiN coated stainless steel really better than just plain stainless steel?

14 14/20 Managed by UT-Battelle for the Department of Energy Future plans Continue to develop active damping system –400 W, 3 to 300 MHz, each plane Complete purchase of TiN coating system –$339k from Kurt J Lesker Co., due ~Jan. 2010 Continue to get all chambers TiN coated Continue to develop diagnostics and characterize electrons in ring –RFA electron detectors –Microwave plasma measurements Determine effectiveness of TiN coating M. Plum -- AEC'09 -- Oct. 12-13, 2009

15 15/20 Managed by UT-Battelle for the Department of Energy Electrons in vicinity of stripper foil Convoy electrons from a 1 GeV H − beam have 545 keV energy, gyroradius 12 mm, period 0.29 ns, pitch 16-23 mm. Center of circular motion moves ~14 mm downstream and ~5 mm beam left. Electrons are collected in an “electron catcher”. A 1 MW beam has ~1 kW power in the convoy electrons. M. Plum -- AEC'09 -- Oct. 12-13, 2009

16 16/20 Managed by UT-Battelle for the Department of Energy Electron catcher and clearing electrode Water cooled carbon-carbon wedges Undercut prevents secondary electrons from escaping M. Plum -- AEC'09 -- Oct. 12-13, 2009 +/-20 kV biasing system Inlet and outlet water cooling lines have thermocouples, read out by EPICS and archived

17 17/20 Managed by UT-Battelle for the Department of Energy Electron catcher boroscope image M. Plum -- AEC'09 -- Oct. 12-13, 2009 Al coating Electron impact

18 18/20 Managed by UT-Battelle for the Department of Energy Graphitization at top of vacuum chamber M. Plum -- AEC'09 -- Oct. 12-13, 2009 152 mm ~24 mm Could be reflected convoy electrons or trailing-edge multipactoring Clearing electrode

19 19/20 Managed by UT-Battelle for the Department of Energy Summary e-p instablility is present in SNS ring at intensities as low as 3e13 ppp (one-fifth design intensity). Theoretical work prior to commissioning predicted no e-p instability up to 30% greater than the design intensity. e-p instability can be controlled with ring RF system up to full design intensity of 1.5e14 ppp (one time only) Results from TiN coating are mixed – is it really better than just stainless steel? Note that ring still has ~11.3 m (4.6%) with no TiN coating. Attempting to coat everything with TiN has been expensive and has caused installation delays. It will be interesting to determine if it has been worth it. M. Plum -- AEC'09 -- Oct. 12-13, 2009

20 20/20 Managed by UT-Battelle for the Department of Energy Thank you for your attention! M. Plum -- AEC'09 -- Oct. 12-13, 2009

21 21/20 Managed by UT-Battelle for the Department of Energy Backup slides M. Plum -- AEC'09 -- Oct. 12-13, 2009

22 22/20 Managed by UT-Battelle for the Department of Energy SNS injection schematic Closed orbit bump of about 100 mm Merge H - and circulating beams with zero relative angle Place foil in 2.5 kG field and keep chicane #3 peak field <2.4 kG for H 0 excited states Field tilt [arctan(By/Bz)] >65 mrad to keep electrons off foil Funnel stripped electrons down to electron catcher Direct H - and H 0 waste beams to IDmp beam line M. Plum -- AEC'09 -- Oct. 12-13, 2009

23 23/20 Managed by UT-Battelle for the Department of Energy Graphitization M. Plum -- AEC'09 -- Oct. 12-13, 2009 Example of graphitization by multipacting electrons in SRBM11 at PSR. This is not a thermal effect! (R. Macek, HB2008 & private comm.)

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