Presentation is loading. Please wait.

Presentation is loading. Please wait.

J. Haimson and B. Mecklenburg Haimson Research Corporation FG02-05ER84362 Work performed under the auspices of the U.S. Department of Energy SBIR Grant.

Published byGregory Simmons Modified over 8 years ago

Similar presentations

Presentation on theme: "J. Haimson and B. Mecklenburg Haimson Research Corporation FG02-05ER84362 Work performed under the auspices of the U.S. Department of Energy SBIR Grant."— Presentation transcript:

1 J. Haimson and B. Mecklenburg Haimson Research Corporation FG02-05ER84362 Work performed under the auspices of the U.S. Department of Energy SBIR Grant No. DE-FG02-05ER84362 DESIGN FEATURES AND INITIAL RF PERFORMANCE OF A GRADIENT HARDENED 17 GHz LINAC 1 AAC 08

2 To Prevent Surface Erosion During High Gradient Operation and to Assist in Studying RF Breakdown, the Gradient Hardened 17 GHz Linac Structurewas Designed to have To Prevent Surface Erosion During High Gradient Operation and to Assist in Studying RF Breakdown, the Gradient Hardened 17 GHz Linac Structure was Designed to have Brazed and Machined Stainless Steel Surfaces in the High Field Regions of the Circuit. AAC 08 H AIMSON R ESEARCH C ORPORATION 2

3 Topics to be Presented 1.DESIGN PARAMETERS AND SPECIAL FEATURES OF THE GRADIENT HARDENED LINAC AND THE HIGH POWER DUAL RESONANT RING SYSTEM USED FOR RF TESTING. H AIMSON R ESEARCH C ORPORATION 2. 2.THE STATUS OF THE SST/CU LINAC STRUCTURE PRESENTLY BEING RF PROCESSED AT MIT. 3 RF WAVEFORM DYNAMICS RECORDED WHILE RF PROCESSING AT HIGH SURFACE GRADIENTS AND LOW REPETITION RATES. 3. RF WAVEFORM DYNAMICS RECORDED WHILE RF PROCESSING AT HIGH SURFACE GRADIENTS AND LOW REPETITION RATES. AAC 08

4 To Prevent Surface Erosion During High Gradient Operation and to Assist in Studying RF Breakdown, the Gradient Hardened 17 GHz Linac Structurewas Designed to have To Prevent Surface Erosion During High Gradient Operation and to Assist in Studying RF Breakdown, the Gradient Hardened 17 GHz Linac Structure was Designed to have Brazed and Machined Stainless Steel Surfaces in the High Field Regions of the Circuit. AAC 08 H AIMSON R ESEARCH C ORPORATION PAC 2007 4

5 The Filling Time, Insertion Loss and Physical Dimensions of the Gradient Hardened (SST/Cu) Structure were Specifically Chosen to Match the Requirements of an existing Dual Resonant Ring High Power Amplifying System (having an RF Bridge Ratio of 3) that had been Used Previously with a Similar Geometry 17 GHz All-Copper Structure. AAC 08 H AIMSON R ESEARCH C ORPORATION 5

6 DC – High Directivity Directional Coupler FC – Faraday Cup M – Motor Drive PSh– Phase Shifter W – Ceramic RF Window DC SPECTROMETER R F W FC TRIPLE HYBRID M 17 GHz TWRK 94 CAVITY TW LINAC INJECTOR LOAD DC RFRF M PSh LOAD HYBRID DC 22 CAVITY TEST LINAC F R LOAD HYBRID RFRF DC FRFR F R DC (A) (B) H AIMSON R ESEARCH C ORPORATION AAC 08 6 (b)

7 Frequency................ 17.140 GHz Frequency................ 17.140 GHz Number of Cavities........... 22 Number of Cavities........... 22 Phase Advance............. 120 Phase Advance............. 120 Linac Structure Beam Aperture (a/λ)... 0.1715 Linac Structure Beam Aperture (a/λ)... 0.1715 Linac Structure Disc Thickness (t/λ)... 0.0835 Linac Structure Disc Thickness (t/λ)... 0.0835 Group Velocity.............. 0.044c Group Velocity.............. 0.044c Cavity Phase Velocity.......... 4 at c, 2 at 1.005c, Cavity Phase Velocity.......... 4 at c, 2 at 1.005c, 2 at 1.010c, and 14 at1.015c 2 at 1.010c, and 14 at1.015c Structure Attenuation Parameter.... 0.178 Np Structure Attenuation Parameter.... 0.178 Np Resonant Ring Loop Loss........ 1.65 dB Resonant Ring Loop Loss........ 1.65 dB RF Power Buildup [= C/(1-TcTf)]...... 3.1 RF Power Buildup [= C/(1-TcTf)]...... 3.1 DESIGN AND OPERATING PARAMETERS OF THE 17 GHz SST/CU LINAC STRUCTURE AND RESONANT RING H AIMSON R ESEARCH C ORPORATION 7 AAC 08 7

8 H AIMSON R ESEARCH C ORPORATION 8

9 9 AAC 08

10 H AIMSON R ESEARCH C ORPORATION 10

11 NORMAL LINAC OPERATION RF Source Power Bridge Load Power Linac Input Power Linac Reflected Power High Power RF Waveforms of the Bridge Protected High Gradient 17 GHz Linac Frequency = 17137 MHz. Time Base = 50 ns/div. “A Linear Accelerator Power Amplification System for High Gradient Structure Research,” in Advanced Accelerator Concepts, AIP Conf. Proc., No. 472, pp. 1003–1013, 1998. Showing that when an Arc Occurs in the Linac, the Linac Input Power (blue) is Rapidly Truncated and, for the Remaining Portion of the Klystron RF Pulse the Bridge Input Power (red) is Automatically Directed into the Bridge Load (green). Thus, the Linac Power Amplifying Bridge Assists in Automatically Protecting both the RF Source and the High Gradient Linac Structure. WITH ARC IN LINAC H AIMSON R ESEARCH C ORPORATION 11 AAC 08

12 BECAUSE THE RING LIMITS THE ENERGY DEPOSITION IN THE STRUCTURE DURING THE BREAKDOWN, AND BECAUSE THE KLYSTRON POWER IS SIMULTANEOUSLY SWITCHED INTO THE LOAD ARM AND DISSIPATED OUTSIDE THE HIGH VACUUM ENVELOPE, BREAKDOWNS CAN BE TOLERATED WITHOUT TRIPPING OR SWITCHING OFF THE SYSTEM, AND BY REDUCING THE REP RATE TO ½ or 1Hz, THE SYSTEM CAN BE RUN CONTINUOUSLY WHILE OBSERVING THE PULSE BY PULSE PROGRESSION OF THE RF CONDITIONING PROCESS. AAC 08 H AIMSON R ESEARCH C ORPORATION

13 893 894 895 896 AAC 08 H AIMSON R ESEARCH C ORPORATION 13 ARC SPARK SIZZLE AFTER THE PULSE WIDTH IS INCREASED BY ONLY 10 ns, IT TAKES ONLY 1 (0R 2) PULSES AT THE NEW WIDTH TO ERASE THE SURFACE MEMORY OF THE PRIOR PROCESSING HOLD -OFF LEVEL AND FOR THE BREAKDOWN TO DEFAULT TO A MUCH LOWER LEVEL.

14 AAC 08 14 H AIMSON R ESEARCH C ORPORATION 17 GHz Data Attained After 1.5e05 Pulses Input Power from RF Source (160ns)... Linac Input Power............. E SM / E A...... E SM / E A...... Maximum Accelerating Gradient...... Maximum Surface Gradient....... SST/Cu SST/Cu 16 MW 16 MW 50 MW 50 MW 2.22 2.22 84 MV/m 84 MV/m 186 MV/m 186 MV/m (RF Processing Still in Progress)

15 AAC 08 H AIMSON R ESEARCH C ORPORATION 15

16 H AIMSON R ESEARCH C ORPORATION 16 AAC 08

17 Observations During High Gradient Testing of the 22 Cavity SST/Cu Linac H AIMSON R ESEARCH C ORPORATION A notable difference in the processing behavior of the ring driven linac structures was the absence of retrogressive breakdown thresholds, even after heavy discharges duringA notable difference in the processing behavior of the ring driven linac structures was the absence of retrogressive breakdown thresholds, even after heavy discharges during wide pulse operation. A gradient of 84 MV/m has been achieved after 1.5x10 5 pulses,and RF processing is still in progress.A gradient of 84 MV/m has been achieved after 1.5x10 5 pulses, and RF processing is still in progress. AAC 08 17

18 Observations During High Gradient Testing of the 22 Cavity SST/Cu Linac Because the resonant ring automatically limits energy deposition during RF breakdown events, it is possible to continue operating at threshold values of surface gradient without trip interruptions. Thus, by also operating at a low pulse repetition rate, the pulse by pulse progression of the RF processing mechanism can be continually monitored and studied as the RF pulse parameters are varied.Because the resonant ring automatically limits energy deposition during RF breakdown events, it is possible to continue operating at threshold values of surface gradient without trip interruptions. Thus, by also operating at a low pulse repetition rate, the pulse by pulse progression of the RF processing mechanism can be continually monitored and studied as the RF pulse parameters are varied. AAC 08 H AIMSON R ESEARCH C ORPORATION This low pulse repetition mode of operation continues to provide interesting data related to structure BD and is influencing the planning and direction of future R&D efforts.

19 DC – High Directivity Directional Coupler FC – Faraday Cup M – Motor Drive PSh– Phase Shifter W – Ceramic RF Window DC SPECTROMETER R F W FC TRIPLE HYBRID M 17 GHz TWRK 94 CAVITY TW LINAC INJECTOR LOAD DC RFRF M PSh LOAD HYBRID DC 22 CAVITY TEST LINAC F R LOAD HYBRID RFRF DC FRFR F R DC (A) (B) H AIMSON R ESEARCH C ORPORATION AAC 08 19

20 H AIMSON R ESEARCH C ORPORATION Ivan Mastovsky Roark MarshBrian Munroe This is to acknowledge contributions of the MIT Plasma Science and Fusion Center Staff, especially the assistance of Ivan Mastovsky, Roark Marsh and Brian Munroe with the Ongoing RF Testing of the Gradient Hardened 17GHz Linac Structure. AAC 08 20

21 J. Haimson and B. Mecklenburg Haimson Research Corporation FG02-05ER84362 Work performed under the auspices of the U.S. Department of Energy SBIR Grant No. DE-FG02-05ER84362 DESIGN FEATURES AND INITIAL RF PERFORMANCE OF A GRADIENT HARDENED 17 GHz LINAC 21 AAC 08

Download ppt "J. Haimson and B. Mecklenburg Haimson Research Corporation FG02-05ER84362 Work performed under the auspices of the U.S. Department of Energy SBIR Grant."

Similar presentations

Tom Powers Practical Aspects of SRF Cavity Testing and Operations SRF Workshop 2011 Tutorial Session.

Tom Powers Practical Aspects of SRF Cavity Testing and Operations SRF Workshop 2011 Tutorial Session.
Breakdown Rate Dependence on Gradient and Pulse Heating in Single Cell Cavities and TD18 Faya Wang, Chris Nantista and Chris Adolphsen May 1, 2010.

Breakdown Rate Dependence on Gradient and Pulse Heating in Single Cell Cavities and TD18 Faya Wang, Chris Nantista and Chris Adolphsen May 1, 2010.
5th Collaboration Meeting on X-band Accelerator Structure Design and Test Program. May 2011 Review of waveguide components development for CLIC I. Syratchev,

5th Collaboration Meeting on X-band Accelerator Structure Design and Test Program. May 2011 Review of waveguide components development for CLIC I. Syratchev,
PAL/POSTECH 제 2 회 한국 국제선형충돌가속기 워크숍 Waveguide System for Linear Collider Woon-Ha Hwang Linac Division Pohang Accelerator Laboratory 2005,12,28.

PAL/POSTECH 제 2 회 한국 국제선형충돌가속기 워크숍 Waveguide System for Linear Collider Woon-Ha Hwang Linac Division Pohang Accelerator Laboratory 2005,12,28.
ESS End-to-End Optics and Layout Integration Håkan Danared European Spallation Source Catania, 6 July 2011.

ESS End-to-End Optics and Layout Integration Håkan Danared European Spallation Source Catania, 6 July 2011.
ON/OFF news. Reflected Transmitted Stroke 8.0 mm RF power, dB Piston position (gap width), mm ON OFF Compact design of the high RF power variable (mechanically)

ON/OFF news. Reflected Transmitted Stroke 8.0 mm RF power, dB Piston position (gap width), mm ON OFF Compact design of the high RF power variable (mechanically)
CARE07, 29 Oct. 2007 Alexej Grudiev, New CLIC parameters. The new CLIC parameters 29.10.2007 Alexej Grudiev.

CARE07, 29 Oct Alexej Grudiev, New CLIC parameters. The new CLIC parameters Alexej Grudiev.
1 X-band Single Cell and T18_SLAC_2 Test Results at NLCTA Faya Wang Chris Adolphsen Jul-9-2009.

1 X-band Single Cell and T18_SLAC_2 Test Results at NLCTA Faya Wang Chris Adolphsen Jul
Design of Standing-Wave Accelerator Structure

Design of Standing-Wave Accelerator Structure
Different mechanisms and scenarios for the local RF

Different mechanisms and scenarios for the local RF
Alessandro Cappelletti for CTF3 collaboration 5 th May 2010 RESULTS OF BEAM BASED RF POWER PRODUCTION IN CTF3.

Alessandro Cappelletti for CTF3 collaboration 5 th May 2010 RESULTS OF BEAM BASED RF POWER PRODUCTION IN CTF3.
CLIC Drive Beam Linac Rolf Wegner. Outline Introduction: CLIC Drive Beam Concept Drive Beam Modules (modulator, klystron, accelerating structure) Optimisation.

CLIC Drive Beam Linac Rolf Wegner. Outline Introduction: CLIC Drive Beam Concept Drive Beam Modules (modulator, klystron, accelerating structure) Optimisation.
HIGH RF POWER TESTING FOR THE CLIC PETS - 2010 International Workshop on Linear Colliders 20 th October 2010 Alessandro Cappelletti for the CLIC team with.

HIGH RF POWER TESTING FOR THE CLIC PETS International Workshop on Linear Colliders 20 th October 2010 Alessandro Cappelletti for the CLIC team with.
E. KAKO (KEK) 2009' Sept. 30 Albuquerque Global Design Effort 1 Cavity Test Items in S1-G Cryomodule Eiji Kako (KEK, Japan)

E. KAKO (KEK) 2009' Sept. 30 Albuquerque Global Design Effort 1 Cavity Test Items in S1-G Cryomodule Eiji Kako (KEK, Japan)
201 MHz NC RF Cavity R&D for Muon Cooling Channels

201 MHz NC RF Cavity R&D for Muon Cooling Channels
RF Distribution Alternatives R.A.Yogi & FREIA group Uppsala University.

RF Distribution Alternatives R.A.Yogi & FREIA group Uppsala University.
1 C-Band Linac Development Satoshi Ohsawa 2004.Feb.19LCPAC.

1 C-Band Linac Development Satoshi Ohsawa 2004.Feb.19LCPAC.
June 2007, CERN. HDS 60 (cells) copper was processed from both sides Low Vg a/λ=0.16 High Vg a/λ=0.19 HDS 11 titanium Very often we do observe, that after.

June 2007, CERN. HDS 60 (cells) copper was processed from both sides Low Vg a/λ=0.16 High Vg a/λ=0.19 HDS 11 titanium Very often we do observe, that after.
Clustered Surface RF Production Scheme Chris Adolphsen Chris Nantista SLAC.

Clustered Surface RF Production Scheme Chris Adolphsen Chris Nantista SLAC.
February 17-18, 2010 R&D ERL Alex Zaltsman R&D ERL High Power RF Systems Alex Zaltsman February 17-18, 2010 High Power RF Systems.

February 17-18, 2010 R&D ERL Alex Zaltsman R&D ERL High Power RF Systems Alex Zaltsman February 17-18, 2010 High Power RF Systems.

Similar presentations

Ads by Google