1. MICROWAVE AMPLIFIERS Alan Phelps A.W. Cross, K. Ronald, C.G. Whyte, A.R. Young, W. He, I.V. Konoplev, A.W. Cross, K. Ronald, C.G. Whyte, A.R. Young, W. He, I.V. Konoplev, D. Barclay, H. Yin, C.W. Robertson, D.C. Speirs, C.R. Donaldson, P. MacInnes, S.L. McConville, K.M. Gillespie, L. Fisher, F. Li, M. McStravick, L. Zhang, D. Constable, D. Bowes, K.A. Matheson, R. Bryson, M. King, P. McElhinney Department of Physics, SUPA, University of Strathclyde, Glasgow, G4 0NG, UK ABP CarterFest 14 July 2010

2. Introduction  Links with Richard  Microwave amplifiers - background  Fast wave amplifiers  THz trends with miniature conventional devices  Conclusions

3. Links with Richard ~150 miles

4. < 150 yds ?

5. Creative location for:  NVEC conference series  Faraday Partnership in HPRF  MSc degree in HPRF

6. Microwave amplifiers - background Gyro-TWA Strathcyde

7. Simulations are increasingly important for vacuum electronic microwave amplifiers  Modelling – using MAGIC, KARAT, SURETRAJ, OPERA, MICROWAVE STUDIO, COMSOL, VORPAL  Electron beam research using thermionic, plasma flare, field emission array and pseudospark cathodes  Design, construction and measuring output of high power mm-wave vacuum electronic devices. Includes research, design and construction of couplers, cavities, converters, collectors and windows  (i) high power mm-wave diagnostics (ii) power supplies to drive the devices (ii) power supplies to drive the devices

8. High power microwave amplifiers  High power broadband amplifiers are generally more difficult to achieve than the single frequency oscillators  A solution Strathclyde has been working on for several years is the helical waveguide gyro-TWA (a type of gyro-TWT)

9. Where s is an integer, ω c is the cyclotron frequency and ω co is the cut-off frequency of the waveguide. Use of dispersion graphs to design new RF sources

11. Ideal dispersion can be realized by using a helically corrugated interaction waveguide It changes the dispersion diagram such that an eigenwave of a constant group velocity (V g =V b ) exists in the near-infinite phase velocity region (k z =0) for a very wide frequency band. k z Conventional Gyro-TWT  Ideal Gyro-amplifier dispersion  k z High power microwave amplifiers

12. Synthesis of Ideal mode to create new sources

13. Gyro -TWA amplifier schematic Kicker Helical waveguide with tapers Main solenoid High power microwave amplifiers Physical Review Letters 81, 5680-5683, 1998 Physical Review Letters 84, 2746-2749, 2000 Physical Review Letters 92, art 118301, 2004

14. Wideband W-band gyro-device

15. Helical interaction waveguide - High power, high frequency, high efficiency - Wide frequency band

16. Predicted Performance Centre freq.  95 GHz Freq. bandwidth  10% Maximum power  10 kW Efficiency  15% Gain = 40dB Gyro-TWA

17. Depressed Collector Simulation Simulation uses 3D PIC code MAGIC Not an amplifier but a gyro-BWO - however the genetic algorithm is used to optimize geometry (another link to Richard) Simulation of X-band gyro-BWO and W-band gyro-BWO L. Zhang, et al, IEEE Trans. Plasma Sci., 37, 390-394, 2009 L. Zhang, et al, IEEE Trans. Plasma Sci., 37, 2328-2334, 2009 Primary True secondary Rediffused

18. Mm-wave sources using a pseudospark generated electron beam 8

19. Experimental setup of the 14-gap PS powered by a cable pulser and beam-wave interaction investigation

20. 1 mm aperture single gap pseudospark beam measurements Measured small size (1 mm) beam

21. 206 GHz four cavity klystron

22. Conclusions  High power mm-wave amplifiers – novel solutions  Gyro amplifiers 100 to 1000 times higher powers  MM-wave research also moving into THz range  Vacuum electronics can’t be matched by solid state in some parameter ranges in some parameter ranges  In NVEC several papers will expand on this brief overview

23. Acknowledgements Support from EPSRC, STFC, RSE, RS, EU, Dstl, The Faraday Partnership, e2v & TMD

24. Best wishes Richard for an active and interesting retirement