Latest Results in SLAC 75 MW PPM Klystrons

Sprehn, D.; Caryotakis, G.; Haase, Andy; Jongewaard, E.; Laurent, L.; Pearson, C.; Phillips, R.

doi:10.1063/1.2158768

Cited by 8 publications

(6 citation statements)

References 3 publications

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“…The difference can be attributed to the difference between the simulated and measured magnetic field, the somewhat sensitive nature of the weakly confined flow optics to variations, and the fact that all electron beams have a varying radial current-density distribution and halo electrons which are not readily known or modeled by the simulation codes. For comparison, the various SLAC PPMfocused klystrons that were made had reported beam-current transmissions ranging from 93% to 98.7% at saturated output [12], [13]. The small increase in transmission at 9320 MHz in the figure appears to be due to overall slightly faster moving electrons at that frequency.…”

Section: B Rf Performancementioning

confidence: 86%

Design and Operation of a 2.7 MW Periodic Permanent Magnet Focused X-band Klystron

Balkcum

Begum

Cattelino

et al. 2010

IEEE Trans. Plasma Sci.

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A compact periodic permanent magnet focused 9290 MHz klystron is described that produces 2.7 MW of output power with 52 dB of gain and 43% efficiency. Three klystrons have been manufactured that exhibited a high degree of repeatability and robustness with all meeting the performance requirements. The goal of a first-time-through design success was met through the use of extensive multidimensional modeling of all aspects of the klystron. Agreement between simulated and measured performance was very good.

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Section: B Rf Performancementioning

confidence: 86%

Design and Operation of a 2.7 MW Periodic Permanent Magnet Focused X-band Klystron

Balkcum

Begum

Cattelino

et al. 2010

IEEE Trans. Plasma Sci.

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“…Neither it is economical to build and operate a high power RF source such as a klystron with the output pulse width reduced to sub-microsecond level. When a certain klystron is being operated at such a short pulse width, the peak output does not increase significantly as the pulse width shrinks, and the RF power in one pulse is much lower compared to a longer pulse of several microseconds [5]. The efficiency of such a system will also be very low, since the switching time of the modulator is at the level of several hundred nanoseconds and the loss during the switching is huge.…”

Section: Rf Pulse Compression Systemsmentioning

confidence: 99%

The Development of the Electrically Controlled High Power RF Switch and Its Application to Active RF Pulse Compression Systems

Guo

2008

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In the past decades, there has been increasing interest in pulsed high power RF sources for building high-gradient high-energy particle accelerators. Passive RF pulse compression systems have been used in many applications to match the available RF sources to the loads requiring higher RF power but a shorter pulse. Theoretically, an active RF pulse compression system has the advantage of higher efficiency and compactness over the passive system. However, the key component for such a systeman element capable of switching hundreds of megawatts of RF power in a short time compared to the compressed pulse width -is still an open problem.In this dissertation, we present a switch module composed of an active window based on the bulk effects in semiconductor, a circular waveguide three-port network and a movable short plane, with the capability to adjust the S-parameters before and after switching. The RF properties of the switch module were analyzed. We give the scaling laws of the multiple-element switch systems, which allow the expansion of the system to a higher power level.We present a novel overmoded design for the circular waveguide three-port network and the associated circular-to-rectangular mode-converter. We also detail the design and synthesis process of this novel mode-converter.We demonstrate an electrically controlled ultra-fast high power X-band RF active window built with PIN diodes on high resistivity silicon. The window is capable of handling multi-megawatt RF power and can switch in 2-300ns with a 1000A current driver. A low power active pulse compression experiment was carried out with the switch vi module and a 375ns resonant delay line, obtaining 8 times compression gain with a compression ratio of 20.vii ACKNOWLEDGMENTS

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“…Although many promising results are summarized in [4] and [5], this line of study did not lead to the use of gyroklystrons as drivers for accelerating cavities and klystrons are still the industry standard. Commercially available klystrons can comfortably deliver the required power at the C-band and X-band drive frequencies which are currently favored in accelerator design [6].…”

Section: Introductionmentioning

confidence: 99%

Design of a 48 GHz Gyroklystron Amplifier

Nix

Zhang

Cross

2021

IEEE Trans. Electron Devices

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The continued development of linear accelerators at higher frequencies poses several technological challenges. One such challenge is the requirement for high-frequency amplifiers to drive linearization systems. Presented in this article is the design of a 48 GHz gyroklystron amplifier appropriate for application in a harmonic linearizer for a 6 GHz or 12 GHz drive frequency. The beam used in the gyroklystron is provided by a magnetron injection gun (MIG), which has been designed using genetic optimization. The gyroklystron interaction circuit was designed with the aid of a Particle-in-Cell (PIC) simulation study which predicted 2 MW of output power at 48 GHz with a gain of 35 dB and an efficiency of 38%. This article summarizes the preceding work on the interaction circuit and MIG with additional phase stability analysis as well as presenting the design and analysis of vacuum windows, an input coupler, and the collector.

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Latest Results in SLAC 75 MW PPM Klystrons

Cited by 8 publications

References 3 publications

Design and Operation of a 2.7 MW Periodic Permanent Magnet Focused X-band Klystron

Design and Operation of a 2.7 MW Periodic Permanent Magnet Focused X-band Klystron

The Development of the Electrically Controlled High Power RF Switch and Its Application to Active RF Pulse Compression Systems

Design of a 48 GHz Gyroklystron Amplifier

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