Development of Ultra High Power Compact X-Band Pulse Compressor

TL;DR

This paper presents a novel compact X-band RF pulse compressor using spherical cavities supporting TE modes, achieving high peak power and short pulse durations for high-gradient applications.

Contribution

The development and high-power testing of a new spherical cavity-based pulse compressor that improves robustness and performance for X-band RF applications.

Findings

Achieved peak power of 317 MW with 52 MW input pulses.

Compressed pulse width of 27 ns at full-width half-maximum.

Demonstrated viability for high-gradient RF photoinjectors.

Abstract

We demonstrate a new 11.424 GHz SLED-type RF pulse compressor for powering high-gradient X-band photoinjectors with pulse lengths around 20 ns. RF pulse compression provides a practical path to higher peak power at the cost of pulse length for various applications such as RF deflectors for electron beam diagnostics on free electron lasers. Our new compact pulse compressor uses spherical cavities supporting axially symmetric TE modes which have minimal electric fields on the cavity surfaces, intended to improve high-power robustness as compared to existing compact spherical SLEDs which use a TE dipole mode. We present the design of this pulse compressor composed of two spherical cavities and a waveguide hybrid. The two cavities and hybrid have TE01 circular waveguide ports. This pulse compressor was built and high power tested at SLAC. These tests demonstrated a peak power of 317 MW by compressing 52 MW, 1 {\mu}s pulses generated by a SLAC XL-4 klystron. The full-width at half-maximum of this compressed pulse was 27 ns. We conjecture that this development demonstrates a viable route to reaching the high-gradient, short pulse regime for accelerating structures and RF photoinjectors.