Single-pass high-efficiency terahertz free-electron laser

The terahertz gap is a region of the electromagnetic spectrum where high average and peak power radiation sources are scarce while at the same time scientific and industrial applications are growing in demand. Free-electron laser (FEL) coupling in a magnetic undulator is one of the best options for radiation generation in this frequency range, but slippage effects require the use of relatively long and low-current electron bunches to drive the terahertz FEL, limiting amplification gain and output peak power. Here we use a circular waveguide in a 0.96-m strongly tapered helical undulator to match the radiation and electron-beam velocities, allowing resonant energy extraction from an ultrashort 200-pC 5.5-MeV electron beam over an extended distance. Electron-beam spectrum measurements, supported by energy and spectral measurement of the terahertz FEL radiation, indicate an average energy efficiency of similar to 10%, with some particles losing >20% of their initial kinetic energy.

Automated summary

The terahertz gap is a region in the electromagnetic spectrum where high power radiation sources are scarce but the demand for scientific and industrial applications is increasing. This study demonstrates the use of a circular waveguide and a strongly tapered helical undulator to efficiently extract resonant energy from a short electron beam, resulting in an average energy efficiency of about 10%.