# Superradiant terahertz free-electron laser driven by electron microbunch trains

**Authors:** Yifan Liang, Tong Li, Jitao Sun, Zhuoyuan Liu, Jiayue Yang, Xiaofan Wang, Yong Yu, Qili Tian, Zhigang He, Hongfei Wang, Li Zeng, Huaiqian Yi, Hao Sun, Yingjie Dai, Xiujie Deng, Guorong Wu, Weiqing Zhang, Xueming Yang, Chuanxiang Tang, Lixin Yan

PMC · DOI: 10.1038/s41377-025-02156-7 · 2026-01-08

## TL;DR

A new superradiant terahertz free-electron laser is demonstrated using electron microbunch trains, enabling high-intensity THz radiation.

## Contribution

An ultra-widely tunable superradiant THz FEL is demonstrated with millijoule-level pulse energy using tapered undulators.

## Key findings

- Ultra-short electron microbunches enhance THz emission efficiency through in-phase radiation.
- Tapered undulators double the emission intensity compared to non-tapered setups.
- Narrow-band THz pulses reach millijoule energy levels in a one-meter undulator.

## Abstract

Superradiance, an enhanced radiation phenomenon stemming from the phase synchronization of emitters, features a radiation intensity proportional to the number of emitters squared. The pursuit of superradiance from free electrons has long been a goal for generating intense radiation across a broad spectrum, from terahertz (THz) to the X-ray regime. However, achieving superradiance in the THz spectral range has been hindered by the lack of effective microbunching techniques. Here, we demonstrate an ultra-widely tunable superradiant THz free-electron laser (FEL) driven by high-peak-current electron microbunch trains. The emission efficiency is substantially improved as the ultra-short electron microbunches emit in phase and engage in strong interactions with the generated THz waves within the undulator. We further demonstrate that the implementation of a tapered undulator configuration leads to a two-fold enhancement in emission intensity compared to the non-tapered case, elevating the pulse energy of the narrow-band THz radiation to the millijoule level in a one-meter-long undulator. This experimental breakthrough represents a critical step toward realizing a compact, high-power, narrow-band THz source capable of fully bridging the ‘THz gap’ and will unlock numerous opportunities across a wide range of scientific disciplines.

## Full-text entities

- **Chemicals:** Ti (MESH:D014025), CO2 (MESH:D002245), BBO (-), gold (MESH:D006046)

## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12779983/full.md

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Source: https://tomesphere.com/paper/PMC12779983