Average power scaling of THz spintronic emitters in reflection geometry

TL;DR

This study investigates the power scaling of metallic spintronic THz emitters under high-average-power excitation, demonstrating optimized efficiency and guiding principles for achieving high-power, broadband THz emission at high repetition rates.

Contribution

It provides the first detailed analysis of power scaling behavior of spintronic THz emitters with high-average-power femtosecond lasers, including efficiency optimization and cooling strategies.

Findings

Reflection geometry with back-side cooling is optimal for high-power operation.

Conversion efficiency depends mainly on incident fluence when cooled effectively.

Achieved a conversion efficiency of 5×10⁻⁶ at high excitation powers.

Abstract

Metallic spintronic THz emitters have become well-established for offering ultra-broadband, gap-less THz emission in a variety of excitation regimes, in combination with reliable fabrication and excellent scalability. However, so far, their potential for high-average-power excitation to reach strong THz fields at high repetition rates has not been thoroughly investigated. In this article, we explore the power scaling behavior of tri-layer spintronic emitters using an Yb-fiber excitation source, delivering an average power of 18.5 W at 400 kHz repetition rate, temporally compressed to a pulse duration of 27 fs. We confirm that the reflection geometry with back-side cooling is ideally suited for these emitters in the high-average-power excitation regime. In order to understand limiting mechanisms, we disentangle the effects on THz power generation by average power and pulse energy, by varying the repetition rate of the laser. Our results show that the conversion efficiency remains mostly dependent on the incident fluence in this high-average-power, high-repetition-rate excitation regime if the emitters are efficiently cooled. Using these findings, we optimize the conversion efficiency to reach 5e-6 at highest excitation powers in the back-cooled reflection geometry. Our findings provide guidelines for scaling the power of THz radiation emitted by spintronic emitters to the mW-level by using state-of-the-art femtosecond sources with multi-hundred-Watt average power to reach ultra-broadband, strong-field THz sources with high repetition rate.