Microwave vortex beam lasing via photonic time crystals

TL;DR

This paper demonstrates the first surface-emitted microwave vortex beam laser with orbital angular momentum using photonic time crystals, enabling gain-free, non-reciprocal, and OAM-carrying microwave emission for advanced applications.

Contribution

It introduces a novel ring-shaped photonic time crystal design that achieves OAM microwave lasing without gain media and demonstrates non-reciprocal mode control.

Findings

Achieved over 100% permittivity modulation depth.

Established momentum bandgaps enabling microwave amplification.

Demonstrated selective OAM microwave lasing with non-reciprocity.

Abstract

Microwave lasing carrying orbital angular momentum (OAM) holds significant potential for advanced applications in fields such as high-capacity communications, precision sensing, and radar imaging. However, conventional approaches to masers fail to produce emission with embedded OAM. The recent emergence of photonic time crystals (PTCs)-artificially structured media with periodically varying electromagnetic properties in time-offers a paradigm shift toward resonance-free lasing without the need for gain media. Yet, pioneering PTC designs have been based on three-dimensional bulk structures, which lack a surface-emitting configuration, and do not possess the capability to modulate OAM, thus hindering the realization of surface-emitted PTC masing that carries OAM. Here, we report the first experimental demonstration of non-resonant, gain medium-free, and surface-emitted microwave vortex beam lasing OAM using ring-shaped PTCs. By developing a multiplier-driven time-varying metamaterial that achieves over 100% equivalent permittivity modulation depth, we establish momentum bandgaps (k gaps) with sufficient bandwidth to overcome intrinsic losses and enable self-sustained coherent microwave amplification. Furthermore, space-time modulation induces non-reciprocity between clockwise and counterclockwise k gap modes within the circularly symmetric PTC structure, facilitating the selective generation of microwave lasing carrying OAM-a capability beyond the reach of conventional maser technologies. Our work bridges PTC physics with coherent OAM-carrying microwave emission, establishing a transformative platform for next-generation wireless communications, advanced sensing systems, and OAM-based technologies.