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Time-variant parity-time symmetry in frequency-scanning systems

Mingjian Li, Tengfei Hao, Guozheng Li, Anle Wang, Yitang Dai, Wei Li, J. Capmany, Jianping Yao, Ninghua Zhu, Ming Li, Ming Li, Ming Li

2024Nature Communications14 citationsDOIOpen Access PDF

Abstract

Parity-time (PT) symmetry is an active research area that provides a variety of new opportunities for different systems with novel functionalities. For instance, PT symmetry has been used in lasers and optoelectronic oscillators to achieve single-frequency lasing or oscillation. A single-frequency system is essentially a static PT-symmetric system, whose frequency is time-invariant. Here we investigate time-variant PT symmetry in frequency-scanning systems. Time-variant PT symmetry equations and eigenfrequencies for frequency-scanning systems are developed. We show that time-variant PT symmetry can dynamically narrow the instantaneous linewidth of frequency-scanning systems. The instantaneous linewidth of a produced frequency-modulated continuous-wave (FMCW) waveform is narrowed by a factor of 14 in the experiment. De-chirping and radar imaging results also show that the time-variant PT-symmetric system outperforms a conventional frequency-scanning one. Our study paves the way for a new class of time-variant PT-symmetric systems and shows great promise for applications including FMCW radar and lidar systems. Frequency-scanning systems with narrow instantaneous linewidth hold promise for various fields. Here, the authors report the use of time-variant parity-time symmetry to dynamically narrow the instantaneous linewidth of frequency-scanning systems.

Topics & Concepts

Laser linewidthChirpSymmetry (geometry)PhysicsParity (physics)Time–frequency analysisLasing thresholdWaveformOscillation (cell signaling)RadarOpticsComputer scienceLaserMathematicsTelecommunicationsAtomic physicsGeometryBiologyGeneticsQuantum Mechanics and Non-Hermitian PhysicsNonlinear Photonic SystemsNonlinear Waves and Solitons