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Single-shot compressed optical field topography

Haocheng Tang, Ting Men, Xianglei Liu, Yaodan Hu, Jingqin Su, Yanlei Zuo, Ping Li, Jinyang Liang, M. C. Downer, Zhengyan Li

2022Light Science & Applications75 citationsDOIOpen Access PDF

Abstract

Femtosecond lasers are powerful in studying matter's ultrafast dynamics within femtosecond to attosecond time scales. Drawing a three-dimensional (3D) topological map of the optical field of a femtosecond laser pulse including its spatiotemporal amplitude and phase distributions, allows one to predict and understand the underlying physics of light interaction with matter, whose spatially resolved transient dielectric function experiences ultrafast evolution. However, such a task is technically challenging for two reasons: first, one has to capture in single-shot and squeeze the 3D information of an optical field profile into a two-dimensional (2D) detector; second, typical detectors are only sensitive to intensity or amplitude information rather than phase. Here we have demonstrated compressed optical field topography (COFT) drawing a 3D map for an ultrafast optical field in single-shot, by combining the coded aperture snapshot spectral imaging (CASSI) technique with a global 3D phase retrieval procedure. COFT can, in single-shot, fully characterize the spatiotemporal coupling of a femtosecond laser pulse, and live stream the light-speed propagation of an air plasma ionization front, unveiling its potential applications in ultrafast sciences.

Topics & Concepts

Ultrashort pulseFemtosecondOpticsPhysicsLaserFemtosecond pulse shapingLight fieldSingle shotLaser-Matter Interactions and ApplicationsLaser-Plasma Interactions and DiagnosticsLaser-induced spectroscopy and plasma
Single-shot compressed optical field topography | Litcius