Flatfield Ultrafast Imaging with Single-Shot Non-Synchronous Array Photography

TL;DR

SNAP is a novel imaging technique that captures a sequence of time-resolved images in a single shot by splitting a laser pulse into multiple beamlets with different delays, enabling ultrafast scene evolution capture at teraframe rates.

Contribution

This paper introduces SNAP, a new single-shot ultrafast imaging method that uses non-synchronous beamlet arrays to achieve high temporal resolution limited only by laser pulse duration.

Findings

Captured laser-induced plasma evolution at 20 frames.

Achieved an average rate of 4.2 Tfps.

Demonstrated effective single-shot ultrafast imaging.

Abstract

We present a method for acquiring a sequence of time-resolved images in a single shot, called Single-Shot Non-Synchronous Array Photography (SNAP). In SNAP, a pulsed laser beam is split by a diffractive optical element into an array of angled beamlets whose illumination fronts remain perpendicular to the optical axis. Different time delays are imparted to each beamlet by an echelon, enabling them to probe a scene in rapid succession. The beamlets are then imaged onto different regions of a camera by a lenslet array. Because the illumination fronts remain flat (head-on) independently of beamlet angle, the temporal resolution of SNAP is fundamentally limited only by the laser pulse duration, akin to a "global shutter" in conventional imaging. We demonstrate SNAP by capturing the evolution of a laser induced plasma filament for 20 frames at an average rate of 4.2 Tfps.