Ultra-broadband photonic sampling of optical waveforms

TL;DR

This paper introduces GHOSTs, a novel all-optical sampling method that surpasses traditional bandwidth limits by controlling light-pulse waveforms, enabling ultra-broadband optical waveform measurement.

Contribution

The paper proposes GHOSTs, a new heterodyne optical-sampling technique that overcomes bandwidth limitations of existing methods through waveform control.

Findings

GHOSTs achieve broader bandwidth than previous methods.

The technique enhances sensitivity in optical waveform sampling.

Potential applications in physics, chemistry, and medicine.

Abstract

Direct access to the electric field of light provides a subcycle view of the polarization response of matter, thus enabling sensitive metrology in physics, chemistry, and medicine. Optical-field sampling techniques take advantage of some process that lasts much less than an optical cycle of the measured light wave. Most of them rely on the generation of free electrons either by a weak extreme ultraviolet pulse or by a strong optical pulse. The ability of such techniques to detect weak signals is limited by undesirable effects associated with ionization. An alternative is all-optical methods, where the fast process is a nonlinear wave mixing. Such photonic methods may rely on extreme ultraviolet or optical pulses. They typically have better sensitivity, but smaller bandwidth. Here we propose generalized heterodyne optical-sampling techniques (GHOSTs), which overcome the bandwidth limit through controlling light-pulse waveforms.