Quartz as an Accurate High-Field Low-Cost THz Helicity Detector

TL;DR

This paper demonstrates that z-cut α-quartz can serve as a precise, low-cost electrooptic detector for full amplitude, phase, and polarization measurement of intense THz fields, enabling advanced THz polarization and helicity analysis.

Contribution

It establishes α-quartz as a reliable, cost-effective THz detector with a well-characterized response function for complete polarization measurements.

Findings

Complex detector response function determined experimentally

Good agreement between model and experimental response

Enables rapid, cost-efficient THz polarization analysis

Abstract

The advent of high-field THz sources has opened the field of nonlinear THz physics and unlocked access to fundamental low energy excitations for ultrafast material control. Recent advances towards controlling and employing chiral excitations, or generally angular momentum of light, not only rely on the measurement of undistorted intense THz fields, but also on the precise knowledge about sophisticated THz helicity states. A recently reported and promising detector material is $\alpha$-quartz. However, its electrooptic response function and contributing nonlinear effects have remained elusive. Here, we establish z-cut $\alpha$-quartz as a precise electrooptic THz detector for full amplitude, phase and polarization measurement of intense THz fields, all at a fraction of costs of conventional THz detectors. We experimentally determine its complex detector response function, which is in good agreement with our model based on predominantly known literature values. It also explains previously observed thickness-dependent waveforms. These insights allow us to develop a swift and reliable protocol to precisely measure arbitrary THz polarization and helicity states. This two-dimensional electrooptic sampling (2D-EOS) in $\alpha$-quartz fosters rapid and cost-efficient THz time-domain ellipsometry, and enables the characterization of polarization-tailored fields for driving chiral or other helicity-sensitive quasiparticles and topologies.