Terahertz emission from ZnGeP2: Phase-matching, intensity and length scalability

TL;DR

This study investigates terahertz generation in ZnGeP2 using phase-matched optical rectification, analyzing how crystal length, pump intensity, and phase-matching affect pulse quality and efficiency.

Contribution

It provides detailed analysis of phase-matching, absorption effects, and scalability parameters for terahertz emission in ZnGeP2, including experimental and numerical insights.

Findings

Optimal crystal thickness (~1 mm) for undistorted terahertz pulses at high intensity.

Longer crystals or higher intensities cause pulse distortion due to phase mismatch.

Phase-matching dispersion maps enable tuning over 1.1-2.4 microns.

Abstract

Collinear phase-matched optical rectification is studied in ZnGeP$_{2}$ pumped with near-infrared light. The pump-intensity dependence is presented for three crystal lengths (0.3, 1.0 and 3.0 mm) to determine the effects of linear optical absorption, nonlinear optical absorption and terahertz free-carrier absorption on the generation. Critical parameters such as the coherence length (for velocity matching), dispersion length (for linear pulse broadening) and nonlinear length (for self-phase modulation) are determined for this material. These parameters provide insight into the upper limit of pulse intensity and crystal length required to generate intense terahertz pulse without detriment to the pulse shape. It is found that for 1-mm thick ZnGeP$_{2}$(012), pumped at 1.28 micron with intensity of ~15 GW/cm2 will produce intense undistorted pulses, whereas longer crystals or larger intensities modify the pulse shape to varying degrees. Moreover, phase-matching dispersion maps are presented for the terahertz generation over a large tuning range (1.1-2.4 micron) in longer (3 mm) crystal, demonstrating the phase-matching bandwidth and phase mismatch that leads to fringing associated with multi-pulse interference. All observed results are simulated numerically showing good qualitative agreement.