Removal of spectral distortion due to echo for ultrashort pulses propagating through multilayer structures with thick substrate

TL;DR

This paper presents an analytical method to remove echo-induced spectral distortions in ultrashort pulses transmitted through multilayer structures with thick substrates, improving modeling accuracy in time-domain spectroscopy.

Contribution

The authors introduce a novel analytical approach to eliminate echoes from transmission spectra, simplifying computations and enhancing comparison with experimental data.

Findings

Effective removal of spectral echo distortion achieved

Reduced computational complexity and time

Enhanced accuracy in modeling ultrashort pulse transmission

Abstract

Given the wide range of applications of time-domain spectroscopy, and particularly THz time-domain spectroscopy, the modelling of a probe pulse propagating through a multilayered structure is often required. Due to the fact that the multilayers are usually grown on a substrate much thicker than the other layers, the transmission of a probe pulse includes a series of echo pulses caused by the multiple reflections at the substrate interfaces. Experiments often measure the time profile and construct the transmitted spectrum only from the first transmitted pulse. Due to the fact that typical substrates lead to times of crossing comparable to the spectral bandwidth, the first transmitted pulse's spectrum and the full transmitted spectrum can be importantly different. It is therefore important to theoretically model the transmission without the echo, to be able to directly compare with experimental results. Here we propose a method to elegantly and easily theoretically remove the echo from the transmission spectrum, without Fourier transforming the signal twice. The spectrum of the transmitted pulse without echo will be produced analytically without additional numerical steps, reducing computational time and program complexity when dealing with larger scale computing.