Experimental and Numerical Investigations into Terahertz Time-Domain Spectroscopy

Abstract

This Master's thesis presents numerical and experimental results that benchmark a state-of-the-art terahertz time-domain spectrometer. We begin by describing the theory behind the nonlinear optical mechanisms through which we generate and detect short pulses of THz radiation. Based on a coherent electro-optic detection scheme, our measurements trace out the oscillating electric field of the THz pulses generated from the optical mixing process of optical rectification. A numerical simulation based on the theory presented in this work helps present the physical intuition behind our use of these nonlinear optical processes and is furthermore used to complement our measurements with theory. Utilizing the simultaneous amplitude and phase information provided by our detection scheme, we perform terahertz time-domain spectroscopy on sample materials. Our samples of interest are the III-V zinc-blende semiconductors GaP and ZnTe which are nonlinear media popular for their advantageous dispersive and absorptive properties in the terahertz range. Therefore, the thesis culminates in the demonstration of a material parameter extraction procedure which we use to obtain the complex refractive index of a GaP crystal and a ZnTe crystal.