Terahertz Spectroscopy of Dynamic YBa2Cu3O7-δ Thin Films

Abstract

<p> The optical properties of high temperature superconductors have long been of interest to condensed matter physicists. The majority of the research has concentrated on the steady-state properties of cuprates. Optical excitation of cuprate superconductors provides the valuable opportunity to study the dynamics of the superconducting state via the evolution of the superconducting condensate and excited quasiparticles. Terahertz (THz) spectroscopy is particularly attractive for the study of thin film cuprates, as the energies available in broad spectrum THz pulses lie below the maximum superconducting gap values. Optical pump THz probe spectroscopy utilizes a high energy infrared pulse to destroy the condensate and excite quasiparticles states out of equilibrium. The THz probe is capable of spectrally resolving the sample's temporal response to the optical perturbation. The direct measurement of both the amplitude and phase of the electric fields associated with the transmitted THz radiation allow for the calculation of both the real and imaginary parts of the conductivity. This offers the tantalizing potential of untangling the condensate's recovery from quasi-particle dynamics.</p> <p> The focus of this thesis will be upon the long timescale dynamics of YBa2Cu3O7-δ (YBCO) thin films. It has generally been believed that the condensate is fully recovered after a few picoseconds, and that the recovery of these films at longer timescales is essentially a thermal process although perhaps slowed by a phonon bottleneck. However, we will show spectral evidence that this picture cannot fully explain long lived dynamics in YBCO thin films. Specifically we see a suppression of the low frequency components of the optical conductivity. This anomaly is consistent with the formation of spatial inhomogeneity in the superconducting fraction, which likely arises from a non-uniform formation of the condensate across the film. The role of local inhomogeneity in the condensate and its effect on the conductivity of the thin film will be discussed. Evidence of intrinsic inhomogeneities in YBCO films may prove useful to the theoretical understanding of condensate dynamics in the cuprates. The spectral response of three doping levels, from optimally doped to underdoped YBCO, will also be shown, with a brief discussion of the normal state dynamics in underdoped films and the possible sensitivity of THz radiation to pseudogap dynamics.</p>