University of Illinois Urbana-Champaign

Reimagining of optical kerr effect spectroscopy: development of a new spectroscopic technique

Brister, Matthew M.

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https://hdl.handle.net/2142/107317

Description

Title
Reimagining of optical kerr effect spectroscopy: development of a new spectroscopic technique
Author(s)
Brister, Matthew M.
Contributor(s)
  • Slaughter, Daniel S.
  • Shivaram, Niranjan
  • Weber, Thorsten
  • Tan, Liang Z.
  • Thurston, Richard
Issue Date
2020-06-25
Keyword(s)
Dynamics and kinetics
Abstract
Multidimensional nonlinear spectroscopic methods are powerful tools to investigate ultrafast vibrational dynamics and coherences. Several techniques that have recently been applied to excited electronic states require three or more ultrashort pulses to measure the nonlinear optical response. The additional beamsplitters, mirrors and optical delay stages in these techniques complicates their application in the extreme ultraviolet and X-ray regime, where reflectance is low except at grazing incidence. Optical Kerr effect spectroscopy is a traditional two-pulse technique to measure the 3$^{rd}$-order nonlinear optical susceptibility of molecules in their ground electronic state. Ultrafast transient polarization spectroscopy (UTPS) is an extension of this technique to excited electronic states, enabling coupled electronic and nuclear dynamics to be investigated by the 3$^{rd}$-order nonlinear optical susceptibility. In UTPS, a pump pulse excites a population, then a Kerr gate and probe pulse monitor the 3$^{rd}$-order nonlinear response of excited-state molecules, as a function of delay between each of the three pulses. Two-photon absorption of femtosecond pump pulses populate the S$_{1}$ excited-state of nitrobenzene. We were able to extract a dephasing time that oscillates as function of the time delay after excitation. This dephasing time and supporting theoretical calculation allows for distinguishing between an intersystem crossing conical intersection and an internal conversion conical intersection on the same excited-state potential energy surface.
Publisher
International Symposium on Molecular Spectroscopy
Type of Resource
Text
Language
eng
Permalink
http://hdl.handle.net/2142/107317
Copyright and License Information
Copyright 2020 is held by the Author(s)

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Abstracts & Presentations - 2020 International Symposium on Molecular Spectroscopy PRIMARY