Physical and Theoretical Chemistry

Biography

Biography: Tadashi Ogitsu

Abstract

Electrochemical processes are ubiquitously seen in problems relevant for our life, yet, extremely challenging to gain an accurate atomistic information due to its complex and dynamical nature. However, recent progresses on ab-initio computer simulation techniques combined with the advancement in high performance computing made direct simulations of complex electrochemical interfaces possible albeit connection to the corresponding real problem often is not apparent. On the other hand, there are many experimental probes that provides chemical and physical information of such problems albeit interpretation of such experimental data tends not to be straightforward. In this presentation, we will demonstrate how a combination of ab-initio simulations and in-operando characterization techniques such as ambient-pressure X-ray photoemission spectroscopy (AP-XPS) can be used to gain atomistic insights into electrochemical problems. We will discuss how AP-XPS data taken for oxidation of III-V semiconductors (GaP/InP) induced by chemical agents such as oxygen and/or water can be interpreted with the help of ab-initio simulations. Most importantly, ab-initio simulations provide information regarding relation between thermodynamic stability of structural models and their spectroscopic signatures that will give us confidence in interpreting the experimental data. This is particularly the case, when comprehensive set of spectroscopic information for the given problem is available. We show that one can effectively narrow down the candidate surface oxidation models based on systematic theory-experiments comparisons on O1s, P2p core-level binding energies, surface workfunction shift as well as their stabilities. Such a comprehensive theory-experiments comparison will lead to deeper understanding of electrochemical processes such as hydrogen/oxygen evolution and/or material corrosions that will facilitate improvements of the energy conversion/storage technologies.

This work was performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344, and is supported by the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, Fuel Cell Technologies Office.