Detailseite
Projekt Druckansicht

Modellierung der elektrischen Doppelschicht an Metalloxid-Elektroden/Elektrolyt-Grenzflächen durch Dichtefunktionaltheorie-basierte Molekulardynamik

Antragsteller Dr. Chao Zhang
Fachliche Zuordnung Theoretische Chemie: Moleküle, Materialien, Oberflächen
Physikalische Chemie von Molekülen, Flüssigkeiten und Grenzflächen, Biophysikalische Chemie
Theoretische Chemie: Elektronenstruktur, Dynamik, Simulation
Förderung Förderung von 2014 bis 2017
Projektkennung Deutsche Forschungsgemeinschaft (DFG) - Projektnummer 263270542
 
Erstellungsjahr 2018

Zusammenfassung der Projektergebnisse

Most earth-abundant metal oxides for electrocatalysis are operated in alkaline solution (pH 14), the surface of oxides is known to undergo hydroxylation in the presence of adsorbed water molecules. When deprotonated at high pH, acidic sites acquire a negative charge and form an electric double layer (EDL) by attracting hydrated counter ions in solution. Thus, modeling and simulation of at the metal oxide electrode/electrolyte interfaces is an integral part of optimizing the cost efficiency of energy conversion. In this project, by combining concepts of (single) electrode potentials in electrochemistry and Berry phase polarization in periodic systems for the first time, we were able to charge the double layer at fixed chemical composition similar to experiments and to have the macroscopic polarization as a new observable. According to the classical Debye theory, switching the electric boundary condition from constant potential (E) to constant charge (D) leads to a speed-up of the relaxation time of the macroscopic polarization by a factor comparable to the dielectric constant of the medium. This would be two orders of magnitude difference for aqueous solutions and makes electric properties of oxide/electrolyte interfaces accessible to density functional theory based molecular dynamics (DFTMD). Adapting constant electric displacement D method originally designed for treating spontaneous polarization in groundstate ferroelectric systems, we showed that the simulation of finite temperature polarization fluctuations and dielectric constant in polar liquids are now doable in DFTMD. The advantage of constant D method is not only to speed up simulations but also to eliminate the finite size effect for modeling EDL due to the periodic boundary condition. We have also shown that the computed Helmholtz capacitance is independent of the size of charged insulator slab using constant electric displacement simulations. This methodology was further extended to treat the charge compensation between polar surfaces and the electrolyte solution. This series of works lays down the methodological foundations for DFTMD modeling of structural, dynamical and dielectric properties at charged oxide-electrolyte interfaces. Follow-up works in this area are expected in the near future.

Projektbezogene Publikationen (Auswahl)

 
 

Zusatzinformationen

Textvergrößerung und Kontrastanpassung