Understanding Mobile Particles in Solid-State Materials: From the Perspective of Potential Energy Surfaces

Fabian Schwarz, Senja Barthel, Amber Mace*

*Corresponding author for this work

Research output: Contribution to JournalArticleAcademicpeer-review

Abstract

The structure and dynamics of a material are essentially determined by the complex combination of potential energy landscapes experienced by the individual atoms in the system. In turn, valuable information on the properties of the material is encoded in the shapes of the potential energy landscape.For example, configurations of particles within a solid are determined by the shapes and presence of energetic basins, and the self-diffusion of mobile particles is defined by the geometry of how these energetic basins are connected to form paths.Understanding diffusion processes in solids at the atomistic scale is crucial for many important applications such as predicting Li-ion conduction through a solid-state battery cell or membranes for separation processes including carbon capture and water purification. While modeling can facilitate such understanding, there are still many challenges to overcome in terms of reaching relevant length and time scales that capture the complexity of the material. In this Perspective, we will discuss state-of-the-art modeling methods for mass transport inside a solid-state material and how they relate to the geometry of the potential energy landscape. We believe that approaching diffusion from a geometrical standpoint offers great promise in advancing modeling methodologies while yielding a better understanding of the structure-dynamic properties relationship and rate-limiting processes.
Original languageEnglish
Pages (from-to)11359-11376
Number of pages18
JournalChemistry of Materials
Volume36
Issue number23
DOIs
Publication statusPublished - 21 Nov 2024

Funding

The authors thank the Swedish Research Council (RegistrationNo. 2019-05366), the Swedish Energy Agency (project 50098-1), the Center for Applied Mathematics (CIM) at UppsalaUniversity, and the Swedish National Strategic e-Scienceprogramme (eSSENCE) for financial support.

FundersFunder number
Uppsala Universitet
Basque Center for Applied Mathematics
Vetenskapsrådet2019-05366
Energimyndigheten50098-1

    Keywords

    • energy materials
    • molecular simulation
    • potential energy surface
    • topology and chemistry
    • dynamics
    • mass transport

    VU Research Profile

    • Science for Sustainability

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