Atomistic modeling of functionalized magnetite surfaces with oxidation states

Understanding the atomic structure of magnetite-carboxylic acid interfaces is crucial for tailoring nanocomposites involving this interface. We present a Monte Carlo (MC)-based method utilizing iron oxidation state exchange to model magnetite interfaces with tens of thousands of atoms, scales typically inaccessible by electronic structure calculations. Charge neutrality is ensured by the oxidation of Fe ions. The MC approach allows magnetite to adapt to its environment at interfaces without requiring interface-specific rescaling of force-field parameters. This enables a simple, versatile method. By comparing adsorption sites, layer distances, and bond lengths with results from electronic structure calculations and experiments, we validated the accuracy of our method. We found that the oxidation state distribution and, consequently, binding site preference depend on coverage and surface thickness, with a critical thickness signaling the transition from layered to bulk-like oxidation states. The method ensures seamless compatibility with popular biomolecular force fields providing transferability and simplifying the study of magnetite interfaces in general.

DDC Class

539: Matter; Molecular Physics; Atomic and Nuclear physics; Radiation; Quantum Physics

541: Physical; Theoretical

620.1: Engineering Mechanics and Materials Science

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https://creativecommons.org/licenses/by/4.0/

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gürsoy-et-al-2025-atomistic-modeling-of-functionalized-magnetite-surfaces-with-oxidation-states.pdf

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Atomistic modeling of functionalized magnetite surfaces with oxidation states