Quantum hardware calculations of the activation and dissociation of nitrogen on iron clusters and surfaces
Abstract
Catalytic processes are vital in the chemical industry, with nitrogen-to-ammonia conversion being a major industrial process. Designing catalysts relies on computational chemistry methods like Density Functional Theory (DFT), which have limitations in accuracy, especially for complex materials. Quantum computing advancements offer promise for precise ab-initio methods. We introduce a hybrid quantum-classical workflow to model chemical reactions on surfaces, demonstrated on nitrogen activation and dissociation on small Fe clusters and an iron surface. We decoupled key electronic structures using CASSCF, translated them into qubits, and estimated energies with quantum and classical simulations, showing potential for quantum computing in catalysis research as technology scales up.
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