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arxiv: 2403.08107 · v1 · pith:NN5WJFAV · submitted 2024-03-12 · quant-ph · physics.chem-ph· physics.comp-ph

Simulation of a Diels-Alder Reaction on a Quantum Computer

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classification quant-ph physics.chem-phphysics.comp-ph
keywords quantumhardwarereactionactivationalgorithmschemicalreactionsbarriers
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The simulation of chemical reactions is an anticipated application of quantum computers. Using a Diels-Alder reaction as a test case, in this study we explore the potential applications of quantum algorithms and hardware in investigating chemical reactions. Our specific goal is to calculate the activation barrier of a reaction between ethylene and cyclopentadiene forming a transition state. To achieve this goal, we use quantum algorithms for near-term quantum hardware (entanglement forging and quantum subspace expansion) and classical post-processing (many-body perturbation theory) in concert. We conduct simulations on IBM quantum hardware using up to 8 qubits, and compute accurate activation barriers in the reaction between cyclopentadiene and ethylene by accounting for both static and dynamic electronic correlation. This work illustrates a hybrid quantum-classical computational workflow to study chemical reactions on near-term quantum devices, showcasing the potential of quantum algorithms and hardware in accurately calculating activation barriers.

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Cited by 2 Pith papers

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