Platinum-based Catalysts for Oxygen Reduction Reaction simulated with a Quantum Computer
Hydrogen has emerged as a promising energy source, holding the key to achieve low-carbon and sustainable mobility. However, its applications are still limited by modest conversion efficiency in the electrocatalytic oxygen reduction reaction (ORR) within fuel cells. Consequently, the development of n...
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| creator | Di Paola, Cono Plekhanov, Evgeny Krompiec, Michal Kumar, Chandan Marsili, Emanuele Du, Fengmin Weber, Daniel Krauser, Jasper Simon Shishenina, Elvira Ramo, David Muñoz |
| description | Hydrogen has emerged as a promising energy source, holding the key to achieve
low-carbon and sustainable mobility. However, its applications are still
limited by modest conversion efficiency in the electrocatalytic oxygen
reduction reaction (ORR) within fuel cells. Consequently, the development of
novel catalysts and a profound understanding of the underlying reactions have
become of paramount importance. The complex nature of the ORR potential energy
landscape and the presence of strong electronic correlations present challenges
to atomistic modelling using classical computers. This scenario opens new
avenues for the implementation of novel quantum computing workflows to address
these molecular systems. Here, we present a pioneering study that combines
classical and quantum computational approaches to investigate the ORR on pure
platinum and platinum/cobalt surfaces. Our research demonstrates, for the first
time, the feasibility of implementing this workflow on the H1-series
trapped-ion quantum computer and identify the challenges of the quantum
chemistry modelling of this reaction. The results highlight the involvement of
strongly correlated species in the cobalt-containing catalyst, suggesting their
potential as ideal candidates for showcasing quantum advantage in future
applications. |
| doi_str_mv | 10.48550/arxiv.2307.15823 |
| format | Article |
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low-carbon and sustainable mobility. However, its applications are still
limited by modest conversion efficiency in the electrocatalytic oxygen
reduction reaction (ORR) within fuel cells. Consequently, the development of
novel catalysts and a profound understanding of the underlying reactions have
become of paramount importance. The complex nature of the ORR potential energy
landscape and the presence of strong electronic correlations present challenges
to atomistic modelling using classical computers. This scenario opens new
avenues for the implementation of novel quantum computing workflows to address
these molecular systems. Here, we present a pioneering study that combines
classical and quantum computational approaches to investigate the ORR on pure
platinum and platinum/cobalt surfaces. Our research demonstrates, for the first
time, the feasibility of implementing this workflow on the H1-series
trapped-ion quantum computer and identify the challenges of the quantum
chemistry modelling of this reaction. The results highlight the involvement of
strongly correlated species in the cobalt-containing catalyst, suggesting their
potential as ideal candidates for showcasing quantum advantage in future
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low-carbon and sustainable mobility. However, its applications are still
limited by modest conversion efficiency in the electrocatalytic oxygen
reduction reaction (ORR) within fuel cells. Consequently, the development of
novel catalysts and a profound understanding of the underlying reactions have
become of paramount importance. The complex nature of the ORR potential energy
landscape and the presence of strong electronic correlations present challenges
to atomistic modelling using classical computers. This scenario opens new
avenues for the implementation of novel quantum computing workflows to address
these molecular systems. Here, we present a pioneering study that combines
classical and quantum computational approaches to investigate the ORR on pure
platinum and platinum/cobalt surfaces. Our research demonstrates, for the first
time, the feasibility of implementing this workflow on the H1-series
trapped-ion quantum computer and identify the challenges of the quantum
chemistry modelling of this reaction. The results highlight the involvement of
strongly correlated species in the cobalt-containing catalyst, suggesting their
potential as ideal candidates for showcasing quantum advantage in future
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low-carbon and sustainable mobility. However, its applications are still
limited by modest conversion efficiency in the electrocatalytic oxygen
reduction reaction (ORR) within fuel cells. Consequently, the development of
novel catalysts and a profound understanding of the underlying reactions have
become of paramount importance. The complex nature of the ORR potential energy
landscape and the presence of strong electronic correlations present challenges
to atomistic modelling using classical computers. This scenario opens new
avenues for the implementation of novel quantum computing workflows to address
these molecular systems. Here, we present a pioneering study that combines
classical and quantum computational approaches to investigate the ORR on pure
platinum and platinum/cobalt surfaces. Our research demonstrates, for the first
time, the feasibility of implementing this workflow on the H1-series
trapped-ion quantum computer and identify the challenges of the quantum
chemistry modelling of this reaction. The results highlight the involvement of
strongly correlated species in the cobalt-containing catalyst, suggesting their
potential as ideal candidates for showcasing quantum advantage in future
applications.</abstract><doi>10.48550/arxiv.2307.15823</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Chemical Physics Physics - Materials Science Physics - Quantum Physics |
| title | Platinum-based Catalysts for Oxygen Reduction Reaction simulated with a Quantum Computer |
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