English

Modelling Carbon Capture on Metal-Organic Frameworks with Quantum Computing

Quantum Physics 2023-01-18 v2 Materials Science Atomic Physics Chemical Physics Computational Physics

Abstract

Despite the recent progress in quantum computational algorithms for chemistry, there is a dearth of quantum computational simulations focused on material science applications, especially for the energy sector, where next generation sorbing materials are urgently needed to battle climate change. To drive their development, quantum computing is applied to the problem of CO2_2 adsorption in Al-fumarate Metal-Organic Frameworks. Fragmentation strategies based on Density Matrix Embedding Theory are applied, using a variational quantum algorithm as a fragment solver, along with active space selection to minimise qubit number. By investigating different fragmentation strategies and solvers, we propose a methodology to apply quantum computing to Al-fumarate interacting with a CO2_2 molecule, demonstrating the feasibility of treating a complex porous system as a concrete application of quantum computing. Our work paves the way for the use of quantum computing techniques in the quest of sorbents optimisation for more efficient carbon capture and conversion applications.

Keywords

Cite

@article{arxiv.2203.15546,
  title  = {Modelling Carbon Capture on Metal-Organic Frameworks with Quantum Computing},
  author = {Gabriel Greene-Diniz and David Zsolt Manrique and Wassil Sennane and Yann Magnin and Elvira Shishenina and Philippe Cordier and Philip Llewellyn and Michal Krompiec and Marko J. Rančić and David Muñoz Ramo},
  journal= {arXiv preprint arXiv:2203.15546},
  year   = {2023}
}
R2 v1 2026-06-24T10:30:06.569Z