A charge-density machine-learning workflow for computing the infrared spectrum of molecules

• URL: http://arxiv.org/abs/2507.16565v1
• Date: Tue, 22 Jul 2025 13:18:04 GMT
• Title: A charge-density machine-learning workflow for computing the infrared spectrum of molecules
• Authors: Suman Hazra, Urvesh Patil, Stefano Sanvito,
• Abstract summary: We present a machine-learning workflow for the calculation of the infrared spectrum of molecules.<n>We use the Jacobi-Legendre cluster expansion to predict the real-space charge density of a converged density-functional-theory calculation.<n>The scheme is implemented here within the numerical framework of the PySCF code and applied to the infrared spectrum of the uracil molecule in the gas phase.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: We present a machine-learning workflow for the calculation of the infrared spectrum of molecules, and more generally of other temperature-dependent electronic observables. The main idea is to use the Jacobi-Legendre cluster expansion to predict the real-space charge density of a converged density-functional-theory calculation. This gives us access to both energy and forces, and to electronic observables such as the dipole moment or the electronic gap. Thus, the same model can simultaneously drive a molecular dynamics simulation and evaluate electronic quantities along the trajectory, namely it has access to the same information of ab-initio molecular dynamics. A similar approach within the framework of machine-learning force fields would require the training of multiple models, one for the molecular dynamics and others for predicting the electronic quantities. The scheme is implemented here within the numerical framework of the PySCF code and applied to the infrared spectrum of the uracil molecule in the gas phase.

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