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Auteurs principaux: Carral-Sainz, Nayara, Fernández-Ruiz, Toraya, Íñiguez, Jorge, Junquera, Javier, Garcia-Fernandez, Pablo
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2505.22056
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author Carral-Sainz, Nayara
Fernández-Ruiz, Toraya
Íñiguez, Jorge
Junquera, Javier
Garcia-Fernandez, Pablo
author_facet Carral-Sainz, Nayara
Fernández-Ruiz, Toraya
Íñiguez, Jorge
Junquera, Javier
Garcia-Fernandez, Pablo
contents We present a systematic, quasi-automated methodology for generating electronic models in the framework of second-principles density functional theory (SPDFT). This approach enables the construction of accurate and computationally efficient models by deriving all necessary parameters from first-principles calculations on a carefully designed training set. A key feature of our method is the enforcement of space group symmetries, which reduces both the number of independent parameters and the required computational effort. The formalism includes improved treatments of one-electron Hamiltonians, electron-lattice coupling-through both linear and quadratic terms-and electron-electron interactions, enabling accurate modeling of structural and electronic responses. We apply the methodology to SrTiO$_{3}$ and LiF, materials representative of transition-metal perovskites and wide-band-gap insulators, respectively. In both cases, the resulting models reproduce DFT reference data with high fidelity across various atomic configurations and charge states. Our results validate the robustness of the approach and highlight its potential for simulating complex phenomena such as polarons and excitons. This work lays the foundation for extending SPDFT to real-time simulations of optoelectronic properties and further integration with machine-learning methods.
format Preprint
id arxiv_https___arxiv_org_abs_2505_22056
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Systematic generation of electron models for Second-Principles Density Functional Theory Methods
Carral-Sainz, Nayara
Fernández-Ruiz, Toraya
Íñiguez, Jorge
Junquera, Javier
Garcia-Fernandez, Pablo
Materials Science
Other Condensed Matter
We present a systematic, quasi-automated methodology for generating electronic models in the framework of second-principles density functional theory (SPDFT). This approach enables the construction of accurate and computationally efficient models by deriving all necessary parameters from first-principles calculations on a carefully designed training set. A key feature of our method is the enforcement of space group symmetries, which reduces both the number of independent parameters and the required computational effort. The formalism includes improved treatments of one-electron Hamiltonians, electron-lattice coupling-through both linear and quadratic terms-and electron-electron interactions, enabling accurate modeling of structural and electronic responses. We apply the methodology to SrTiO$_{3}$ and LiF, materials representative of transition-metal perovskites and wide-band-gap insulators, respectively. In both cases, the resulting models reproduce DFT reference data with high fidelity across various atomic configurations and charge states. Our results validate the robustness of the approach and highlight its potential for simulating complex phenomena such as polarons and excitons. This work lays the foundation for extending SPDFT to real-time simulations of optoelectronic properties and further integration with machine-learning methods.
title Systematic generation of electron models for Second-Principles Density Functional Theory Methods
topic Materials Science
Other Condensed Matter
url https://arxiv.org/abs/2505.22056