Abstract
Density functional theory (DFT) is one of the most widely used tools to solve the many-body Schrodinger equation. The core uncertainty inside DFT theory is the exchange-correlation (XC) functional, the exact form of which is still unknown. Therefore, the essential part of DFT success is based on the progress in the development of XC approximations. Traditionally, they are built upon analytic solutions in low- and high-density limits and result from quantum Monte Carlo numerical calculations. However, there is no consistent and general scheme of XC interpolation and functional representation. Many different developed parametrizations mainly utilize a number of phenomenological rules to construct a specific XC functional. In contrast, the neural network (NN) approach can provide a general way to parametrize an XC functional without any a priori knowledge of its functional form. In this work, we develop NN XC functionals and prove their applicability to 3-dimensional physical systems. We show that both the local density approximation (LDA) and generalized gradient approximation (GGA) are well reproduced by the NN approach. It is demonstrated that the local environment can be easily considered by changing only the number of neurons in the first layer of the NN. The developed NN XC functionals show good results when applied to systems that are not presented in the training/test data. The generalizability of the formulated NN XC framework leads us to believe that it could give superior results in comparison with traditional XC schemes provided training data from high-level theories such as the quantum Monte Carlo and post-Hartree-Fock methods.
Highlights
Density functional theory (DFT) is one of the most widely used tools to solve the many-body Schrodinger equation
This study showed that neural network (NN) approach is flexible and principally applicable to generate XC potentials to be used in the real physical systems DFT calculations
We show that the constructed NN XC potentials have the capability to reproduce local density approximation (LDA) and generalized gradient approximation (GGA) results for real physical systems
Summary
Density functional theory (DFT) is one of the most widely used tools to solve the many-body Schrodinger equation. The essential part of DFT success is based on the progress in the development of XC approximations They are built upon analytic solutions in low- and high-density limits and result from quantum Monte Carlo numerical calculations. We develop NN XC functionals and prove their applicability to 3-dimensional physical systems We show that both the local density approximation (LDA) and generalized gradient approximation (GGA) are well reproduced by the NN approach. The major progress was produced by the introduction of the generalized gradient approximation (GGA), which takes into account local gradients of electron density[7,8,9] This greatly enhanced the ability of DFT to describe systems with inhomogeneous electron densities, such as molecules and surfaces. GGA potential region-to-point mapping is achieved by increasing the number of input neurons to take into account the local environment
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