Special Issue “50th Anniversary of the Kohn–Sham Theory—Advances in Density Functional Theory”

Abstract: Abstract:The properties of many materials at the atomic scale depend on the electronic structure, which requires a quantum mechanical treatment. The most widely used approach to make such a treatment feasible is density functional theory (DFT), the advances in which were presented and discussed during the DFT conference in Debrecen. Some of these issues are presented in this Special Issue.

“…The accuracy of DFT in investigating the electronic structure of atoms, molecules and condensed phases has been well demonstrated, and it is being widely used today to study the mechanical, electronic, dielectric and thermodynamic properties of metals, inorganic compounds, molecules and polymers. [16][17][18][19][20][21][22] One significant transformation that computational materials science underwent over the last 50 years was the evolution of methods like DFT from being merely post hoc (i.e., being applied to study materials and explain observations post-experiment) to driving rational materials design by eliminating guesswork from experiments. 23 In the literature, many glittering examples can be found of DFT-driven experiments leading to the accelerated design of new materials, such as the identification TS:1 of new cathode materials for Li batteries, 24 the design of novel NiTi shape-memory alloys, 25,26 and the discovery of previously unknown ABX type thermoelectrics and conductors.…”

Rational Design of Polymer Dielectrics: An Application of Density Functional Theory and Machine Learning

“…The accuracy of DFT in investigating the electronic structure of atoms, molecules and condensed phases has been well demonstrated, and it is being widely used today to study the mechanical, electronic, dielectric and thermodynamic properties of metals, inorganic compounds, molecules and polymers. [16][17][18][19][20][21][22] One significant transformation that computational materials science underwent over the last 50 years was the evolution of methods like DFT from being merely post hoc (i.e., being applied to study materials and explain observations post-experiment) to driving rational materials design by eliminating guesswork from experiments. 23 In the literature, many glittering examples can be found of DFT-driven experiments leading to the accelerated design of new materials, such as the identification TS:1 of new cathode materials for Li batteries, 24 the design of novel NiTi shape-memory alloys, 25,26 and the discovery of previously unknown ABX type thermoelectrics and conductors.…”

Rational Design of Polymer Dielectrics: An Application of Density Functional Theory and Machine Learning