Extended <scp>tight‐binding</scp> quantum chemistry methods

Christoph Bannwarth; Eike Caldeweyher; Sebastian Ehlert; Andreas Hansen; Philipp Pracht; Jakob Seibert; Sebastian Spicher; Stefan Grimme

doi:10.1002/wcms.1493

Abstract

Abstract This review covers a family of atomistic, mostly quantum chemistry (QC) based semiempirical methods for the fast and reasonably accurate description of large molecules in gas and condensed phase. The theory is derived from a density functional (DFT) perturbation expansion of the electron density in fluctuation terms to various orders similar to the original density functional tight binding model. The term “eXtended” in their name (xTB) emphasizes the parameter availability for almost the entire periodic table of elements ( Z ≤ 86) and improvements of the underlying theory regarding, for example, the atomic orbital basis set, the level of multipole approximation and the treatment of the important electrostatic and dispersion interactions. A common feature of most members is their consistent parameterization on accurate gas phase theoretical reference data for geometries, vibrational frequencies and noncovalent interactions, which are the primary properties of interest in typical applications to systems composed of up to a few thousand atoms. Further specialized versions were developed for the description of electronic spectra and corresponding response properties. Besides a provided common theoretical background with some important implementation details in the efficient and free xtb program, various benchmarks for structural and thermochemical properties including (transition‐)metal systems are discussed. The review is completed by recent extensions of the model to the force‐field (FF) level as well as its application to solids under periodic boundary conditions. The general applicability together with the excellent cost‐accuracy ratio and the high robustness make the xTB family of methods very attractive for various fields of computer‐aided chemical research. This article is categorized under: Electronic Structure Theory > Ab Initio Electronic Structure Methods Electronic Structure Theory > Semiempirical Electronic Structure Methods Software > Quantum Chemistry

Keywords

Multipole expansionStatistical physicsPerturbation theory (quantum mechanics)Density functional theoryQuantum chemistryBasis setElectronic structureTight bindingRandom phase approximationPhysicsComputer scienceChemistryQuantum mechanicsChemical physicsComputational chemistryMolecule

Affiliated Institutions

Related Publications

GFN2-xTB—An Accurate and Broadly Parametrized Self-Consistent Tight-Binding Quantum Chemical Method with Multipole Electrostatics and Density-Dependent Dispersion Contributions

Christoph Bannwarth , Sebastian Ehlert , Stefan Grimme

An extended semiempirical tight-binding model is presented, which is primarily designed for the fast calculation of structures and noncovalent interaction energies for molecular...

2019 Journal of Chemical Theory and Comput... 3606 citations

<scp>LOBSTER</scp> : Local orbital projections, atomic charges, and chemical‐bonding analysis from <scp>projector‐augmented‐wave‐based</scp> density‐functional theory

Ryky Nelson , Christina Ertural , Janine George +3 more

Abstract We present an update on recently developed methodology and functionality in the computer program Local Orbital Basis Suite Toward Electronic‐Structure Reconstruction (L...

2020 Journal of Computational Chemistry 1158 citations

Liquid structure of transition metals: investigations using molecular dynamics and perturbation- and integral-equation techniques

Ch. Hausleitner , Gerhard Kahl , J. Häfner

The authors present investigations of the structure of liquid 3d and 4d transition metals using molecular dynamics simulations, thermodynamic perturbation theories, and integral...

1991 Journal of Physics Condensed Matter 61 citations

Effect of exchange and correlation on bulk properties of MgO, NiO, and CoO

Thomas Bredow , Andrea R. Gerson

Bulk properties of the isostructural oxides MgO, NiO, and CoO have been calculated quantum chemically with periodic models and compared with experimental data from the literatur...

2000 Physical review. B, Condensed matter 393 citations

Software update: The <scp>ORCA</scp> program system—Version 5.0

Frank Neese

Abstract Version 5.0 of the ORCA quantum chemistry program suite was released in July 2021. ORCA 5.0 represents a major improvement over all previous versions of ORCA and featur...

2022 Wiley Interdisciplinary Reviews Compu... 3647 citations

Publication Info

Year: 2020
Type: article
Volume: 11
Issue: 2
Citations: 1340
Access: Closed

External Links

View on DOI.org

Social Impact

Altmetric

Extended <scp>tight‐binding</scp> quantum chemistry methods

PlumX Metrics

Social media, news, blog, policy document mentions

Citation Metrics

1340

OpenAlex

Cite This

APA Style

                            
                                
                                    Christoph Bannwarth, 
                                
                                    Eike Caldeweyher, 
                                
                                    Sebastian Ehlert
                                
                                et al.
                            
                            (2020). 
                            Extended <scp>tight‐binding</scp> quantum chemistry methods. 
                            Wiley Interdisciplinary Reviews Computational Molecular Science
                            , 11
                            (2)
                            .
                            https://doi.org/10.1002/wcms.1493
                        

Identifiers

DOI: 10.1002/wcms.1493