:orphan: .. status publishable .. product VASP .. sectionauthor Gerhard .. SME Walter .. PR Gerhard .. TW Kathy .. date 2024 .. _vasp6DTS: |medea| |mvasp6| Access the World’s Leading First-Principles DFT Code --------------------------------------------------------------------- .. admonition:: **At-a-Glance** |medea|\ :sup:`®`\ [#TM]_ *VASP 6* provides industrial strength, efficient, cutting edge access to |vasp|, the world's leading first-principles DFT code. Integrated in the |medea| atomistic simulation environment, with comprehensive structural databases, model building tools, and fully automated property modules, |medea| |mvasp| *6* has an easy to use graphical user interface, access to automation and large-scale high-throughput capabilities, efficient property calculation, and interactive analysis. **Key Benefits** * High accuracy, high performance first-principles methods and properties * Access to the latest DFT methods and developments (and beyond) * Efficient selection of parameters, thorough validation, and testing * Efficient management of all calculation parameters and data * Licensing model maximizes exploitation of computational resources |mvasp| *6* is the world’s leading first-principles solid state electronic structure program for solids, surfaces, and interfaces [#Hafner]_. Possessing a comprehensive array of advanced features, including hybrid functionals [#Marsman]_ and metaGGAs, the ability to incorporate dispersion interactions, and comprehensive and validated self-consistent PAW potentials, |medea| |mvasp| *6* provides access to state of the art first-principles simulation methods in a comprehensive and easy to use package. Advanced features include linear response calculations for properties such as Born effective charges, dielectric and piezoelectric tensors and NMR chemical shifts. In terms of accuracy |mvasp| *6* advances far beyond capabilities of semi-local and non-local functionals based on the unique, highly precise treatment of electronic correlation in the framework of the so-called ACFDT-RPA approach [#Harl]_. Outstanding results can be obtained even for systems where other ab initio approaches are known to fail. On the other hand, typical limitations of ab initio methods in terms of length and time scales are overcome by means of on-the-fly machine-learning of forcefields (MLFF) [#Jinnouchi]_ during ab initio molecular dynamics, thus enabling unprecedented long dynamics runs on rather large systems. The obtained forcefields can be applied for many other simulations, such as structure optimizations, phonons, elastic properties etc.. |medea| |mvasp| *6* is fully integrated in the |medea| |menvironment| with graphical user interface driven model construction, efficient calculation execution, and analysis capabilities. .. figure:: /Datasheets/images/VASPvsOtherDFT_GoogleScholar2025.png :width: 3.2in :myquote:`VASP is by far the most widely used ab-initio code applicable to solids and surfaces. This can easily be verified by an internet search.` Properties from |medea| |mvasp6| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |medea| |mvasp| *6* enables the efficient computation of the following properties: * Total electronic energy of any 3D periodic arrangement of atoms, formation energy * Forces on atoms, pressure, and stress tensors * Collinear and non-collinear magnetic moments (optionally constrain total moment or atomic spin vectors) * Equilibrium lattice parameters and atomic positions as obtained from energy, force, and stress minimization, selective lattice parameter and atom position optimization * Ab-initio molecular dynamics: nVE, nVT, npT, npH ensembles, simulated annealing, lattice constraints, averages, uncertainties, and trajectories * Energy band structure: atom and orbital momentum projected bands display (so-called fat bands), accurate band gaps, dopant levels, and band offsets based on hybrid functionals, and GW methods * Total and partial (atom, orbital momentum and magnetic quantum number projected) electronic density of states * Electronic charge and spin density, electrostatic potential, and Bader charge analysis * Work functions * Response functions including dielectric and piezoelectric tensors * Born effective charges and :math:`\Gamma`-point phonon modes * Optical spectra: dielectric function and conductivity, reflectivity, refractive index, transmission, absorption, attenuation and extinction coefficients as well as emissivity as a function of frequency, total emissivity vs. temperature, color spaces for D65 and FL2 spectral distributions of illuminants (CIELAB) * Hyperfine splitting * Electric field gradients and quadrupolar coupling constants * NMR chemical shifts * Solvation effects for surfaces and molecules * External electrostatic field effects .. figure:: /Datasheets/images/VASP5.4_Figure1.jpg :width: 3.2in Computational Characteristics ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ * Plane-wave based electronic structure method for periodic structures * All-electron method with projector augmented wave (PAW) potentials for all elements from H to Cm, including a set for highly accurate excited states * Scalar- and fully-relativistic, spin-orbit coupling * Density functional theory (DFT) with local (LDA) and gradient- corrected (GGA) semi-local functionals: AM05, PBEsol, PBE, revPBE, rPBE, BLYP, etc. * Hybrid functionals: HSE06, HSE03, PBE0, RSHXLDA, RSHXPBE, B3LYP, SCAN0, and dielectric-dependent hybrid functionals with the mixing parameter for non-local exchange being determined from the dielectric function. In addition, screened exchange and Hartree-Fock * Meta-GGA functionals: revTPSS, TPSS, SCAN, rSCAN, r \ :sup:`2`\ SCAN, SCAN-L, rSCAN-L, r \ :sup:`2`\ SCAN-L, v1-sregTM, v2-sregTM, v3-sregTM, v2-sregTM-L, OFR2, MS2, MS1, MS0, M06-L, modified Becke-Johnson LDA and its local variant * A variety of Van-der-Waals functionals: optB86b-vdW, optB88-vdW, optPBE-vdW, BEEF-vdW, rev-vdW-DF2, rPW86-vdW2, revPBE-vdW, vdW-DF-cx, rVV10, SCAN + rVV10, r \ :sup:`2`\ SCAN + rVV10, PBE + rVV10L * DFT-D2/D3 (Grimme), DFT-dDsC, DFT-ulg, many-body dispersion energy, and Tkatchenko-Scheffler force-field based correction for van-der-Waals and dispersion forces and energies * Optical response functions from DFT, hybrid functionals, GW, or the time evolution algorithm * Electron-hole interactions (excitonic effects) from time-dependent hybrid functionals or solving the Bethe-Salpeter equation on top of GW [#Paier]_ * Accurate total energy, forces, and zone center phonon modes from adiabatic connection fluctuation dissipation theorem and the random phase approximation (ACFDT-RPA), automatic optimization of atom positions based on ACFDT-RPA * Space-time algorithm for cumputing the polarizability for GW and ACFDT-RPA [#Liu]_, which scales mostly cubic rather than quartic with system size, thus enabling simulations for much larger systems * Accurate total energy from Moeller-Plesset perturbation theory * Density functional perturbation theory, linear response * Electron-phonon coupling from stochastic displacement sampling (single configuration or Monte Carlo sampling) * On-the-fly machine-learning based on Bayesian error prediction during molecular dynamics simulations Required Modules ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ * |medea| |menvironment| * |medea| |mvasp6| Tightly Integrated Modules ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * |medea| |mphonon| * |medea| |electronics| (Fermi surface and transport) * |medea| |mtfull| * |medea| |transitionstatesearch| * |medea| |munclefull| * |medea| |ffo| To accelerate calculations, |medea| |mvasp6| uses intermediate results to improve the efficiency of subsequent steps. The |medea| |mjobservertaskserver| architecture provides efficient storage and deployment for temporary files, and lets you focus on the science while computational bookkeeping and data storage is handled by the |medea| infrastructure. |medea| manages computational details, such as matching k-meshes and setting reasonable |vasp| parameters, automatically. .. figure:: /Datasheets/images/VASP5.4_Figure2.jpg :width: 3.2in Tested, Validated, and Optimized for High-throughput ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Materials Design supports a wide array of hardware configurations with optimized and validated |vasp| executables. Windows and Linux versions allow you to mix and match architectures, so you can run more calculations, and with larger models, on Linux clusters. You can be confident that the results will be consistent with calculations executed on your laptop or desktop machines. The |medea| |menvironment| enables both investigative and high-throughput calculations, and the Materials Design licensing model allows you to maximize parallel execution. You can exploit the growing availability of high performance compute resources, and rapidly obtain state of the art research results. |vasp| executables supporting GPUs are available. Find Out More ^^^^^^^^^^^^^^^ Watch the Webinar: |vaspwebinar| and the online video tutorial: |youtube04.01|. Learn how |medea| |mvasp| can be employed by visiting the |appnotewixpage| page of our website. Examples of |medea| |mvasp| are in the following application notes: * Adsorption and Dissociation of Iodine Molecules on a Zr Surface * Acidity of Amorphous Silica-Alumina Catalysts * Stability of Alkaline-Earth Hydrides * Graphite Electrode Elastic Properties upon Li Intercalation * Atomic Structure of Hydrodesulfurization (HDS) Catalysts * Embrittlement of Cu Micro-Structures * Diffusion of Hydrogen in Nickel * Energy of Dissociative Chemisorption of SiH4 on Si (001) Surface .. add for a column break, adjust where needed .. raw:: latex \newpage * Structure of an iron oxide (Fe2O3) surface, as function of temperature and O2 pressure * Low-Strain Cathode Materials for Solid-State Li-Ion Batteries * Surface Magnetism of Fe(001) * Prediction of Schottky Barrier in Electronic Devices * Catalysts activity computational screening * Thermoelectric Properties of Bi2Te3 as calculated using |medea| |electronics| * Accurate Band Gaps of Correlated Transition-Metal Oxides from Hybrid-Functional Calculations * Temperature-Dependent Phase Transitions of ZrO2 .. [#TM] |regTMinfo| .. [#Hafner] J. Hafner, *J. Comput. Chem.* **29**, 2044 (2008) (`DOI `__) .. full author list: M. Marsman, J. Paier, A. Stroppa, and G. Kresse .. [#Marsman] M. Marsman *et al.*, *J. Phys.: Condens. Matter* **20**, 064201 (2008) (`DOI `__) .. full author list: J. Harl and G. Kresse .. [#Harl] J. Harl *et al.*, *Phys. Rev. Lett.* **103**, 056401 (2009) (`DOI `__) .. full author list: R. Jinnouchi, J. Lahnsteiner, F. Karsai, G. Kresse, and M. Bokdam .. [#Jinnouchi] R. Jinnouchi *et al.*, *Phys. Rev. Lett.* **122**, 225701 (2019) (`DOI `__); R. Jinnouchi *et al.*, *Phys. Rev. B* **100**, 014105 (2019) (`DOI `__) .. full author list: J. Paier, M. Marsman, and G. Kresse .. [#Paier] J. Paier *et al.*, *Phys. Rev. B* **78**, 121201 (2008) (`DOI `__) .. full author list: P. Liu, M. Kaltak, J. Klimes, and G. Kresse .. [#Liu] P. Liu *et al.*, *Phys. Rev. B* **94**, 165109 (2016) (`DOI `__) .. only:: html :download: :download:`pdf `