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The LDA+U has become the method of choice to perform predictive and affordable calculations of the properties of minerals in the Earth's interior. In fact, the ubiquitous presence of transition metals (especially Fe) in several compounds of the mantle and of the core of our planet imposes an accurate description of the effects of electronic correlation. At the same time the investigation of the thermodynamic and mechanical properties of these materials at various and extreme conditions of temperature and pressure requires a method to evaluate energies and energy derivatives with a low computational cost. LDA+U is one of the few approach (if not the only one) to satisfy both these requirements. In this paper I will review the general formulation of this approach, will present some successful paradigmatic applications, and finally will discuss possible developments to improve its accuracy.

Accurate and Efficient Calculations on Strongly Correlated Minerals with the LDA+U Method: Review and Perspectives

Cococcioni, M.
2010-01-01

Abstract

The LDA+U has become the method of choice to perform predictive and affordable calculations of the properties of minerals in the Earth's interior. In fact, the ubiquitous presence of transition metals (especially Fe) in several compounds of the mantle and of the core of our planet imposes an accurate description of the effects of electronic correlation. At the same time the investigation of the thermodynamic and mechanical properties of these materials at various and extreme conditions of temperature and pressure requires a method to evaluate energies and energy derivatives with a low computational cost. LDA+U is one of the few approach (if not the only one) to satisfy both these requirements. In this paper I will review the general formulation of this approach, will present some successful paradigmatic applications, and finally will discuss possible developments to improve its accuracy.
2010
THEORETICAL AND COMPUTATIONAL METHODS IN MINERAL PHYSICS: GEOPHYSICAL APPLICATIONS
Applied Physics/Condensed Matter/Materials Science encompasses the resources of three related disciplines: Applied Physics, Condensed Matter Physics, and Materials Science. The applied physics resources are concerned with the applications of topics in condensed matter as well as optics, vacuum science, lasers, electronics, cryogenics, magnets and magnetism, acoustical physics and mechanics. The condensed matter physics resources are concerned with the study of the structure and the thermal, mechanical, electrical, magnetic and optical properties of condensed matter. They include superconductivity, surfaces, interfaces, thin films, dielectrics, ferroelectrics and semiconductors. The materials science resources are concerned with the physics and chemistry of materials and include ceramics, composites, alloys, metals and metallurgy, nanotechnology, nuclear materials, adhesion and adhesives. Resources dealing with polymeric materials are listed in the Organic Chemistry/Polymer Science category.
WOS:000277362500008
2-s2.0-77956955731
Inglese
Internazionale
ELETTRONICO
71
147
167
21
R. M. Wentzcovitch, L. Stixrude
STATI UNITI D'AMERICA
ELECTRON-TRANSFER REACTIONS; EXTENDED HUBBARD-MODEL; GENERALIZED GRADIENT APPROXIMATION; QUASI-PARTICLE CALCULATIONS; AB-INITIO CALCULATIONS; INFINITE DIMENSIONS; OPTICAL-ABSORPTION; PHASE-DIAGRAM; HIGH-PRESSURE; GROUND-STATE
no
2 Contributo in Volume::2.1 Contributo in volume (Capitolo o Saggio)
1
268
none
Cococcioni, M.
info:eu-repo/semantics/bookPart
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11571/1284066
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