TY - JOUR
T1 - First-principles calculations for point defects in solids
AU - Freysoldt, Christoph
AU - Grabowski, Blazej
AU - Hickel, Tilmann
AU - Neugebauer, Joerg
AU - Kresse, Georg
AU - Janotti, Anderson
AU - Van de Walle, Chris G.
PY - 2014/3/28
Y1 - 2014/3/28
N2 - Point defects and impurities strongly affect the physical properties of materials and have a decisive impact on their performance in applications. First-principles calculations have emerged as a powerful approach that complements experiments and can serve as a predictive tool in the identification and characterization of defects. The theoretical modeling of point defects in crystalline materials by means of electronic-structure calculations, with an emphasis on approaches based on density functional theory (DFT), is reviewed. A general thermodynamic formalism is laid down to investigate the physical properties of point defects independent of the materials class (semiconductors, insulators, and metals), indicating how the relevant thermodynamic quantities, such as formation energy, entropy, and excess volume, can be obtained from electronic structure calculations. Practical aspects such as the supercell approach and efficient strategies to extrapolate to the isolated-defect or dilute limit are discussed. Recent advances in tractable approximations to the exchange-correlation functional (DFT + U, hybrid functionals) and approaches beyond DFT are highlighted. These advances have largely removed the long-standing uncertainty of defect formation energies in semiconductors and insulators due to the failure of standard DFT to reproduce band gaps. Two case studies illustrate how such calculations provide new insight into the physics and role of point defects in real materials.
AB - Point defects and impurities strongly affect the physical properties of materials and have a decisive impact on their performance in applications. First-principles calculations have emerged as a powerful approach that complements experiments and can serve as a predictive tool in the identification and characterization of defects. The theoretical modeling of point defects in crystalline materials by means of electronic-structure calculations, with an emphasis on approaches based on density functional theory (DFT), is reviewed. A general thermodynamic formalism is laid down to investigate the physical properties of point defects independent of the materials class (semiconductors, insulators, and metals), indicating how the relevant thermodynamic quantities, such as formation energy, entropy, and excess volume, can be obtained from electronic structure calculations. Practical aspects such as the supercell approach and efficient strategies to extrapolate to the isolated-defect or dilute limit are discussed. Recent advances in tractable approximations to the exchange-correlation functional (DFT + U, hybrid functionals) and approaches beyond DFT are highlighted. These advances have largely removed the long-standing uncertainty of defect formation energies in semiconductors and insulators due to the failure of standard DFT to reproduce band gaps. Two case studies illustrate how such calculations provide new insight into the physics and role of point defects in real materials.
KW - DENSITY-FUNCTIONAL THEORY
KW - QUASI-PARTICLE ENERGIES
KW - WAVE BASIS-SET
KW - SCANNING-TUNNELING-MICROSCOPY
KW - PERIODIC BOUNDARY-CONDITIONS
KW - V SEMICONDUCTOR STRUCTURES
KW - LOCAL VIBRATIONAL-MODES
KW - MOLECULAR-BEAM EPITAXY
KW - AB-INITIO CALCULATIONS
KW - WIDE-GAP MATERIALS
UR - http://www.scopus.com/inward/record.url?scp=84899731030&partnerID=8YFLogxK
U2 - 10.1103/RevModPhys.86.253
DO - 10.1103/RevModPhys.86.253
M3 - Article
SN - 0034-6861
VL - 86
SP - 253
EP - 305
JO - Reviews of Modern Physics
JF - Reviews of Modern Physics
IS - 1
M1 - 253
ER -