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Wave-Function-Based Embedding Potential for Ion-Covalent Crystals. / Abarenkov, Igor Vasilievich; Boyko, Maksim Anatolievich.

In: International Journal of Quantum Chemistry, Vol. 116, No. 3, 2016, p. 211-236.

Research output: Contribution to journalLiterature review

Harvard

Abarenkov, IV & Boyko, MA 2016, 'Wave-Function-Based Embedding Potential for Ion-Covalent Crystals', International Journal of Quantum Chemistry, vol. 116, no. 3, pp. 211-236. https://doi.org/10.1002/qua.25041

APA

Abarenkov, I. V., & Boyko, M. A. (2016). Wave-Function-Based Embedding Potential for Ion-Covalent Crystals. International Journal of Quantum Chemistry, 116(3), 211-236. https://doi.org/10.1002/qua.25041

Vancouver

Abarenkov IV, Boyko MA. Wave-Function-Based Embedding Potential for Ion-Covalent Crystals. International Journal of Quantum Chemistry. 2016;116(3):211-236. https://doi.org/10.1002/qua.25041

Author

Abarenkov, Igor Vasilievich ; Boyko, Maksim Anatolievich. / Wave-Function-Based Embedding Potential for Ion-Covalent Crystals. In: International Journal of Quantum Chemistry. 2016 ; Vol. 116, No. 3. pp. 211-236.

BibTeX

@article{5387fbfa4b464425b4c01ec0df5b2851,
title = "Wave-Function-Based Embedding Potential for Ion-Covalent Crystals",
abstract = "Many important properties of crystals are the result of the local defects. However, when one address directly the problem of a crystal with a local defect one must consider a very large system despite the fact that only a small part of it is really essential. This part is responsible for the properties one is interested in. By extracting this part from the crystal one obtains a so-called cluster. At the same time, properties of a single cluster can deviate significantly from properties of the same cluster embedded in crystal. In many cases, a single cluster can even be unstable. To bring the state of the extracted cluster to that of the cluster in the crystal one must apply a so-called embedding potential to the cluster. This article discusses a case study of embedding for ion-covalent crystals. In the case considered, the embedding potential has two qualitatively different components, a long-range (Coulomb), and a short-range. Different methods should be used to generate different components. A number of app",
author = "Abarenkov, {Igor Vasilievich} and Boyko, {Maksim Anatolievich}",
year = "2016",
doi = "10.1002/qua.25041",
language = "English",
volume = "116",
pages = "211--236",
journal = "International Journal of Quantum Chemistry",
issn = "0020-7608",
publisher = "Wiley-Blackwell",
number = "3",

}

RIS

TY - JOUR

T1 - Wave-Function-Based Embedding Potential for Ion-Covalent Crystals

AU - Abarenkov, Igor Vasilievich

AU - Boyko, Maksim Anatolievich

PY - 2016

Y1 - 2016

N2 - Many important properties of crystals are the result of the local defects. However, when one address directly the problem of a crystal with a local defect one must consider a very large system despite the fact that only a small part of it is really essential. This part is responsible for the properties one is interested in. By extracting this part from the crystal one obtains a so-called cluster. At the same time, properties of a single cluster can deviate significantly from properties of the same cluster embedded in crystal. In many cases, a single cluster can even be unstable. To bring the state of the extracted cluster to that of the cluster in the crystal one must apply a so-called embedding potential to the cluster. This article discusses a case study of embedding for ion-covalent crystals. In the case considered, the embedding potential has two qualitatively different components, a long-range (Coulomb), and a short-range. Different methods should be used to generate different components. A number of app

AB - Many important properties of crystals are the result of the local defects. However, when one address directly the problem of a crystal with a local defect one must consider a very large system despite the fact that only a small part of it is really essential. This part is responsible for the properties one is interested in. By extracting this part from the crystal one obtains a so-called cluster. At the same time, properties of a single cluster can deviate significantly from properties of the same cluster embedded in crystal. In many cases, a single cluster can even be unstable. To bring the state of the extracted cluster to that of the cluster in the crystal one must apply a so-called embedding potential to the cluster. This article discusses a case study of embedding for ion-covalent crystals. In the case considered, the embedding potential has two qualitatively different components, a long-range (Coulomb), and a short-range. Different methods should be used to generate different components. A number of app

U2 - 10.1002/qua.25041

DO - 10.1002/qua.25041

M3 - Literature review

VL - 116

SP - 211

EP - 236

JO - International Journal of Quantum Chemistry

JF - International Journal of Quantum Chemistry

SN - 0020-7608

IS - 3

ER -

ID: 7547046