Theoretical Toolkits for Inorganic and Bioinorganic Complexes: Their Applications and Insights

D. Danovich; S. Shaik; H. Chen

doi:10.1016/B978-0-08-097774-4.00901-3

Theoretical Toolkits for Inorganic and Bioinorganic Complexes: Their Applications and Insights

D. Danovich^*, S. Shaik, H. Chen

^*Corresponding author for this work

Institute of Chemistry

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

7 Scopus citations

Abstract

Following Coulson's dictum, 'give us insight, not numbers,' we review in this chapter the theoretical methods that are currently available for studies of structure, spectroscopy, and reactivity of transition-metal complexes in inorganic/organic and bioinorganic chemistry, and the means of extracting insight from these calculations. As such, we describe herein methodologies of density functional theory (DFT), wave function theory, hybrid quantum mechanical/molecular mechanical approaches, and relativistic calculations. We appraise the weaknesses and strengths of these methods and provide wherever possible practical advice for conducting the calculations meaningfully. In addition, we highlight the essential use of orbitals in DFT - natural orbitals, natural spin orbitals, and corresponding orbitals - as the means for understanding the electronic reorganization in complex bioinorganic reactions. Lastly, we review the use of valence bond (VB) theory in modeling reactivity and of 'VB reading' of complex multireference/multiconfigurational wave functions.

Original language	English
Title of host publication	Theory and Methods
Publisher	Elsevier Ltd.
Pages	1-57
Number of pages	57
Volume	9
ISBN (Print)	9780080965291
DOIs	https://doi.org/10.1016/B978-0-08-097774-4.00901-3
State	Published - Aug 2013

Keywords

Bioinorganic chemistry
Bond activation
CASPT2
CASSCF
Catalysis
Configuration interaction
Corresponding orbitals
Coupled cluster theory
Cytochrome P450
DFT
Electron correlation
Exchange
Exchange correlation
H-abstraction
Multiconfiguration calculations
Multireference calculations
Natural orbitals
Nonheme complexes
Perturbation theory
QM/MM
Relativistic effect
Spectroscopy
Spin natural orbitals
Sulfur oxidation
Transition-metal complexes
Valence bond
VBCMD
VBSCD
WFT

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title = "Theoretical Toolkits for Inorganic and Bioinorganic Complexes: Their Applications and Insights",

abstract = "Following Coulson's dictum, 'give us insight, not numbers,' we review in this chapter the theoretical methods that are currently available for studies of structure, spectroscopy, and reactivity of transition-metal complexes in inorganic/organic and bioinorganic chemistry, and the means of extracting insight from these calculations. As such, we describe herein methodologies of density functional theory (DFT), wave function theory, hybrid quantum mechanical/molecular mechanical approaches, and relativistic calculations. We appraise the weaknesses and strengths of these methods and provide wherever possible practical advice for conducting the calculations meaningfully. In addition, we highlight the essential use of orbitals in DFT - natural orbitals, natural spin orbitals, and corresponding orbitals - as the means for understanding the electronic reorganization in complex bioinorganic reactions. Lastly, we review the use of valence bond (VB) theory in modeling reactivity and of 'VB reading' of complex multireference/multiconfigurational wave functions.",

keywords = "Bioinorganic chemistry, Bond activation, CASPT2, CASSCF, Catalysis, Configuration interaction, Corresponding orbitals, Coupled cluster theory, Cytochrome P450, DFT, Electron correlation, Exchange, Exchange correlation, H-abstraction, Multiconfiguration calculations, Multireference calculations, Natural orbitals, Nonheme complexes, Perturbation theory, QM/MM, Relativistic effect, Spectroscopy, Spin natural orbitals, Sulfur oxidation, Transition-metal complexes, Valence bond, VBCMD, VBSCD, WFT",

author = "D. Danovich and S. Shaik and H. Chen",

year = "2013",

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doi = "10.1016/B978-0-08-097774-4.00901-3",

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AU - Shaik, S.

AU - Chen, H.

PY - 2013/8

Y1 - 2013/8

N2 - Following Coulson's dictum, 'give us insight, not numbers,' we review in this chapter the theoretical methods that are currently available for studies of structure, spectroscopy, and reactivity of transition-metal complexes in inorganic/organic and bioinorganic chemistry, and the means of extracting insight from these calculations. As such, we describe herein methodologies of density functional theory (DFT), wave function theory, hybrid quantum mechanical/molecular mechanical approaches, and relativistic calculations. We appraise the weaknesses and strengths of these methods and provide wherever possible practical advice for conducting the calculations meaningfully. In addition, we highlight the essential use of orbitals in DFT - natural orbitals, natural spin orbitals, and corresponding orbitals - as the means for understanding the electronic reorganization in complex bioinorganic reactions. Lastly, we review the use of valence bond (VB) theory in modeling reactivity and of 'VB reading' of complex multireference/multiconfigurational wave functions.

AB - Following Coulson's dictum, 'give us insight, not numbers,' we review in this chapter the theoretical methods that are currently available for studies of structure, spectroscopy, and reactivity of transition-metal complexes in inorganic/organic and bioinorganic chemistry, and the means of extracting insight from these calculations. As such, we describe herein methodologies of density functional theory (DFT), wave function theory, hybrid quantum mechanical/molecular mechanical approaches, and relativistic calculations. We appraise the weaknesses and strengths of these methods and provide wherever possible practical advice for conducting the calculations meaningfully. In addition, we highlight the essential use of orbitals in DFT - natural orbitals, natural spin orbitals, and corresponding orbitals - as the means for understanding the electronic reorganization in complex bioinorganic reactions. Lastly, we review the use of valence bond (VB) theory in modeling reactivity and of 'VB reading' of complex multireference/multiconfigurational wave functions.

KW - Bioinorganic chemistry

KW - Bond activation

KW - CASPT2

KW - CASSCF

KW - Catalysis

KW - Configuration interaction

KW - Corresponding orbitals

KW - Coupled cluster theory

KW - Cytochrome P450

KW - DFT

KW - Electron correlation

KW - Exchange

KW - Exchange correlation

KW - H-abstraction

KW - Multiconfiguration calculations

KW - Multireference calculations

KW - Natural orbitals

KW - Nonheme complexes

KW - Perturbation theory

KW - QM/MM

KW - Relativistic effect

KW - Spectroscopy

KW - Spin natural orbitals

KW - Sulfur oxidation

KW - Transition-metal complexes

KW - Valence bond

KW - VBCMD

KW - VBSCD

KW - WFT

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PB - Elsevier Ltd.

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Theoretical Toolkits for Inorganic and Bioinorganic Complexes: Their Applications and Insights

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Keywords

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