Foundations of the LRESC model for response properties and some applications

Accurate calculations of some response properties, like the NMR spectroscopic parameters, are quite exigent for the theoretical quantum chemistry models together with the computational codes that are written from them. They need to include a very good description of the electronic density in regions...

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Autores principales: Aucar, G.A., Melo, J.I., Aucar, I.A., Maldonado, A.F.
Formato: JOUR
Materias:
g-tensor
NMR
response properties
spin-rotation tensor
two-component methods
Computational chemistry
Magnetic shielding
Molecules
Nuclear magnetic resonance
Quantum chemistry
Relativity
Shielding
Spin dynamics
Tensors
Accurate calculations
G tensors
Relativistic effects
Response properties
Spectroscopic parameters
Spin-rotations
Susceptibility tensors
Two-component methods
Atoms
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_00207608_v118_n1_p_Aucar
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Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_00207608_v118_n1_p_Aucar
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spelling todo:paper_00207608_v118_n1_p_Aucar2023-10-03T14:18:49Z Foundations of the LRESC model for response properties and some applications Aucar, G.A. Melo, J.I. Aucar, I.A. Maldonado, A.F. g-tensor NMR response properties spin-rotation tensor two-component methods Computational chemistry Magnetic shielding Molecules Nuclear magnetic resonance Quantum chemistry Relativity Shielding Spin dynamics Tensors Accurate calculations G tensors Relativistic effects Response properties Spectroscopic parameters Spin-rotations Susceptibility tensors Two-component methods Atoms Accurate calculations of some response properties, like the NMR spectroscopic parameters, are quite exigent for the theoretical quantum chemistry models together with the computational codes that are written from them. They need to include a very good description of the electronic density in regions close to the nuclei. When heavy-atom containing systems are studied, those requirements become even higher. Given that relativistic effects must be included in one way or another on the calculation of response properties of heavy-atoms and heavy-atom containing molecules, different schemes were developed during the past decades to include them in as good as possible way. There are some four-component models, which include relativistic effects in a very compact way, although calculations have large time-consumption; one also needs to deal with new and unusual four-component operators. There are also two-component models, which in general may be less accurate, although their application to property calculations on medium-size and large-size molecules are feasible, and they maintain the application of usual operators. In this review, we give the fundamentals of the two-component linear response elimination of small component formalism, LRESC, together with some applications to few selected response properties. New physical insights do appear when the LRESC model is used to analyze the effect of the environment on magnetic shieldings, and when one search for the relativistic extension of well-known nonrelativistic relationships like Flygare's relation among the NMR magnetic shielding and the nuclear spin-rotation constant. A similar relationship is found for the g-tensor and the susceptibility tensor. © 2017 Wiley Periodicals, Inc. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00207608_v118_n1_p_Aucar
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic g-tensor
NMR
response properties
spin-rotation tensor
two-component methods
Computational chemistry
Magnetic shielding
Molecules
Nuclear magnetic resonance
Quantum chemistry
Relativity
Shielding
Spin dynamics
Tensors
Accurate calculations
G tensors
Relativistic effects
Response properties
Spectroscopic parameters
Spin-rotations
Susceptibility tensors
Two-component methods
Atoms
spellingShingle g-tensor
NMR
response properties
spin-rotation tensor
two-component methods
Computational chemistry
Magnetic shielding
Molecules
Nuclear magnetic resonance
Quantum chemistry
Relativity
Shielding
Spin dynamics
Tensors
Accurate calculations
G tensors
Relativistic effects
Response properties
Spectroscopic parameters
Spin-rotations
Susceptibility tensors
Two-component methods
Atoms
Aucar, G.A.
Melo, J.I.
Aucar, I.A.
Maldonado, A.F.
Foundations of the LRESC model for response properties and some applications
topic_facet g-tensor
NMR
response properties
spin-rotation tensor
two-component methods
Computational chemistry
Magnetic shielding
Molecules
Nuclear magnetic resonance
Quantum chemistry
Relativity
Shielding
Spin dynamics
Tensors
Accurate calculations
G tensors
Relativistic effects
Response properties
Spectroscopic parameters
Spin-rotations
Susceptibility tensors
Two-component methods
Atoms
description Accurate calculations of some response properties, like the NMR spectroscopic parameters, are quite exigent for the theoretical quantum chemistry models together with the computational codes that are written from them. They need to include a very good description of the electronic density in regions close to the nuclei. When heavy-atom containing systems are studied, those requirements become even higher. Given that relativistic effects must be included in one way or another on the calculation of response properties of heavy-atoms and heavy-atom containing molecules, different schemes were developed during the past decades to include them in as good as possible way. There are some four-component models, which include relativistic effects in a very compact way, although calculations have large time-consumption; one also needs to deal with new and unusual four-component operators. There are also two-component models, which in general may be less accurate, although their application to property calculations on medium-size and large-size molecules are feasible, and they maintain the application of usual operators. In this review, we give the fundamentals of the two-component linear response elimination of small component formalism, LRESC, together with some applications to few selected response properties. New physical insights do appear when the LRESC model is used to analyze the effect of the environment on magnetic shieldings, and when one search for the relativistic extension of well-known nonrelativistic relationships like Flygare's relation among the NMR magnetic shielding and the nuclear spin-rotation constant. A similar relationship is found for the g-tensor and the susceptibility tensor. © 2017 Wiley Periodicals, Inc.
format JOUR
author Aucar, G.A.
Melo, J.I.
Aucar, I.A.
Maldonado, A.F.
author_facet Aucar, G.A.
Melo, J.I.
Aucar, I.A.
Maldonado, A.F.
author_sort Aucar, G.A.
title Foundations of the LRESC model for response properties and some applications
title_short Foundations of the LRESC model for response properties and some applications
title_full Foundations of the LRESC model for response properties and some applications
title_fullStr Foundations of the LRESC model for response properties and some applications
title_full_unstemmed Foundations of the LRESC model for response properties and some applications
title_sort foundations of the lresc model for response properties and some applications
url http://hdl.handle.net/20.500.12110/paper_00207608_v118_n1_p_Aucar
work_keys_str_mv AT aucarga foundationsofthelrescmodelforresponsepropertiesandsomeapplications
AT meloji foundationsofthelrescmodelforresponsepropertiesandsomeapplications
AT aucaria foundationsofthelrescmodelforresponsepropertiesandsomeapplications
AT maldonadoaf foundationsofthelrescmodelforresponsepropertiesandsomeapplications
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