Using inherent radical stabilization energies to predict unknown enthalpies of formation and associated bond dissociation energies of complex molecules

Michelle L. Coote; Andreas A. Zavitsas

doi:10.1016/j.tet.2016.03.015

Using inherent radical stabilization energies to predict unknown enthalpies of formation and associated bond dissociation energies of complex molecules

Michelle L. Coote, Andreas A. Zavitsas^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Many free radical reactions are used currently for syntheses not easily accomplished by other methods. Hence, there is an increasing need for information about bond dissociation energies and enthalpies of formation of the molecules and radicals than is currently available for the more complex species involved in such reactions. We provide 98 standard enthalpies of formation that are not available in the extensive NIST database (number 69), 127 bond dissociation energies not experimentally available, and many previously unknown or uncertain enthalpies of formation of radicals, all at 298 K. A method is presented that allows one to obtain good predictions of the thermodynamic properties of new species using the inherent radical stabilities of their components. The information should be useful for designing and rationalizing synthetic radical reactions.

Original language	English
Pages (from-to)	7749-7756
Number of pages	8
Journal	Tetrahedron
Volume	72
Issue number	48
DOIs	https://doi.org/10.1016/j.tet.2016.03.015
Publication status	Published - 2016

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title = "Using inherent radical stabilization energies to predict unknown enthalpies of formation and associated bond dissociation energies of complex molecules",

abstract = "Many free radical reactions are used currently for syntheses not easily accomplished by other methods. Hence, there is an increasing need for information about bond dissociation energies and enthalpies of formation of the molecules and radicals than is currently available for the more complex species involved in such reactions. We provide 98 standard enthalpies of formation that are not available in the extensive NIST database (number 69), 127 bond dissociation energies not experimentally available, and many previously unknown or uncertain enthalpies of formation of radicals, all at 298 K. A method is presented that allows one to obtain good predictions of the thermodynamic properties of new species using the inherent radical stabilities of their components. The information should be useful for designing and rationalizing synthetic radical reactions.",

keywords = "Bond dissociation energies, Enthalpies of formation, Inherent radical stabilities, Radical electronegativities",

author = "Coote, {Michelle L.} and Zavitsas, {Andreas A.}",

note = "Publisher Copyright: {\textcopyright} 2016 Elsevier Ltd",

year = "2016",

doi = "10.1016/j.tet.2016.03.015",

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T1 - Using inherent radical stabilization energies to predict unknown enthalpies of formation and associated bond dissociation energies of complex molecules

AU - Coote, Michelle L.

AU - Zavitsas, Andreas A.

PY - 2016

Y1 - 2016

N2 - Many free radical reactions are used currently for syntheses not easily accomplished by other methods. Hence, there is an increasing need for information about bond dissociation energies and enthalpies of formation of the molecules and radicals than is currently available for the more complex species involved in such reactions. We provide 98 standard enthalpies of formation that are not available in the extensive NIST database (number 69), 127 bond dissociation energies not experimentally available, and many previously unknown or uncertain enthalpies of formation of radicals, all at 298 K. A method is presented that allows one to obtain good predictions of the thermodynamic properties of new species using the inherent radical stabilities of their components. The information should be useful for designing and rationalizing synthetic radical reactions.

AB - Many free radical reactions are used currently for syntheses not easily accomplished by other methods. Hence, there is an increasing need for information about bond dissociation energies and enthalpies of formation of the molecules and radicals than is currently available for the more complex species involved in such reactions. We provide 98 standard enthalpies of formation that are not available in the extensive NIST database (number 69), 127 bond dissociation energies not experimentally available, and many previously unknown or uncertain enthalpies of formation of radicals, all at 298 K. A method is presented that allows one to obtain good predictions of the thermodynamic properties of new species using the inherent radical stabilities of their components. The information should be useful for designing and rationalizing synthetic radical reactions.

KW - Bond dissociation energies

KW - Enthalpies of formation

KW - Inherent radical stabilities

KW - Radical electronegativities

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DO - 10.1016/j.tet.2016.03.015

M3 - Article

SN - 0040-4020

VL - 72

SP - 7749

EP - 7756

JO - Tetrahedron

JF - Tetrahedron

IS - 48

ER -

Using inherent radical stabilization energies to predict unknown enthalpies of formation and associated bond dissociation energies of complex molecules

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