Comparison of G3 and G4 theories for radical addition and abstraction reactions

Ching Yeh Lin; Jennifer L. Hodgson; Mansoor Namazian; Michelle L. Coote

doi:10.1021/jp900649j

Comparison of G3 and G4 theories for radical addition and abstraction reactions

Ching Yeh Lin, Jennifer L. Hodgson, Mansoor Namazian, Michelle L. Coote

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47 Citations (Scopus)

Abstract

A test set of 21 radical addition and 28 hydrogen abstraction reactions has been studied at the Wl, G4, G3X, G3X(MP2), and G3X(MP2)-RAD levels of theory with a view to establishing whether the recently introduced G4 theory offers improved performance over the G3 methods. All methods tested approximated the benchmark Wl values to within a mean absolute deviation (MAD) of 4 kJ mol ^-1 or less, although maximum absolute deviations for problematic reactions (such as radical addition to thiocarbonyl compounds) can be as much as 10 kJ mol^-1 for the G3 methods. The new noncanceling higher-level correction (HLC) term in G4 was found to be capable of mitigating these errors in radical addition, but it introduced a systematic error to the reaction energies of the abstraction reactions, and its format may therefore require re-examination. G3 methods were shown to offer "chemical accuracy" even for these problematic cases, provided they were corrected to the Wl level of theory via an ONIOM-based approach.

Original language	English
Pages (from-to)	3690-3697
Number of pages	8
Journal	Journal of Physical Chemistry A
Volume	113
Issue number	15
DOIs	https://doi.org/10.1021/jp900649j
Publication status	Published - 16 Apr 2009

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abstract = "A test set of 21 radical addition and 28 hydrogen abstraction reactions has been studied at the Wl, G4, G3X, G3X(MP2), and G3X(MP2)-RAD levels of theory with a view to establishing whether the recently introduced G4 theory offers improved performance over the G3 methods. All methods tested approximated the benchmark Wl values to within a mean absolute deviation (MAD) of 4 kJ mol -1 or less, although maximum absolute deviations for problematic reactions (such as radical addition to thiocarbonyl compounds) can be as much as 10 kJ mol-1 for the G3 methods. The new noncanceling higher-level correction (HLC) term in G4 was found to be capable of mitigating these errors in radical addition, but it introduced a systematic error to the reaction energies of the abstraction reactions, and its format may therefore require re-examination. G3 methods were shown to offer {"}chemical accuracy{"} even for these problematic cases, provided they were corrected to the Wl level of theory via an ONIOM-based approach.",

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AU - Lin, Ching Yeh

AU - Hodgson, Jennifer L.

AU - Namazian, Mansoor

AU - Coote, Michelle L.

PY - 2009/4/16

Y1 - 2009/4/16

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AB - A test set of 21 radical addition and 28 hydrogen abstraction reactions has been studied at the Wl, G4, G3X, G3X(MP2), and G3X(MP2)-RAD levels of theory with a view to establishing whether the recently introduced G4 theory offers improved performance over the G3 methods. All methods tested approximated the benchmark Wl values to within a mean absolute deviation (MAD) of 4 kJ mol -1 or less, although maximum absolute deviations for problematic reactions (such as radical addition to thiocarbonyl compounds) can be as much as 10 kJ mol-1 for the G3 methods. The new noncanceling higher-level correction (HLC) term in G4 was found to be capable of mitigating these errors in radical addition, but it introduced a systematic error to the reaction energies of the abstraction reactions, and its format may therefore require re-examination. G3 methods were shown to offer "chemical accuracy" even for these problematic cases, provided they were corrected to the Wl level of theory via an ONIOM-based approach.

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Comparison of G3 and G4 theories for radical addition and abstraction reactions

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