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Literature DB >> 24416504

Do Spin State and Spin Density Affect Hydrogen Atom Transfer Reactivity?

Abstract

The prevalence of hydrogen atom transfer (HAT) reactions in chemical and biological systems has prompted much interest in establishing and understanding the underlying factors that enable this reactivity. Arguments have been advanced that the electronic spin state of the abstractor and/or the spin-density at the abstracting atom are critical for HAT reactivity. This is consistent with the intuition derived from introductory organic chemistry courses. Herein we present an alternative view on the role of spin state and spin-density in HAT reactions. After a brief introduction, the second section introduces a new and simple fundamental kinetic analysis, which shows that unpaired spin cannot be the dominant effect. The third section examines published computational studies of HAT reactions, which indicates that the spin state affects these reactions indirectly, primarily via changes in driving force. The essay concludes with a broader view of HAT reactivity, including indirect effects of spin and other properties on reactivity. It is suggested that some of the controversy in this area may arise from the diversity of HAT reactions and their overlap with proton-coupled electron transfer (PCET) reactions.

Entities: Chemical Disease Gene Mutation Species

Year: 2014 PMID： 24416504 PMCID： PMC3885253 DOI： 10.1039/C3SC52664J

Source DB: PubMed Journal: Chem Sci ISSN： 2041-6520 Impact factor: 9.825

68 in total

1. Exchange-enhanced reactivity in bond activation by metal-oxo enzymes and synthetic reagents.

Authors: Sason Shaik; Hui Chen; Deepa Janardanan
Journal: Nat Chem Date: 2010-12-15 Impact factor: 24.427

Review 2. Thermochemistry of proton-coupled electron transfer reagents and its implications.

Authors: Jeffrey J Warren; Tristan A Tronic; James M Mayer
Journal: Chem Rev Date: 2010-10-06 Impact factor: 60.622

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Authors: Sergey V Kryatov; Elena V Rybak-Akimova; Siegfried Schindler
Journal: Chem Rev Date: 2005-06 Impact factor: 60.622

4. Two-state reactivity in alkane hydroxylation by non-heme iron-oxo complexes.

Authors: Hajime Hirao; Devesh Kumar; Lawrence Que; Sason Shaik
Journal: J Am Chem Soc Date: 2006-07-05 Impact factor: 15.419

5. Gas-phase ionic reactions: dynamics and mechanism of nucleophilic displacements

Authors:
Journal: Science Date: 1998-03-20 Impact factor: 47.728

6. Ligand effects on hydrogen atom transfer from hydrocarbons to three-coordinate iron imides.

Authors: Ryan E Cowley; Patrick L Holland
Journal: Inorg Chem Date: 2012-07-16 Impact factor: 5.165

7. Thermal hydrogen-atom transfer from methane: the role of radicals and spin states in oxo-cluster chemistry.

Authors: Nicolas Dietl; Maria Schlangen; Helmut Schwarz
Journal: Angew Chem Int Ed Engl Date: 2012-03-16 Impact factor: 15.336

8. Theoretical study of electron, proton, and proton-coupled electron transfer in iron bi-imidazoline complexes.

Authors: N Iordanova; H Decornez; S Hammes-Schiffer
Journal: J Am Chem Soc Date: 2001-04-25 Impact factor: 15.419

Review 9. Reactivity of high-valent iron-oxo species in enzymes and synthetic reagents: a tale of many states.

Authors: Sason Shaik; Hajime Hirao; Devesh Kumar
Journal: Acc Chem Res Date: 2007-05-09 Impact factor: 22.384

Review 10. High-valent iron in chemical and biological oxidations.

Authors: John T Groves
Journal: J Inorg Biochem Date: 2006-03-03 Impact factor: 4.155

17 in total

1. Radicals and molecular products from the gas-phase pyrolysis of lignin model compounds. Cinnamyl alcohol.

Authors: Lavrent Khachatryan; Meng-Xia Xu; Ang-Jian Wu; Mikhail Pechagin; Rubik Asatryan
Journal: J Anal Appl Pyrolysis Date: 2016-07-09 Impact factor: 5.541

Review 2. Mono- and binuclear non-heme iron chemistry from a theoretical perspective.

Authors: Tibor András Rokob; Jakub Chalupský; Daniel Bím; Prokopis C Andrikopoulos; Martin Srnec; Lubomír Rulíšek
Journal: J Biol Inorg Chem Date: 2016-05-26 Impact factor: 3.358

Review 3. VTST/MT studies of the catalytic mechanism of C-H activation by transition metal complexes with [Cu₂(μ-O₂)], [Fe₂(μ-O₂)] and Fe(IV)-O cores based on DFT potential energy surfaces.

Authors: Yongho Kim; Binh Khanh Mai; Sumin Park
Journal: J Biol Inorg Chem Date: 2017-01-16 Impact factor: 3.358

4. Ferryl protonation in oxoiron(IV) porphyrins and its role in oxygen transfer.

Authors: Nicholas C Boaz; Seth R Bell; John T Groves
Journal: J Am Chem Soc Date: 2015-02-17 Impact factor: 15.419

5. Enzyme-Like Hydroxylation of Aliphatic C-H Bonds From an Isolable Co-Oxo Complex.

Authors: McKenna K Goetz; Joseph E Schneider; Alexander S Filatov; Kate A Jesse; John S Anderson
Journal: J Am Chem Soc Date: 2021-12-02 Impact factor: 15.419

6. Semiempirical method for examining asynchronicity in metal-oxido-mediated C-H bond activation.

Authors: Suman K Barman; Meng-Yin Yang; Trenton H Parsell; Michael T Green; A S Borovik
Journal: Proc Natl Acad Sci U S A Date: 2021-09-07 Impact factor: 11.205

7. Mechanism of Permanganate-Promoted Dihydroxylation of Complex Diketopiperazines: Critical Roles of Counter-cation and Ion-Pairing.

Authors: Brandon E Haines; Brandon M Nelson; Jessica M Grandner; Justin Kim; K N Houk; Mohammad Movassaghi; Djamaladdin G Musaev
Journal: J Am Chem Soc Date: 2018-10-08 Impact factor: 15.419

Do Spin State and Spin Density Affect Hydrogen Atom Transfer Reactivity?

1. Exchange-enhanced reactivity in bond activation by metal-oxo enzymes and synthetic reagents.

Review 2. Thermochemistry of proton-coupled electron transfer reagents and its implications.

Review 3. Kinetics and mechanisms of formation and reactivity of non-heme iron oxygen intermediates.

4. Two-state reactivity in alkane hydroxylation by non-heme iron-oxo complexes.

5. Gas-phase ionic reactions: dynamics and mechanism of nucleophilic displacements

6. Ligand effects on hydrogen atom transfer from hydrocarbons to three-coordinate iron imides.

7. Thermal hydrogen-atom transfer from methane: the role of radicals and spin states in oxo-cluster chemistry.

8. Theoretical study of electron, proton, and proton-coupled electron transfer in iron bi-imidazoline complexes.

Review 9. Reactivity of high-valent iron-oxo species in enzymes and synthetic reagents: a tale of many states.

Review 10. High-valent iron in chemical and biological oxidations.

1. Radicals and molecular products from the gas-phase pyrolysis of lignin model compounds. Cinnamyl alcohol.

Review 2. Mono- and binuclear non-heme iron chemistry from a theoretical perspective.

Review 3. VTST/MT studies of the catalytic mechanism of C-H activation by transition metal complexes with [Cu₂(μ-O₂)], [Fe₂(μ-O₂)] and Fe(IV)-O cores based on DFT potential energy surfaces.

4. Ferryl protonation in oxoiron(IV) porphyrins and its role in oxygen transfer.

5. Enzyme-Like Hydroxylation of Aliphatic C-H Bonds From an Isolable Co-Oxo Complex.

6. Semiempirical method for examining asynchronicity in metal-oxido-mediated C-H bond activation.

7. Mechanism of Permanganate-Promoted Dihydroxylation of Complex Diketopiperazines: Critical Roles of Counter-cation and Ion-Pairing.

8. Toward the synthesis of more reactive S = 2 non-heme oxoiron(IV) complexes.

9. Statistical analysis of C-H activation by oxo complexes supports diverse thermodynamic control over reactivity.

10. Activation of a high-valent manganese-oxo complex by a nonmetallic Lewis acid.

Review 2. Thermochemistry of proton-coupled electron transfer reagents and its implications.

Review 3. Kinetics and mechanisms of formation and reactivity of non-heme iron oxygen intermediates.

Review 9. Reactivity of high-valent iron-oxo species in enzymes and synthetic reagents: a tale of many states.

Review 10. High-valent iron in chemical and biological oxidations.

Review 2. Mono- and binuclear non-heme iron chemistry from a theoretical perspective.

Review 3. VTST/MT studies of the catalytic mechanism of C-H activation by transition metal complexes with [Cu2(μ-O2)], [Fe2(μ-O2)] and Fe(IV)-O cores based on DFT potential energy surfaces.

Review 3. VTST/MT studies of the catalytic mechanism of C-H activation by transition metal complexes with [Cu₂(μ-O₂)], [Fe₂(μ-O₂)] and Fe(IV)-O cores based on DFT potential energy surfaces.