Links
Contact Info.
  • Address:重庆市沙坪坝区重庆大学虎溪校区理科楼LC210
  • Zip:401331
  • Tel:02365678934
  • Fax:
  • Email:chxh7@cqu.edu.cn
Current Location :> Home > Publications > Text
Cation-Modulated Electron-Transfer Channel: H-Atom Transfer vs Proton- Coupled Electron Transfer with a Variable Electron-Transfer Channel in Acylamide Units
writer:Xiaohua Chen, Yuxiang Bu*
keywords:Proton- Coupled Electron Transfer
source:期刊
specific source:J. Am. Chem. Soc. 2007, 129 (31), 9713–9720.
Issue time:2007年

The mechanism of proton transfer (PT)/electron transfer (ET) in acylamide units was explored theoretically using density functional theory in a representative model (a cyclic coupling mode between formamide and the N-dehydrogenated formamidic radical, FF). In FF, PT/ET normally occurs via a seven-center cyclic proton-coupled electron transfer (PCET) mechanism with a N→N PT and an O→O ET. However, when different hydrated metal ions are bound to the two oxygen sites of FF, the PT/ET mechanism may significantly change. In addition to their inhibition of PT/ET rate, the hydrated metal ions can effectively regulate the FF PT/ET cooperative mechanism to produce a single pathway hydrogen atom transfer (HAT) or a flexible proton coupled electron transfer (PCET) mechanism by changing the ET channel. The regulation essentially originates from the change in the O···O bond strength in the transition state, subject to the binding ability of the hydrated metal ions. In general, the high valent metal ions and those with large binding energies can promote HAT, and the low valent metal ions and those with small binding energies favor PCET. Hydration may reduce the Lewis acidity of cations, and thus favor PCET. Good correlations among the binding energies, barrier heights, spin density distributions, O···O contacts, and hydrated metal ion properties have been found, which can be used to interpret the transition in the PT/ET mechanism. These findings regarding the modulation of the PT/ET pathway via hydrated metal ions may provide useful information for a greater understanding of PT/ET cooperative mechanisms, and a possible method for switching conductance in nanoelectronic devices.