10.1021/ja026209p.s001
Dongil Lee
Dongil
Lee
John C. Hutchison
John C.
Hutchison
Anthony M. Leone
Anthony M.
Leone
Joseph M. DeSimone
Joseph M.
DeSimone
Royce W. Murray
Royce W.
Murray
Electron and Mass Transport in Hybrid Redox Polyether Melts
Contacted with Carbon Dioxide
American Chemical Society
2002
CO 2 pressure
electron
D ClO 4
Hybrid Redox Polyether Melts
CO 2
mass transport properties
log
Co
D PHYS
1000 psi causes
Carbon Dioxide Films
diffusion coefficient
k EX
2002-07-13 00:00:00
Journal contribution
https://acs.figshare.com/articles/journal_contribution/Electron_and_Mass_Transport_in_Hybrid_Redox_Polyether_Melts_Contacted_with_Carbon_Dioxide/3643281
Films of neat metal salts with covalently attached oligoether side chains ([Co(bpy(CO<sub>2</sub>MePEG-350)<sub>2</sub>)<sub>3</sub>](ClO<sub>4</sub>)<sub>2</sub>; bpy is 2,2‘-bipyridine, and MePEG-350 is methyl-terminated oligomeric ethylene oxide with
an average molecular weight of 350 Da) undergo marked changes in physical and electrochemical properties
upon contact with CO<sub>2</sub>. Electrochemical measurements indicate that the physical diffusion coefficient (<i>D</i><sub>PHYS</sub>)
of the Co(II) species, the observed rate constant for Co(II/I) self-exchange (<i>k</i><sub>EX</sub>), and the physical diffusion
coefficient of the perchlorate counterion (<i>D</i><sub>ClO4</sub>) increase from 2.4 × 10<sup>-11</sup> to 7.0 × 10<sup>-10</sup> cm<sup>2</sup>/s, 6.8 × 10<sup>5</sup>
to 4.5 × 10<sup>6</sup> M<sup>-1</sup> s<sup>-1</sup>, and 3.4 × 10<sup>-10</sup> to 4.3 × 10<sup>-9</sup> cm<sup>2</sup>/s, respectively, as CO<sub>2</sub> pressure is increased from
0 to 2000 psi at 23 °C. A reduction in activation energy accompanies the enhancement of each of these
properties over this pressure range. Increasing CO<sub>2</sub> pressure from ambient to 1000 psi causes the films to
swell 13%, and free-volume theory explains the enhanced mass transport properties of the films. The origin
of increases in electron-transfer kinetics is considered. Plots of log(<i>k</i><sub>EX</sub>) versus log(<i>D</i><sub>PHYS</sub>) and log(<i>k</i><sub>EX</sub>)
versus log(<i>D</i><sub>ClO4</sub>) are both linear. This suggests that electron self-exchange is controlled by factors that
also affect log(<i>D</i><sub>PHYS</sub>) or log(<i>D</i><sub>ClO4</sub>). One explanation is based on plasticization of the oligoether side-chain
motions by CO<sub>2</sub> that affect ether dipole repolarization and Co complex diffusion rates. A second explanation
for the changes in <i>k</i><sub>EX</sub> is based on control of electron transfer by relaxation of counterions neighbor to the
Co complexes, which is measured by <i>D</i><sub>ClO4</sub>. Both explanations represent a kind of solvent dynamics control
of <i>k</i><sub>EX</sub>.