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Various solvents, using Roduner’s 2005 demonstration that the solvation of H?is energetically roughly equal to that of H2.50 As described in Section 3.1 above, use of this T0901317 site approximation has led to revision of the H+/H?reduction potentials in different solvents. The H?H- reduction potentials in water362 and in DMSO and MeCN363 have been reported, allowing the pKa of H2 to be estimated by eq 22. H2 is very weakly acidic, though significantly more acidic than methane. Recently Kelly has proposed new values for pKa(H2) and E?H?-), some of which are very different from the values that have long been used.(22)NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript5.9 Separate Proton and Electron Donors/Acceptors This review primarily deals with PCET reagents, that is individual chemical compounds that can donate or accept proton(s) and electron(s). From a Z-DEVD-FMK web thermodynamic perspective, this is equivalent to two reagents, one of which accepts or donates proton(s) and the other of which accepts or donates electrons. For instance, ferrocene-carboxylic acid is a single PCET reagent that can donate e- + H+ (H? to give the zwitterionic ferrocene carboxylate, with an effective BDFE of 68 kcal mol-1 in 80/20 MeCN/H2O solvent [assuming that CG(MeCN) CG(MeCN/H2O)].365 Similarly, the combination of ferrocene and benzoic acid can donate e- + H+. One can even define a formal BDFE for the Cp2Fe + benzoic acid combination in MeCN, 83.3 kcal mol-1, using the same eq 7 as used above for a single PCET reagent. The thermodynamic calculation is independent of whether the proton and electron come from a single reagent or two reagents. The most famous example of a separate outer-sphere oxidant and a base accomplishing a PCET reaction is the oxidation of tyrosine Z in photosystem II, in which the proton is transferred from tyrosine Z to a nearby histidine while the electron is transferred to the chlorophyll radical cation P680+?about 14 ?away.108 The use of a “BDFE” for two separated reagents is perhaps a bit peculiar, because there is no X bond that is being homolytically cleaved. It is, however, a very useful way to characterize the thermochemistry of a PCET system, and it emphasizes the thermodynamic equivalence of H+/e- acceptors and H?acceptors [H+/e- donors and H?donors]. The literature for water oxidation, for example, typically quantifies the free energy required as a minimum redox potential of E?= 1.23 V (pH 0). However, this puts emphasis on the electron, while the thermochemistry depends equally on the e- and the H+. What is needed to convert H2O to O2 is a PCET reagent or PCET system with an average BDFE of 86 kcal mol-1 (eq 18, described above). This free energy can be obtained with a single PCET reagent or with a combination of an oxidant and a base. The required free energy can be obtained with a strong oxidant plus a weak base, or a weak oxidant plus a strong base. WhileChem Rev. Author manuscript; available in PMC 2011 December 8.Warren et al.Pagethis area has not received the same detailed study as traditional H-atom transfer reactions, we believe that it is a very important and versatile approach to PCET, and will prove to be widely used in biology and valuable in the development of new chemical processes. A huge number of possibilities are possible for oxidant/base combinations (H?acceptors) and reductant/acid combinations (H?donors). This is because there are many one-electron redox reagents and a huge number of possible acid.Various solvents, using Roduner’s 2005 demonstration that the solvation of H?is energetically roughly equal to that of H2.50 As described in Section 3.1 above, use of this approximation has led to revision of the H+/H?reduction potentials in different solvents. The H?H- reduction potentials in water362 and in DMSO and MeCN363 have been reported, allowing the pKa of H2 to be estimated by eq 22. H2 is very weakly acidic, though significantly more acidic than methane. Recently Kelly has proposed new values for pKa(H2) and E?H?-), some of which are very different from the values that have long been used.(22)NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript5.9 Separate Proton and Electron Donors/Acceptors This review primarily deals with PCET reagents, that is individual chemical compounds that can donate or accept proton(s) and electron(s). From a thermodynamic perspective, this is equivalent to two reagents, one of which accepts or donates proton(s) and the other of which accepts or donates electrons. For instance, ferrocene-carboxylic acid is a single PCET reagent that can donate e- + H+ (H? to give the zwitterionic ferrocene carboxylate, with an effective BDFE of 68 kcal mol-1 in 80/20 MeCN/H2O solvent [assuming that CG(MeCN) CG(MeCN/H2O)].365 Similarly, the combination of ferrocene and benzoic acid can donate e- + H+. One can even define a formal BDFE for the Cp2Fe + benzoic acid combination in MeCN, 83.3 kcal mol-1, using the same eq 7 as used above for a single PCET reagent. The thermodynamic calculation is independent of whether the proton and electron come from a single reagent or two reagents. The most famous example of a separate outer-sphere oxidant and a base accomplishing a PCET reaction is the oxidation of tyrosine Z in photosystem II, in which the proton is transferred from tyrosine Z to a nearby histidine while the electron is transferred to the chlorophyll radical cation P680+?about 14 ?away.108 The use of a “BDFE” for two separated reagents is perhaps a bit peculiar, because there is no X bond that is being homolytically cleaved. It is, however, a very useful way to characterize the thermochemistry of a PCET system, and it emphasizes the thermodynamic equivalence of H+/e- acceptors and H?acceptors [H+/e- donors and H?donors]. The literature for water oxidation, for example, typically quantifies the free energy required as a minimum redox potential of E?= 1.23 V (pH 0). However, this puts emphasis on the electron, while the thermochemistry depends equally on the e- and the H+. What is needed to convert H2O to O2 is a PCET reagent or PCET system with an average BDFE of 86 kcal mol-1 (eq 18, described above). This free energy can be obtained with a single PCET reagent or with a combination of an oxidant and a base. The required free energy can be obtained with a strong oxidant plus a weak base, or a weak oxidant plus a strong base. WhileChem Rev. Author manuscript; available in PMC 2011 December 8.Warren et al.Pagethis area has not received the same detailed study as traditional H-atom transfer reactions, we believe that it is a very important and versatile approach to PCET, and will prove to be widely used in biology and valuable in the development of new chemical processes. A huge number of possibilities are possible for oxidant/base combinations (H?acceptors) and reductant/acid combinations (H?donors). This is because there are many one-electron redox reagents and a huge number of possible acid.

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