Department of Chemistry, Case Western Reserve University, Cleveland, Ohio 44106-7078, USA.
Phys Chem Chem Phys. 2012 Jan 28;14(4):1330-8. doi: 10.1039/c2cp23616h. Epub 2011 Dec 12.
When standard reversible potentials for bulk solution reactions, U(0), are known, the reversible potentials when the reactant and product are adsorbed on an electrocatalyst surface, U(surf)(rev), are given in terms of these potentials and the adsorption Gibbs energy bond strengths: U(surf)(rev) = U0 + D(ads)G (Ox)/F-Δ(ads)G (R)/F (i). When the Δ(ads)G (Ox) and Δ(ads)G (Red) values are known at potential U, this equation is exact. When the overpotential for a multi-electron transfer reaction is minimal, each electron transfer takes place at the standard reversible potential for the overall reaction. In the case of O(2) reduction to water via the intermediate step OOH(aq) → O(aq) + OH(aq), or via O(2)(g) → 2O(aq), the respective endergonic O-O dissociation Gibbs energies are shown to be 2.52 eV and 4.76 eV. When the oxygen product and water reactant adsorb weakly, as on platinum, the adsorption Gibbs energies, Δ(ads)G, for O, OH, and OOH intermediates can be uniquely predicted using these data. All of the above depend exclusively on experimentally determined data. Reversible potentials have been calculated for oxygen reduction steps on the platinum electrocatalyst surface using Interface 1.0, a comprehensive computational code for the potential dependence of the electrochemical interface. Using these results as benchmarks, is found to be accurate to around 0.1 V when the Δ(ads)G are values calculated for the potentials of zero charge, instead of 1.229 V, which is a significant simplification. The variation in Δ(ads)G values between the calculated potentials of zero charge and 1.229 V are found to be 0.2 eV V(-1) or less. Prior work, using internal adsorption energies calculated at the potential of zero charge in place of Gibbs energies in was found to be accurate to within about 0.2 V. On platinum Δ(ads)G of the reaction OOH(ads) → O(ads) + OH(ads) is calculated at the potential of zero charge for the reactant and product to be about 1.2 eV exergonic under Langmuir conditions, and this Gibbs energy loss reduces the 1.229 V four-electron reversible potential on the platinum surface to an effective reversible potential of about 0.93 V for this mechanism on platinum. The effective reversible potential is a consequence of efficiency loss, not kinetics. Based on these values, the onset potential for four-electron oxygen reduction will be less than or equal to the effective reversible potential and on pure Pt(111) it appears to be equal to it.
当标准的整体溶液反应可逆电位 U(0) 已知时,反应物和产物在电催化剂表面吸附时的可逆电位 U(surf)(rev) 可以用这些电位和吸附吉布斯能键强度表示:U(surf)(rev) = U0 + D(ads)G (Ox)/F-Δ(ads)G (R)/F (i)。当在电位 U 下已知 Δ(ads)G (Ox) 和 Δ(ads)G (Red) 值时,该方程是精确的。当多电子转移反应的过电位最小时,每个电子转移都发生在整个反应的标准可逆电位处。在通过中间步骤 OOH(aq) → O(aq) + OH(aq) 或 O(2)(g) → 2O(aq) 将氧气还原为水的情况下,相应的 O-O 离解吉布斯能分别显示为 2.52 eV 和 4.76 eV。当氧气产物和水反应物在铂等弱吸附时,可以使用这些数据唯一地预测 O、OH 和 OOH 中间体的吸附吉布斯能 Δ(ads)G。所有这些都完全依赖于实验确定的数据。使用综合计算代码 Interface 1.0 计算了铂电催化剂表面氧气还原步骤的可逆电位,Interface 1.0 是用于电化学界面电位依赖性的计算代码。使用这些结果作为基准,发现当针对零电荷电位计算 Δ(ads)G 值而不是 1.229 V 时,准确度约为 0.1 V,这是一个显著的简化。在零电荷电位和 1.229 V 之间计算的 Δ(ads)G 值之间的变化发现为 0.2 eV V(-1) 或更小。之前的工作使用在零电荷电位处计算的内部吸附能代替吉布斯能在准确度方面被发现约为 0.2 V。在铂上,在 Langmuir 条件下,反应物和产物的 OOH(ads) → O(ads) + OH(ads) 反应的 Δ(ads)G 计算为约 1.2 eV 的放热能,这种吉布斯能损失将铂表面的 1.229 V 四电子可逆电位降低到该机制在铂上的有效可逆电位约 0.93 V。有效可逆电位是效率损失的结果,而不是动力学的结果。基于这些值,四电子氧气还原的起始电位将小于或等于有效可逆电位,并且在纯 Pt(111) 上似乎等于它。
