School of Chemical Sciences, Indian Association for the Cultivation of Science, Jadavpur, Kolkata 700032, West Bengal.
Inorg Chem. 2021 Jan 18;60(2):597-605. doi: 10.1021/acs.inorgchem.0c02185. Epub 2021 Jan 7.
Reactions requiring controlled delivery of protons and electrons are important in storage of energy in small molecules. While control over proton transfer can be achieved by installing appropriate chemical functionality in the catalyst, control of electron-transfer (ET) rates can be achieved by utilizing self-assembled monolayers (SAMs) on electrodes. Thus, a deeper understanding of the ET through SAM to an immobilized or covalently attached redox-active species is desirable. Long-range ET across several SAM-covered Au electrodes to covalently attached ferrocene is investigated using protonated and deuterated thiols (R-SH/R-SD). The rate of tunneling is measured using both chronoamperometry and cyclic voltammetry, and it shows a prominent kinetic isotope effect (KIE). The KIE is ∼2 (normal) for medium-chain-length thiols but ∼0.47 (inverse) for long-chain thiols. These results imply substantial contribution from the classical modes at the Au-(H)SR interface, which shifts substantially upon deuteration of the thiols, to the ET process. The underlying H/D KIE of these exchangeable thiol protons should be considered when analyzing solvent isotope effects in catalysis utilizing SAM.
需要控制质子和电子转移的反应在小分子的能量存储中非常重要。虽然可以通过在催化剂中安装适当的化学官能团来控制质子转移,但可以通过在电极上使用自组装单层 (SAM) 来控制电子转移 (ET) 速率。因此,深入了解通过 SAM 到固定或共价附着的氧化还原活性物质的 ET 是可取的。使用质子化和氘化硫醇 (R-SH/R-SD) 研究了跨越几个 SAM 覆盖的 Au 电极到共价附着的二茂铁的长程 ET。使用计时安培法和循环伏安法测量了隧穿速率,并且显示出明显的动力学同位素效应 (KIE)。对于中等链长的硫醇,KIE 约为 2(正常),但对于长链硫醇,KIE 约为 0.47(反转)。这些结果表明,在 Au-(H)SR 界面处的经典模式对 ET 过程有很大的贡献,而硫醇的氘化会大大改变这种贡献。在利用 SAM 分析利用 SAM 的催化中的溶剂同位素效应时,应该考虑这些可交换硫醇质子的潜在 H/D KIE。
