Theoretische Chemie, Universität Heidelberg, Im Neuenheimer Feld 229, D-69120 Heidelberg, Germany.
Phys Chem Chem Phys. 2018 Sep 19;20(36):23492-23499. doi: 10.1039/c8cp04974b.
At present, it is widely accepted that properties (e.g., molecular conformation) of molecules adsorbed to form self-assembled monolayers (SAMs) on electrodes can be very different from isolated species because of a substantial charge transfer or specific chemical bonding at the interface. Contrary to this view, the theoretical results presented here predict that the strong twisting angle (φ) enhancement of floppy molecules adsorbed to form densely packed SAMs on most common electrodes (Pt, Au, Ag, and Cu) is neither due to charge transfer nor to specific bonding but rather to a sui generis electrode-driven spatial confinement effect that can be quantitatively described within an electrode-free two-dimensional model. We predict a logistic ("Fermi-Dirac") growth pattern of φ as the coverage approaches the value characteristic of a herringbone arrangement, which is twice the value for isolated molecules or low-coverage SAMs.
目前,人们普遍认为,由于在界面处发生了大量的电荷转移或特定的化学键合,吸附在电极上形成自组装单层 (SAM) 的分子的性质(例如分子构象)可能与孤立物种非常不同。与这种观点相反,这里提出的理论结果预测,对于在大多数常见电极(Pt、Au、Ag 和 Cu)上形成密排 SAM 的柔性分子的强烈扭转角 (φ) 增强既不是由于电荷转移也不是由于特定键合,而是由于独特的电极驱动的空间限制效应,这种效应可以在无电极的二维模型中进行定量描述。我们预测 φ 的对数 ("费米-狄拉克") 增长模式,随着覆盖率接近鲱鱼骨排列特征值,该值是孤立分子或低覆盖率 SAM 的两倍。
