posted on 2021-07-08, 10:06authored byXiaoping Chen, Bernhard Kretz, Francis Adoah, Cameron Nickle, Xiao Chi, Xiaojiang Yu, Enrique del Barco, Damien ThompsonDamien Thompson, David A. Egger, Christian A. Nijhuis
We present an efficient strategy to modulate tunnelling in molecular junctions by changing
the tunnelling decay coefficient, β, by terminal-atom substitution which avoids altering the
molecular backbone. By varying X = H, F, Cl, Br, I in junctions with S(CH2)(10-18)X, current densities (J) increase >4 orders of magnitude, creating molecular conductors via reduction of β from 0.75 to 0.25 Å−1. Impedance measurements show tripled dielectric constants (εr) with X = I, reduced HOMO-LUMO gaps and tunnelling-barrier heights, and 5-times reduced contact resistance. These effects alone cannot explain the large change in β. Density functional theory shows highly localized, X-dependent potential drops at the S(CH2)nX// electrode interface that modifies the tunnelling barrier shape. Commonly-used tunnelling models neglect localized potential drops and changes in εr.