Electrochemically grafted molecular layers as on-chip energy storage molecular junctions

Abstract

Molecular junctions (MJs) are well celebrated nanoelectronics devices for mimicking conventional electronic functions including rectifiers, sensors, wires, switches, transistors, negative differential resistance, and memory followed by the understanding charge transport mechanisms. However, capacitive nanoscale molecular junctions are rarely sightseen. The present work describes electrochemically (E-Chem) grown covalently attached molecular thin films of 10, 14.3, and 18.6 nm thickness using benzimidazole (BENZ) diazonium salts on ITO electrodes on quartz substrate upon which 50 nm of aluminium (Al) top contact was deposited to fabricate large-scale (area = 500 × 500 µm2) molecular junctions. The capacitance of the molecular junctions decreases with increasing thickness of molecular layers, a behavior attributed to a classical dielectric role in which the geometric capacitance of the device within a uniform dielectric component is expected to decrease with increasing its thickness. An electrical dipole moment in BENZ oligomers enhances the polarizability, hence the dielectric constant of the medium leads to an increase in capacitance of MJs, which reaches maximum values of ~ 53 µF cm-2 for the junction of 10 nm molecular film thickness. In addition to direct-current (DC) electrical measurements, and computational studies, we performed alternating current (AC)-based electrical measurements to understand the frequency response of molecular junctions. Our present study demonstrates that BENZ-based molecular junctions behave as classical organic capacitance and can be a suitable building block for nanoscale on-chip energy storage devices.