Creating functional electrical circuits using individual or ensemble molecules, often termed
as “molecular-scale electronics”, not only meets the increasing technical demands of the …

Single-molecule junctions—devices in which a single molecule is electrically connected by
two electrodes—enable the study of a broad range of quantum-transport phenomena even …

Atomically thin two-dimensional (2D) materials—such as transition metal dichalcogenide
(TMD) monolayers and hexagonal boron nitride (hBN)—and their van der Waals layered …

Intermolecular charge transport plays an essential role in organic electronic materials and
biological systems. To date, experimental investigations of intermolecular charge transport …

To develop low-power, non-volatile computing-in-memory device using ferroelectric
transistor technologies, ferroelectric channel materials with scaled thicknesses are required …

Memristor, based on the principle of biological synapse, is recognized as one of the key
devices in confronting the bottleneck of classical von Neumann computers. However …

With the advent of the era of big data, resistive random access memory (RRAM) has become
one of the most promising nanoscale memristor devices (MDs) for storing huge amounts of …

We review charge transport across molecular monolayers, which is central to molecular
electronics (MolEl), using large-area junctions (NmJ). We strive to provide a wide conceptual …

This review focuses on molecular ensemble junctions in which the individual molecules of a
monolayer each span two electrodes. This geometry favors quantum mechanical tunneling …

Since memristors as an emerging nonlinear electronic component have been considered
the most promising candidate for integrating nonvolatile memory and advanced computing …