Over the past two decades, various techniques for fabricating nano-gapped electrodes have
emerged, promoting rapid development in the field of single-molecule electronics, on both …

Heterogeneous interfaces that are ubiquitous in optoelectronic devices play a key role in the
device performance and have led to the prosperity of today's microelectronics. Interface …

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

Through molecular engineering, single diarylethenes were covalently sandwiched between
graphene electrodes to form stable molecular conduction junctions. Our experimental and …

Monitoring and manipulating the physical and chemical behavior of single molecules is an
important development direction of molecular electronics that aids in understanding the …

Electronic transport properties of single-molecule junctions have been widely measured by
several techniques, including mechanically controllable break junctions, electromigration …

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 …

The use of single molecules in electronics represents the next limit of miniaturisation of
electronic devices, which would enable us to continue the trend of aggressive downscaling …

Molecular electronic devices with tunable conductance states show great potential in
building memories and logic components for next-generation circuits. In recent years …

Molecular electronics is driven by the dream of expanding Moore's law to the molecular level
for next‐generation electronics through incorporating individual or ensemble molecules into …