Single-molecule optoelectronic devices promise a potential solution for miniaturization and
functionalization of silicon-based microelectronic circuits in the future. For decades of its fast …

Monolayer-based electronics have emerged as a promising solution that solves the
limitations of miniaturization in microelectronic circuits and paves the way for advanced …

The Fano resonance in single‐molecule junctions could be created by interaction with
discrete and continuous molecular orbitals and enables effective electron transport …

Dipyridyl molecular junctions often show intriguing conductance switching behaviors with
mechanical modulations, but the mechanisms are still not completely revealed. By applying …

Charge transport in electrochemical energy-storage systems critically relies on supporting
electrolytes to maintain ionic strength and solution conductivity. Despite recent progress, it is …

Over the past decades, the prototypes of single-molecule devices have emerged, promoting
rapid development in the field of single-molecule electronics. To put such molecular devices …

Heterogeneous interfaces in most devices play a key role in the material performance.
Exploring the atomic structure and electronic properties of metal–molecule interfaces is …

As a central research target in molecular electronics, molecular switches have been
extensively explored over the past decades. We theoretically demonstrate that when linking …

Diphenyl sulfide is connected with one or two thioanisoles, in a system initially prepared to
learn about the electronic charge transport through it. Unexpectedly, we observed a …

Achieving highly transmitting molecular junctions through resonant transport at low bias is
key to the next-generation low-power molecular devices. Although resonant transport in …