Molecular junctions are building blocks for constructing future nanoelectronic devices that
enable the investigation of a broad range of electronic transport properties within nanoscale …

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

Highly-efficient molecular photoswitching occurs ex-situ but not to-date inside electronic
devices due to quenching of excited states by background interactions. Here we achieve …

Molecular junctions (MJs) represent an ideal platform for studying charge and energy
transport at the atomic and molecular scale and are of fundamental interest for the …

A key goal in molecular electronics has been to find molecules that facilitate efficient charge
transport over long distances. Normally, molecular wires become less conductive with …

Single-molecule conductance measurements for 9, 14-diphenyl-9, 14-dihydrodibenzo [a, c]
phenazine (DPAC) may offer unique insight into the bent-to-planar photocycle between the …

Molecular electronics is a field that explores the ultimate limits of electronic device
dimensions by using individual molecules as operable electronic devices. Over the past five …

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 …

Single-molecule devices not only promise to provide an alternative strategy to break through
the miniaturization and functionalization bottlenecks faced by traditional semiconductor …

Single‐molecule electrical and spin switches have been one of the main research focuses in
molecular electronics and spintronics because they may form the most important elements …