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 electronic devices in which individual molecules are utilized as active
electronic components constitute a promising approach for the ultimate miniaturization and …

Transport of electrons in a single molecule junction is the simplest problem in the general
subject area of molecular electronics. In the past few years, this area has been extended to …

Short chains of porphyrin molecules can mediate electron transport over distances as long
as 5–10 nm with low attenuation. This means that porphyrin-based molecular wires could be …

The ultimate aim of molecular electronics is to understand and master single-molecule
devices. Based on the latest results on electron transport in single molecules in solid-state …

Molecular electronics seeks to incorporate molecular components as functional elements in
electronic devices. There are numerous strategies reported to date for the fabrication …

Recent progress in the measurement and modeling of transport in molecular junctions has
been very significant. Tunnel transport in the Landauer–Imry regime is now broadly …

Conspectus The field of molecular electronics has grown rapidly since its experimental
realization in the late 1990s, with thousands of publications on how molecules can act as …

Nanogap electrodes (namely, a pair of electrodes with a nanometer gap) are fundamental
building blocks for the fabrication of nanometer‐sized devices and circuits. They are also …

We analyze quantum interference and decoherence effects in single-molecule junctions
both experimentally and theoretically by means of the mechanically controlled break …