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

There is a rapidly growing demand for self-powered technologies in wearable electronic
devices that can be integrated with the human body to accomplish various functions …

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 …

As the size of materials, particles, and devices shrinks to nanometer, atomic, or even
quantum scale, it is more challenging to characterize their thermal properties reliably …

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 …

The demands for waste heat energy recovery from industrial production, solar energy, and
electronic devices have resulted in increasing attention being focused on thermoelectric …

To understand the electrical and charge transport phenomena in either single or large‐scale
molecular junctions, direct current (DC) measurements are mainly utilized. The current …

Conspectus Understanding the thermoelectric effects that convert energy between heat and
electricity on a molecular scale is of great interest to the nanoscience community. As …

With the advent of molecular electronics, tremendous attention has been paid towards
understanding the structure-function relationship of molecular junctions. Understanding how …

The study of thermoelectricity in molecular junctions is of fundamental interest for the
development of various technologies including cooling (refrigeration) and heat-to-electricity …