We review the status of protein-based molecular electronics. First, we define and discuss
fundamental concepts of electron transfer and transport in and across proteins and …

Biomolecular electronics is a rapidly growing multidisciplinary field that combines biology,
nanoscience, and engineering to bridge the two important fields of life sciences and …

The emerging field of BioMolecular Electronics aims to unveil the charge transport
characteristics of biomolecules with two primary outcomes envisioned. The first is to use …

A central vision in molecular electronics is the creation of devices with functional molecular
components that may provide unique properties. Proteins are attractive candidates for this …

Protein structures can facilitate long-range electron transfer in solution. But a fundamental
question remains: can these structures also serve as solid-state electronic conductors …

Electron transfer (ET) through proteins, a fundamental element of many biochemical
reactions, is studied intensively in aqueous solutions. Over the past decade, attempts were …

Bioelectronic materials interface biomolecules, cells, organs, or organisms with electronic
devices, and they represent an active and growing field of materials research. Protein and …

A major challenge in molecular electronics is to attach electrodes to single molecules in a
reproducible manner to make molecular junctions that can be operated as transistors …

Bioelectronics research has mainly focused on redox-active proteins because of their role in
biological charge transport. In these proteins, electronic conductance is a maximum when …

Multi-heme cytochromes (MHCs) are fascinating proteins used by bacterial organisms to
shuttle electrons within, between, and out of their cells. When placed in solid-state electronic …