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

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 …

A challenge in molecular electronics is to control the strength of the molecule–electrode
coupling to optimize device performance. Here we show that non-covalent contacts between …

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 …

Two competing models for long-range electron transport through the conductive biofilms and
nanowires of Geobacter sulfurreducens exist. In one model electrons are transported via pili …

Single‐molecule electrochemical transistors are a type of novel molecular devices in which
the tunneling current through the single‐molecule junction is modulated by the …

Biology leverages a range of electrical phenomena to extract and store energy, control
molecular reactions and enable multicellular communication. Microbes, in particular, have …

Resistive switching memory constitutes a prospective candidate for next‐generation data
storage devices. Meanwhile, naturally occurring biomaterials are promising building blocks …

The ultimate goal in molecular electronics is to use individual molecules as the active
electronic component of a real-world sturdy device. For this concept to become reality, it will …

The field of organic electronics continues to be driven by new charge-transporting materials
that are typically processed from toxic organic solvents incompatible with biological …