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

Electronics obtained through the bottom-up approach of molecular-level control of material
composition and structure may lead to devices and fabrication strategies not possible with …

It is often thought that the ability to control reaction rates with an applied electrical potential
gradient is unique to redox systems. However, recent theoretical studies suggest that …

The design, synthesis, and properties of microporous framework materials have been the
subject of intense recent interest, for example in the areas of gas storage and molecular …

Building an electronic device using individual molecules is one of the ultimate goals in
nanotechnology. To achieve this it will be necessary to measure, control and understand …

This is the report of a DOE-sponsored workshop organized to discuss the status of our
understanding of charge-transfer processes on the nanoscale and to identify research and …

As an emerging area in organic electronics, polymer memories have become an active
research topic in recent years, because they are likely to be an alternative or supplementary …

The use of single molecules in electronics represents the next limit of miniaturisation of
electronic devices, which would enable us to continue the trend of aggressive downscaling …

Multifunctional living materials are attractive due to their powerful ability to self-repair and
replicate. However, most natural materials lack electronic functionality. Here we show that …

Controlling heat flow is a key challenge for applications ranging from thermal management
in electronics to energy systems, industrial processing, and thermal therapy. However …