This finding underscores the need to understand charge transport in organic devices before spin transport can be tackled.

The above conductivity and its associated current density reflect the fundamental mechanisms underlying charge transport in the medium, both in time and over distance.

Barton eventually moved to Caltech, where her research has focused on charge transport in DNA.

These are commonly called charge density waves, and they are an example of collective charge transport.

This can cause strong phonon scattering but would not affect charge transport.

The transport of counterions along with the pressure-driven fluid flow gives rise to a net charge transport: the streaming current.

In the former case charge transport is quantized even in the case of small back scattering.

Since the conformation of wireing path changes along with electronic charge transport in the circuit, equivalent circuit would change continuously.

Higher conductivities originate from highly conjugated systems, while alkane chains are important in understanding basic charge transport and tunneling.

For small channels, surface conductivity is responsible for most of the charge transport.