The theory provides a guideline in
controlling electron energy which is important for applications such as ion acceleration and pair plasma creation.
Not exact matches
This plasma of high -
energy electron particles then release a
controlled beam of ultra-energized photons, the gamma rays.
Understand how
electrons move, and we might
control reactions better, design more effective drugs and better materials for generating
energy, and boost today's sluggish computers to warp speed.
A major difference between graphene and germanene is the «band gap», a property well - known in semiconductor electronics: thanks to this «jump» of
energy levels that
electrons are allowed to have, it is possible to
control, switch and amplify currents.
A bandgap is an
energy barrier, essential for
controlling the flow of
electrons, like an on / off switch.
We use sound waves
controlled by the
electron energies to interpret the crystal, with echoes marking the passing high symmetry points.
To address these challenges, the Molecular and Nanoscale Interfaces Project aims to couple light absorbers, catalysts, and half - reactions for optimal
control of the rate, yield, and energetics of
electron and proton flow at the nanoscale, so that complete macroscale artificial photosynthetic systems can achieve maximum conversion of solar photon
energy into the chemical
energy of a fuel.