Arefiev co-authored the study, «Enhanced multi-MeV photon emission by a laser -
driven electron beam in a self - generated magnetic field,» published May 2016 in the journal Physical Review Letters.
Not exact matches
Energetic
electrons driven in the polarization direction of an intense laser
beam incident normal to a solid target
About a decade ago that question
drove Gilliane Monnier, an archaeologist at the University of Minnesota, to put an artifact under an
electron beam.
We demonstrate that the
electron beam, simultaneously acting as an imaging probe and a source of energy to
drive chemical transformations, offers a new tool for studying the chemical reactions of individual molecules with atomic resolution, which is vital for the discovery of new reaction mechanisms and more efficient future synthesis.»
A recent paper in Nature Communications shows how the transport of a laser -
driven relativistic
electron beam in dense matter is improved when imposing a strong magnetic field.
Berkeley Lab was home to a pioneering experiment) in 2004 that showed laser plasma acceleration can produce relatively narrow energy spread
beams - reported in the so - called «Dream Beam» issue of the journal Nature - and in 2006 used a similar laser -
driven acceleration technique to accelerate
electrons to a then - record energy of 1 billion
electron volts, or GeV.
Berkeley Lab was home to a pioneering experiment in 2004 that showed laser plasma acceleration can produce relatively narrow energy spread
beams — reported in the so - called «Dream Beam» issue of the journal Nature — and in 2006 used a similar laser -
driven acceleration technique to accelerate
electrons to a then - record energy of 1 billion
electron volts, or GeV.