The electric field intensity of the compressed ultra-relativistic electron beams is approaching GV/m levels, which is sufficient to cause observable tunneling effect in the low band gap materials. In this article the tunneling ionization rate is estimated for the experimentally available electron beam parameters, and a proposed proof of principle experiment is outlined. Tunneling effect has exponential dependence on the electric field strength; thus being very sensitive to the electron beam peak current. This non-linear dependence opens up a possibility to construct inexpensive, single shot and non-destructive peak current diagnostics for the ultrarelativistic compressed electron beams
The Electron Beam Ion Trap (EBIT) of the National Superconducting Cyclotron Laboratory at Michigan S...
This paper contains the present development of a non-destructive method for intensive relativistic b...
This paper explores the physics of vacuum rf breakdowns in subterahertz high-gradient traveling-wave...
We present here the first experimental test of a singlepass non-destructive method of monitoring of ...
The correct measurement of beam size using an ionization profile monitor relies on the confinement o...
Relativistic electron microscopes are increasingly under consideration in dream experiments of obser...
Continuing size reduction in semiconductor manufacturing, and a push toward atomic time and spatial ...
Measurements of the longitudinal profile of intense electron bunches with an energy of 100 keV, usin...
The dynamics of atomic scale structures during structural change can be studied by Ultrafast Electro...
Electron emission for single ionization of Ne by 25 fs, 1.0 PW/cm2 laser pulses at 800 nm was invest...
Experiments with high gradient traveling-wave mm-wave metallic accelerating structures were performe...
A quantum approach is presented to investigate tunneling time by supervising the instantaneous ioniz...
Similarly to laser or X-ray beams, the interaction of sufficiently intense particle beams with neutr...
L-band (1.3 GHz) electron linear accelerator as part of its Radiation Chemistry Program. One very in...
Ultrashort electron bunches with rms length of {approx} 1 femtosecond (fs) can be used to generate u...
The Electron Beam Ion Trap (EBIT) of the National Superconducting Cyclotron Laboratory at Michigan S...
This paper contains the present development of a non-destructive method for intensive relativistic b...
This paper explores the physics of vacuum rf breakdowns in subterahertz high-gradient traveling-wave...
We present here the first experimental test of a singlepass non-destructive method of monitoring of ...
The correct measurement of beam size using an ionization profile monitor relies on the confinement o...
Relativistic electron microscopes are increasingly under consideration in dream experiments of obser...
Continuing size reduction in semiconductor manufacturing, and a push toward atomic time and spatial ...
Measurements of the longitudinal profile of intense electron bunches with an energy of 100 keV, usin...
The dynamics of atomic scale structures during structural change can be studied by Ultrafast Electro...
Electron emission for single ionization of Ne by 25 fs, 1.0 PW/cm2 laser pulses at 800 nm was invest...
Experiments with high gradient traveling-wave mm-wave metallic accelerating structures were performe...
A quantum approach is presented to investigate tunneling time by supervising the instantaneous ioniz...
Similarly to laser or X-ray beams, the interaction of sufficiently intense particle beams with neutr...
L-band (1.3 GHz) electron linear accelerator as part of its Radiation Chemistry Program. One very in...
Ultrashort electron bunches with rms length of {approx} 1 femtosecond (fs) can be used to generate u...
The Electron Beam Ion Trap (EBIT) of the National Superconducting Cyclotron Laboratory at Michigan S...
This paper contains the present development of a non-destructive method for intensive relativistic b...
This paper explores the physics of vacuum rf breakdowns in subterahertz high-gradient traveling-wave...
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