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Outrunning damage: Electrons vs X-rays-timescales and mechanisms
John Spence
Applied Structural Discovery, Center for (ASD)
Physics
Biological Physics, Center for
Research output
:
Contribution to journal
›
Article
›
peer-review
46
Scopus citations
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Engineering & Materials Science
X ray lasers
100%
Electrons
73%
X rays
66%
Elastic scattering
65%
Coulomb interactions
58%
Free electron lasers
56%
Electron scattering
33%
Electron spectroscopy
31%
Photoelectrons
28%
Radiation damage
27%
Electron diffraction
24%
Laser pulses
23%
Electron beams
21%
Viruses
21%
Irradiation
18%
Explosions
17%
Proteins
16%
Imaging techniques
14%
Experiments
6%
Physics & Astronomy
damage
52%
free electron lasers
37%
x rays
33%
elastic scattering
32%
electrons
30%
nuclei
23%
viruses
21%
beam currents
19%
radiation damage
18%
emittance
18%
scattering cross sections
18%
mean free path
18%
high energy electrons
18%
pulses
18%
destruction
18%
electron spectroscopy
17%
explosions
16%
photoelectrons
16%
electron scattering
16%
electron diffraction
15%
fluence
15%
proteins
14%
interactions
14%
insulators
13%
electron beams
13%
dosage
12%
irradiation
11%
probes
11%
cross sections
10%
lasers
8%
energy
5%
Chemical Compounds
Elastic Scattering
60%
Free Electron
46%
X-Ray
44%
Electron Particle
39%
Electron Scattering
29%
Electron Spectroscopy
23%
Nonconductor
20%
Electron Beam
19%
Photoelectron
18%
Electron Diffraction
18%
Dose
14%
Probe
11%
Energy
8%
Protein
7%