Add to ORKGAfter a brief introduction to scattering processes, a Monte Carlo procedure is described and used to simulate the interaction of an electron beam with a thick solid target. In particular the backscattering coefficient and the mean energy of the reflected electrons are computed and compared with the experimental data of Cosslett and Thomas, Palluel and Bishop. The Monte Carlo simulations, performed for several elements (Be, C, Al, Si, Ca, Ti, Cr, Cu, Ge, Mo, Ag, Ta, W, Pt, and Au) and for 5 and 10 keV primary energies, have then been used to calculate the energy dissipated in the target and compared with a simple theoretical treatment
A Monte Carlo (MC) simulation is described and used to calculate the energy distribution spectra of ...
This book presents the potential of the Monte Carlo (MC) technique to solve mathematical and physica...
We have computed, by a Monte Carlo code, the backscattering coefficient of low-medium energy electro...
Electron-matter interaction is described by a Monte Carlo procedure in which the mean free path is c...
A Monte Carlo program has been used to simulate the energy dissipation of medium-energy electrons (1...
When an electron beam impinges on a solid, some particles of the beam come back and emerge from the ...
Monte Carlo computations of the electron backscattering coefficient as a function of the primary ene...
A Monte Carlo procedure to simulate the penetration and energy loss of low¿energy electron beams thr...
The backscattering coefficient of low-medium energy electron beams (from 250 eV to 10,000 eV) imping...
Monte Carlo simulations are very useful for many physical processes. The transport of particles was ...
Abstract. The problen of the backscattering of electrons from metal targets is subject of extensive ...
In this work, a Monte Carlo simulation code for the electron-beam propagation was developed using th...
Monte Carlo (MC) technique allows solving mathematical and physical problems of great complexity. On...
Monte Carlo (MC) technique allows solving mathematical and physical problems of great complexity. On...
A Monte Carlo procedure to simulate the penetration and energy loss of low¿energy electron beams thr...
A Monte Carlo (MC) simulation is described and used to calculate the energy distribution spectra of ...
This book presents the potential of the Monte Carlo (MC) technique to solve mathematical and physica...
We have computed, by a Monte Carlo code, the backscattering coefficient of low-medium energy electro...
Electron-matter interaction is described by a Monte Carlo procedure in which the mean free path is c...
A Monte Carlo program has been used to simulate the energy dissipation of medium-energy electrons (1...
When an electron beam impinges on a solid, some particles of the beam come back and emerge from the ...
Monte Carlo computations of the electron backscattering coefficient as a function of the primary ene...
A Monte Carlo procedure to simulate the penetration and energy loss of low¿energy electron beams thr...
The backscattering coefficient of low-medium energy electron beams (from 250 eV to 10,000 eV) imping...
Monte Carlo simulations are very useful for many physical processes. The transport of particles was ...
Abstract. The problen of the backscattering of electrons from metal targets is subject of extensive ...
In this work, a Monte Carlo simulation code for the electron-beam propagation was developed using th...
Monte Carlo (MC) technique allows solving mathematical and physical problems of great complexity. On...
Monte Carlo (MC) technique allows solving mathematical and physical problems of great complexity. On...
A Monte Carlo procedure to simulate the penetration and energy loss of low¿energy electron beams thr...
A Monte Carlo (MC) simulation is described and used to calculate the energy distribution spectra of ...
This book presents the potential of the Monte Carlo (MC) technique to solve mathematical and physica...
We have computed, by a Monte Carlo code, the backscattering coefficient of low-medium energy electro...