Elastic Peak Electron Spectroscopy, abbreviated as EPES, involves the analysis of the line shape found in the elastic peak. The reduction in the energy of electrons within the elastic peak is a result of energy being transferred to the target atoms, a phenomenon referred to as recoil energy. EPES distinguishes itself among electron spectroscopies by its unique ability to identify hydrogen in polymers and hydrogenated carbon-based materials. This distinctiveness is particularly notable because lighter elements demonstrate more pronounced energy shifts. The detection of hydrogen in polymers entails measuring the energy difference between the positions of the carbon (or carbon+oxygen) elastic peak and the hydrogen elastic peak. This difference tends to increase as the kinetic energy of the incident electrons rises. Concerning hydrogen peak intensity, electron beam-induced damage represents a critical aspect of EPES, as hydrogen desorbs under electron irradiation. In this study, the Monte Carlo method was employed to simulate EPES spectra involving electrons interacting with polyacetylene (C2H2), polyethylene (C2H4), polystyrene (C8H8), and polymethyl-methacrylate (C5H8O2) and to evaluate electron-induced hydrogen desorption from these polymers.
Electron-induced hydrogen desorption from selected polymers (polyacetylene, polyethylene, polystyrene, and polymethyl-methacrylate)
Dapor, Maurizio
2024-01-01
Abstract
Elastic Peak Electron Spectroscopy, abbreviated as EPES, involves the analysis of the line shape found in the elastic peak. The reduction in the energy of electrons within the elastic peak is a result of energy being transferred to the target atoms, a phenomenon referred to as recoil energy. EPES distinguishes itself among electron spectroscopies by its unique ability to identify hydrogen in polymers and hydrogenated carbon-based materials. This distinctiveness is particularly notable because lighter elements demonstrate more pronounced energy shifts. The detection of hydrogen in polymers entails measuring the energy difference between the positions of the carbon (or carbon+oxygen) elastic peak and the hydrogen elastic peak. This difference tends to increase as the kinetic energy of the incident electrons rises. Concerning hydrogen peak intensity, electron beam-induced damage represents a critical aspect of EPES, as hydrogen desorbs under electron irradiation. In this study, the Monte Carlo method was employed to simulate EPES spectra involving electrons interacting with polyacetylene (C2H2), polyethylene (C2H4), polystyrene (C8H8), and polymethyl-methacrylate (C5H8O2) and to evaluate electron-induced hydrogen desorption from these polymers.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.