Quasi first-principles Monte Carlo modeling of energy dissipation by low-energy electron beams in multi-walled carbon nanotube materials

Dimitris Emfietzoglou; Ioanna Kyriakou; Rafael Garcia-Molina; Isabel Abril; Kostas Kostarelos

doi:10.1063/1.3688307

Quasi first-principles Monte Carlo modeling of energy dissipation by low-energy electron beams in multi-walled carbon nanotube materials

Dimitris Emfietzoglou, Ioanna Kyriakou, Rafael Garcia-Molina, Isabel Abril, Kostas Kostarelos

Research output: Contribution to journal › Article › peer-review

Abstract

The energy dissipation pattern of low-energy electron beams (0.3-30 keV) in multi-walled carbon nanotube (MWCNT) materials is studied by Monte Carlo simulation taking into account secondary-electron cascade generation. A quasi first-principles discrete-energy-loss model deduced from a dielectric response function description of electronic excitations in MWCNTs is employed whereby both single-particle and plasmon excitations are included in a unified and self-consistent manner. Our simulations provide practical analytical functions for computing depth-dose curves and charged-carrier generation volumes in MWCNT materials under low-energy electron beam irradiation. © 2012 American Institute of Physics.

Original language	English
Article number	093113
Journal	Applied Physics Letters
Volume	100
Issue number	9
DOIs	https://doi.org/10.1063/1.3688307
Publication status	Published - 27 Feb 2012

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title = "Quasi first-principles Monte Carlo modeling of energy dissipation by low-energy electron beams in multi-walled carbon nanotube materials",

abstract = "The energy dissipation pattern of low-energy electron beams (0.3-30 keV) in multi-walled carbon nanotube (MWCNT) materials is studied by Monte Carlo simulation taking into account secondary-electron cascade generation. A quasi first-principles discrete-energy-loss model deduced from a dielectric response function description of electronic excitations in MWCNTs is employed whereby both single-particle and plasmon excitations are included in a unified and self-consistent manner. Our simulations provide practical analytical functions for computing depth-dose curves and charged-carrier generation volumes in MWCNT materials under low-energy electron beam irradiation. {\textcopyright} 2012 American Institute of Physics.",

author = "Dimitris Emfietzoglou and Ioanna Kyriakou and Rafael Garcia-Molina and Isabel Abril and Kostas Kostarelos",

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AU - Emfietzoglou, Dimitris

AU - Kyriakou, Ioanna

AU - Garcia-Molina, Rafael

AU - Abril, Isabel

AU - Kostarelos, Kostas

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N2 - The energy dissipation pattern of low-energy electron beams (0.3-30 keV) in multi-walled carbon nanotube (MWCNT) materials is studied by Monte Carlo simulation taking into account secondary-electron cascade generation. A quasi first-principles discrete-energy-loss model deduced from a dielectric response function description of electronic excitations in MWCNTs is employed whereby both single-particle and plasmon excitations are included in a unified and self-consistent manner. Our simulations provide practical analytical functions for computing depth-dose curves and charged-carrier generation volumes in MWCNT materials under low-energy electron beam irradiation. © 2012 American Institute of Physics.

AB - The energy dissipation pattern of low-energy electron beams (0.3-30 keV) in multi-walled carbon nanotube (MWCNT) materials is studied by Monte Carlo simulation taking into account secondary-electron cascade generation. A quasi first-principles discrete-energy-loss model deduced from a dielectric response function description of electronic excitations in MWCNTs is employed whereby both single-particle and plasmon excitations are included in a unified and self-consistent manner. Our simulations provide practical analytical functions for computing depth-dose curves and charged-carrier generation volumes in MWCNT materials under low-energy electron beam irradiation. © 2012 American Institute of Physics.

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JO - Applied Physics Letters

JF - Applied Physics Letters

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ER -

Quasi first-principles Monte Carlo modeling of energy dissipation by low-energy electron beams in multi-walled carbon nanotube materials

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