Three-dimensional FDTD simulation of biomaterial exposure to electromagnetic nanopulses

Ultra-wideband (UWB) electromagnetic pulses of nanosecond duration, or nanopulses, have recently been approved by the Federal Communications Commission for a number of different applications. They are also being explored for applications in biotechnology and medicine. The simulation of the propagati...

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Veröffentlicht in:	Physics in medicine & biology 2005-11, Vol.50 (21), p.5041-5053, Article 5041
1. Verfasser:	Simicevic, Neven
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Sprache:	eng
Schlagworte:	Algorithms Biocompatible Materials - pharmacology Computer Simulation Electromagnetic Fields Humans Models, Statistical Nanotechnology Radiography - methods Software Time Factors
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creator	Simicevic, Neven
description	Ultra-wideband (UWB) electromagnetic pulses of nanosecond duration, or nanopulses, have recently been approved by the Federal Communications Commission for a number of different applications. They are also being explored for applications in biotechnology and medicine. The simulation of the propagation of a nanopulse through biological matter, previously performed using a two-dimensional finite-difference time-domain (FDTD) method, has been extended here into a full three-dimensional computation. To account for the UWB frequency range, the geometrical resolution of the exposed sample was 0.25 mm and the dielectric properties of biological matter were accurately described in terms of the Debye model. The results obtained from the three-dimensional computation support the previously obtained results: the electromagnetic field inside a biological tissue depends on the incident pulse rise time and width, with increased importance of the rise time as the conductivity increases; no thermal effects are possible for the low pulse repetition rates, supported by recent experiments. New results show that the dielectric sample exposed to nanopulses behaves as a dielectric resonator. For a sample in a cuvette, we obtained the dominant resonant frequency and the Q-factor of the resonator.
doi_str_mv	10.1088/0031-9155/50/21/007
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subjects	Algorithms Biocompatible Materials - pharmacology Computer Simulation Electromagnetic Fields Humans Models, Statistical Nanotechnology Radiography - methods Software Time Factors
title	Three-dimensional FDTD simulation of biomaterial exposure to electromagnetic nanopulses
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