"978-80-87294-23-9" . "213035" . "constriction phenomenon; polymer composites; COMSOL Multiphysics"@en . . "RIV/68407700:21230/11:00183680!RIV12-MSM-21230___" . "Ostrava" . . . . "http://www.nanocon.cz" . "6"^^ . "2011-09-21+02:00"^^ . "Jirk\u016F, Slavom\u00EDr" . . "21230" . "Modeling the Constriction Phenomenon on Composites with Conductive Carbon Particles in COMSOL"@en . . "TANGER, spol.s r.o" . "Brno" . . "3"^^ . . . "Modeling the Constriction Phenomenon on Composites with Conductive Carbon Particles in COMSOL" . "RIV/68407700:21230/11:00183680" . "2"^^ . "Modeling the Constriction Phenomenon on Composites with Conductive Carbon Particles in COMSOL"@en . . . . "Z(MSM6840770021)" . "The constriction phenomenon in polymer composites filled with conductive carbon particles is handled in plane and space using two models. 1st Model: Contact of spherical particles 2nd Model: Connecting of two spherical particles by means of conductive bridge For solving the above mentioned models, we will use the equation defining the electric current field in a conductive environment. The COMSOL Multiphysics program environment was used to resolve the stated boundary conditions for various values of overlapping particles or bridge widths. The current density and current I conducted through electrodes will be evaluated from the obtained electric fields. The models for the joining of conductive carbon particles in an electrically non-conductive environment show the impact the shape of the field has on the electric resistance of the studied system." . . "The constriction phenomenon in polymer composites filled with conductive carbon particles is handled in plane and space using two models. 1st Model: Contact of spherical particles 2nd Model: Connecting of two spherical particles by means of conductive bridge For solving the above mentioned models, we will use the equation defining the electric current field in a conductive environment. The COMSOL Multiphysics program environment was used to resolve the stated boundary conditions for various values of overlapping particles or bridge widths. The current density and current I conducted through electrodes will be evaluated from the obtained electric fields. The models for the joining of conductive carbon particles in an electrically non-conductive environment show the impact the shape of the field has on the electric resistance of the studied system."@en . . . "Modeling the Constriction Phenomenon on Composites with Conductive Carbon Particles in COMSOL" . . "Nanocon 2011, Conference Proceedings" . . "Hampl, J." . . "[E3211D28A7EA]" . "Pilar\u010D\u00EDkov\u00E1, Ivana" .