Simulation Calculation of Mechanical Performance of Particle Filled Electronic Packaging Polymer

Electronic packaging polymers filled with various solid additives such as silica, flame retardant, etc. have excessively been required for the use in advanced IC packages in recent years. It's necessary to predict the mechanical properties of these electronic packaging materials. On the basis o...

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Hauptverfasser:	Dayong Gui, Juhua Mao, Deyu Tian, Jianhong Liu
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Sprache:	eng
Schlagworte:	Additives Chemicals Composite materials electronic packaging polymer Electronics packaging Flame retardants Integrated circuit packaging Mechanical factors mechanical performance Polymers Silicon compounds simulation calculation Solids
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creator	Dayong Gui Juhua Mao Deyu Tian Jianhong Liu
description	Electronic packaging polymers filled with various solid additives such as silica, flame retardant, etc. have excessively been required for the use in advanced IC packages in recent years. It's necessary to predict the mechanical properties of these electronic packaging materials. On the basis of structural and mechanical characterization of particle filled epoxy materials, a new three-phase (dispersion phase, interface phase, and continuous phase) constitutive model and its simulation calculation are performed for the mechanical properties of the particle filled electronic packaging polymer in this study. In this paper, the interface chemical principle and three phase constitute model are combined, which improve the mechanical property's calculation and composition design method of electronic packaging polymer. With this model, the relationship between mechanical properties of the electronic packaging materials and modulus of matrix, solid particles content, particle size, gradation and thickness of the interface adhesive layer were constructed mathematically. This relationship and its derived patterns can be used in not only the prediction of the mechanical properties of electronic packaging materials but also the instruction of the composition design for particle filled electronic packaging materials
doi_str_mv	10.1109/ICEPT.2006.359801
format	Conference Proceeding
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It's necessary to predict the mechanical properties of these electronic packaging materials. On the basis of structural and mechanical characterization of particle filled epoxy materials, a new three-phase (dispersion phase, interface phase, and continuous phase) constitutive model and its simulation calculation are performed for the mechanical properties of the particle filled electronic packaging polymer in this study. In this paper, the interface chemical principle and three phase constitute model are combined, which improve the mechanical property's calculation and composition design method of electronic packaging polymer. With this model, the relationship between mechanical properties of the electronic packaging materials and modulus of matrix, solid particles content, particle size, gradation and thickness of the interface adhesive layer were constructed mathematically. 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identifier	ISBN: 1424406196
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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Additives Chemicals Composite materials electronic packaging polymer Electronics packaging Flame retardants Integrated circuit packaging Mechanical factors mechanical performance Polymers Silicon compounds simulation calculation Solids
title	Simulation Calculation of Mechanical Performance of Particle Filled Electronic Packaging Polymer
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