Page 206 - Polymer-based Nanocomposites for Energy and Environmental Applications
P. 206
178 Polymer-based Nanocomposites for Energy and Environmental Applications
[174] Bunde A, Dieterich W. Percolation in Composites. J Electroceram 2000;5:81–92.
[175] McLachlan DS, Sauti G. The AC and DC conductivity of nanocomposites. 2007:30389.
[176] Sun Y, Zhang Z, Wong CP. Influence of interphase and moisture on the dielectric spec-
troscopy of epoxy/silica composites. Polymer 2005;46:2297–305.
[177] Montanari GC, Fabiani D, Palmieri F, Kaempfer D, Thomann R, Mulhaupt R. Modifi-
cation of electrical properties and performance of EVA and PP insulation through nano-
structure by organophilic silicates. IEEE Trans Dielectr Electr Insul 2004;11:754–62.
[178] Tanaka T, Kozaka M, Fuse N, Ohki Y. Proposal of a multi-core model for polymer
nanocomposite dielectrics. IEEE Trans Dielectr Electr Insul 2005;12:669–81.
[179] Roy M, Nelson JK, MacCrone RK, Schadler LS. Candidate mechanisms controlling the
electrical characteristics of silica/XLPE nanodielectrics. J Mater Sci 2007;42:3789–99.
[180] Kiley EM, Yakovlev VV. Applicability study of classical and contemporary models for
effective complex permittivity of metal powders. J Microw Power Electromagn Energy
2012;46:26–38.
[181] Simpkin R. Derivation of Lichtenecker’s logarithmic mixture formula from Maxwell’s
equations. IEEE Trans Microwave Theory Tech 2010;58:545–50.
[182] Zakri T, Laurent JP, Vauclin M. Theoretical evidence for ‘Lichtenecker’s mixture for-
mulae’ based on the effective medium theory. J Phys D Appl Phys 1998;31:1589–94.
[183] Koledintseva MY, DuBroff RE, Schwartz RW. Maxwell Garnett. Fort Belvoir, VA:
Defense Technical Information Center (DTIC); 2006.
[184] Sihvola A. Mixing rules with complex dielectric coefficients. Subsurf Sens Technol Appl
2000;1:393–415.
[185] Nan C-W. Physics of inhomogeneous inorganic materials. Prog Mater Sci
1993;37:1–116.
[186] Nan C-W. Comment on Effective dielectric function of a random medium. Matter Mater
Phys 2001;63:176201.
[187] Shivola AH. Self-consistency aspects of dielectric mixing theories. Geosci Remote Sens
1989;27:403–15.
[188] Wilkinson D, Langer JS, Sen PN. Enhancement of the dielectric constant near a perco-
lation threshold. Phys Rev B: Condens Matter Mater Phys 1983;28:1081–7.
[189] Calame JP. Finite difference simulations of permittivity and electric field statistics in
ceramic polymer composites for capacitor applications. J Appl Phys 2006;99:084101.
[190] Rahaman M, Chaki TK, Khastgir D. Modeling of DC conductivity for ethylene vinyl ace-
tate (EVA)/polyaniline conductive composites prepared through in situ polymerization
of aniline in EVA matrix. Compos Sci Technol 2012;72:1575–80.
[191] Dang Z-M, Nan C-W, Xie D, Zhang Y-H, Tjong SC. Dielectric behavior and dependence
of percolation threshold on the conductivity of fillers in polymer-semiconductor compos-
ites. Appl Phys Lett 2004;85:97–9.
[192] Balberg I, Azulay D, Toker D, Millo O. Percolation and tunneling in composite materials.
Int J Mod Phys B 2004;18:2091–121.
[193] Mao YP, Mao SY, Ye Z-G, Xie ZX, Zheng LS. Size-dependences of the dielectric and
ferroelectric properties of BaTiO 3 /polyvinylidene fluoride nanocomposites. J Appl Phys
2010;108:014102.
[194] Dang Z-M, Wang H-Y, Peng B, Nan C-W. Effect of BaTiO 3 size on dielectric property of
BaTiO 3 /PVDF composites. J Electroceram 2008;21:381–4.
[195] Liu S, Xue S, Zhang W, Zhai J. Enhanced dielectric and energy storage density induced
by surface-modified BaTiO 3 nanofibers in poly(vinylidene fluoride) nanocomposites.
Ceram Int 2014;40:15633–40.
