The Electro-Magnetic Properties of Combined Carbon Nanotubes and Carbon-Coated Iron Nanoparticles-Modified Polymer Composites
Abstract
Polymer based multifunctional material systems (MFMS) have gained increasing attention in the past two decades. The addition of nanofillers and nanoparticles allows for modification of physical properties as well as the discovery of new features. Multifunctionalization of composites allows us to “do more with less”. For example, electrically conductive additives can eliminate the need for sensors through self-sensing principles, shape morphing matrices can reduce the need for actuators, and the inclusion of fire-resistant constituents can reduce flammability in stringent fire protection measures. With added capabilities, the applications of multifunctional composites extends beyond the aerospace and automotive industries to healthcare, infrastructure, electronics, among others, and optics.The current state of the art is largely focused on single-filler composites or multifiller composites with complementary attributes. For example, carbon nanotubes (CNTs) when mixed with graphene produces higher conductivity than can be achieved via modification with either CNTs or graphene alone. The majority of investigations conducted in this domain have fillers selected with the aim of imparting a singular property. Much less has been done in the area of multifiller and multifunctional polymer matrix composites (PMCs) which can exhibit multiple properties. Consequently, this work seeks to contribute towards the field of synergisticfunctional composites. That is, a multifiller composite material system comprised of differently functional fillers. This approach has potential to yield smart material systems that outperform single-filler or single-functionality materials through the discovery of novel synergistic coupling between the differently functional phases.In light of the preceding motivation, this work presents the results on the experimental electromagnetic and mechanical characterization of multi-walled carbon nanotubes (MWCNTs) + carbon-coated iron nanoparticle (CCFeNP)-modified polymers. Carbon nanotubes with their electrical properties and iron nanoparticles with their magnetic attributes present potential for synergistic electromagnetic interactions in a well-percolated network. We report on the electro-magnetic properties of MWCNT + CCFeNP/epoxy composites including DC and AC conductivity, dielectric permittivity, magnetic permeability, and piezoresistance as a function of varying relative MWCNT and CCFeNP concentrations. The results are in a large part linked to the manufacturing process described herein. This work seeks to establish the foundations of synergistic functional filler combinations that could lead to new multifunctional capabilities in the future.
Degree
M.S.
Advisors
Tallman, Purdue University.
Subject Area
Optics|Electrical engineering|Electromagnetics|Energy|Engineering|Mechanics|Nanotechnology|Polymer chemistry
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