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Alison M. Funston
Researcher at Monash University, Clayton campus
Publications - 83
Citations - 6802
Alison M. Funston is an academic researcher from Monash University, Clayton campus. The author has contributed to research in topics: Plasmon & Surface plasmon. The author has an hindex of 32, co-authored 72 publications receiving 6201 citations. Previous affiliations of Alison M. Funston include University of Melbourne & Brookhaven National Laboratory.
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Spectroscopy and transport of the triplet exciton in a terthiophene end-capped poly(phenylene ethynylene).
TL;DR: Triplet states of poly(phenylene ethynylene), (3)PPE(*), not easily formed by direct photoexcitation, were produced by pulse radiolysis in toluene, along with triplet states of T(3) PPE having terthiophene end-caps, determined in bimolecular energy transfer equilibria.
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Synthesis, structural studies and photochemistry of cobalt(III) complexes of anthracenylcyclam macrocycles
TL;DR: In this paper, the synthesis, structures and photochemistry of trans-[CoIII(2)Cl2]Cl·0.5CH3H2O and trans[Co III(3)Cl 2]Cl 2H2H 2O were reported.
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Plasmonics by design: design principles to structure–function relationships with assemblies of metal nanoparticles
TL;DR: In this paper, a simple and analytical theoretical method, namely the Electrostatic Eigenmode Method (EEM), can be used for designing or interpreting the phenomena that results from plasmon coupling.
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Topologically Enclosed Aluminum Voids as Plasmonic Nanostructures.
TL;DR: The localized surface plasmon resonances (LSPRs) of nanovoids that are topologically enclosed in three-dimensions are revealed: an "anti-nanoparticle" of aluminum, well beyond those accessible with noble metals or yet achieved with aluminum.
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Electron energy loss spectroscopy for polymers: a review
TL;DR: An extensive review of electron energy loss spectroscopy for polymeric systems is presented in this paper, where issues related to appropriate sample preparation and beam degradation of polymers are addressed and advantages of EELS to achieve spectroscopic characterization of polymer systems with high spatial resolution are highlighted.