Putman, Kate J. scite author profile

Putman, Kate J.

5Publications

38Citation Statements Received

125Citation Statements Given

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Curtin University

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Catalysis-free transformation of non-graphitising carbons into highly crystalline graphite

Fogg

Zhang

et al. 2020

Commun Mater

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High-purity graphite is a sought-after material for lithium-ion batteries and graphene production. Most organic materials do not graphitise upon heating unless a metal catalyst is present. The catalyst becomes embedded in the graphite and is difficult to remove. Here, we present a catalysis-free technique capable of producing highly crystalline graphite from materials generally considered incapable of this transformation. Using the furnace inside an Atomic Absorption Spectrometer, we perform repeated high-temperature pulsing of polyvinylidene chloride followed by analysis with Raman, X-ray diffraction and transmission electron microscopy. Unexpectedly,~90% of the sample transforms into highly ordered graphite with very few defects. A combustion route is proposed in which oxygen attacks the structural units that inhibit graphitisation. We apply the same approach to cellulose and obtain ten times more ordered material than conventional furnaces, confirming that polyvinylidene chloride is not an isolated case. Potentially, this method could be used to synthesise graphite from any organic material, including waste sources such as biomass.

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Pulsed thermal treatment of carbon up to 3000 °C using an atomic absorption spectrometer

Sofianos

Rowles

et al. 2018

Carbon

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Electrochemically Controlled Deposition of Ultrathin Polymer Electrolyte on Complex Microbattery Electrode Architectures

Abdelhamid

Rüther

Veder

et al. 2019

J. Electrochem. Soc.

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Solid state microbatteries are highly sought after for emerging microsensor technologies. To overcome the problem of the dwarfing capacity resulting from the miniaturization of the battery, 3D-structured platform consisting of high surface area micropillar-shaped electrodes are used. However, applying a conformal and continuous solid polymer electrolyte films onto the intricate 3D electrodes is a crucial step toward achieving functional microbatteries. In this work, we present our approach for the development of polyethylene oxide (PEO)-acrylate based ion conducting polymer thin films which function as solid polymer electrolyte (SPE) and a separator. The SPEs were electrochemically deposited on the 3D electrodes resulting in ultrathin, continuous, conformal, and pinhole-free polymer films. The electrochemical and Li + ions transport properties of the SPEs were characterized by EIS measurements and cyclic voltammetry. Furthermore, the homogenous composition of the SPEs at various depths were confirmed by XPS depth profiling techniques.

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Defining graphenic crystallites in disordered carbon: Moving beyond the platelet model

Rowles

Marks

et al. 2023

Carbon

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The behaviour of arcs in carbon mixed-mode high-power impulse magnetron sputtering

Tucker

Ganesan

et al. 2017

J. Phys. D: Appl. Phys.

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Putman, Kate J.

Catalysis-free transformation of non-graphitising carbons into highly crystalline graphite

Pulsed thermal treatment of carbon up to 3000 °C using an atomic absorption spectrometer

Electrochemically Controlled Deposition of Ultrathin Polymer Electrolyte on Complex Microbattery Electrode Architectures

Defining graphenic crystallites in disordered carbon: Moving beyond the platelet model

The behaviour of arcs in carbon mixed-mode high-power impulse magnetron sputtering

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About

Putman, Kate J.

Catalysis-free transformation of non-graphitising carbons into highly crystalline graphite

Pulsed thermal treatment of carbon up to 3000 °C using an atomic absorption spectrometer

Electrochemically Controlled Deposition of Ultrathin Polymer Electrolyte on Complex Microbattery Electrode Architectures

Defining graphenic crystallites in disordered carbon: Moving beyond the platelet model

The behaviour of arcs in carbon mixed-mode high-power impulse magnetron sputtering

Contact Info

Product

Resources

About

Pulsed thermal treatment of carbon up to 3000 °C using an atomic absorption spectrometer