Thermal Degradation of Polymers to Polymeric Carbon—An Approach to the Synthesis of New Materials

Fitzer, E.

doi:10.1002/anie.198003751

Cited by 42 publications

(15 citation statements)

References 21 publications

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“…Structure shrinkage has been previously shown to depend on various factors including the type of polymer used as a carbon precursor [26] and amount of cross-linkage in the polymer matrix [27]. The results obtained here when pyrolyzing SU-8 pillars show a shrinkage percentage that is highly dependant on the initial dimensions of the pillars.…”

Section: Shrinkage Of Su-8 Structures During Pyrolysismentioning

confidence: 67%

A novel approach to dielectrophoresis using carbon electrodes

2011

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Carbon-electrode dielectrophoresis (carbon-DEP) is demonstrated here as an alternative to more traditional DEP techniques. Carbon-DEP combines advantages of metal-electrode and insulator-based DEP by using low-cost fabrication techniques and low voltages for particle manipulation. The use of 3-D electrodes is proved to yield significant advantages over the use of traditional planar electrodes. This paper details the fabrication of dense arrays of tall high aspect ratio carbon electrodes on a transparent fused-silica substrate. The shrinkage of the SU-8 structures during carbonization is characterized and a design tool for future devices is provided. Applications of carbon electrodes in DEP are then detailed and include particle positioning, high-throughput filtering and cell focusing using positive-DEP. Manipulated cells include Saccharomyces cerevisiae and Drosophila melanogaster. The advantages and disadvantages of carbon-DEP are discussed at the end of this work.

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Section: Shrinkage Of Su-8 Structures During Pyrolysismentioning

confidence: 67%

A novel approach to dielectrophoresis using carbon electrodes

2011

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“…If the char is resulted from degradation products of the polymer itself exposed to fire conditions, the amount of flammable volatiles evolved will be reduced, and the fire retardancy of the polymer is also improved. However, whether the char is generated from polymer itself is strongly dependent on the chemical structure of polymer 4, 5. Among polymers, carbonization of polyolefin is a real challenge due to its saturated hydrocarbon structure and formation of very flammable degradation products.…”

Section: Introductionmentioning

confidence: 99%

Strengthening Carbon Deposition of Polyolefin Using Combined Catalyst as a General Method for Improving Fire Retardancy

Song

Jiang

et al. 2008

Macromol. Rapid Commun.

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Combination of Ni2O3 and solid acid with Brønsted acid sites and Lewis acid sites (such as HZSM‐5 and H‐beta) could dramatically improve fire retardancy of polyolefin, including polypropylene and linear low‐density polyethylene. This is mainly attributed to the formation of a large amount of residual char from degradation products of polyolefin in the intermediate stage of combustion. Thus, the amount of flammable components diffusing into the flame zone was small. The investigation on the combined effect of solid acid and Ni2O3 showed that the presence of cationic reactive intermediates, mainly originating from Brønsted acid sites on the solid acid, strongly promoted carbon deposition of the degradation products. As a general method for improving fire retardancy of polyolefin, optimizing combination of metal catalyst and solid acid will further promote efficiency of fire retardancy.magnified image

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“…Indeed, previous studies have amply demonstrated that pyrolysis of carbonaceous materials inevitably leads to a distribution of structural topologies, composed of various interconnected clusters of aromatic rings [37][38][39]. For example, Wornat et al identified over 60 different species in their extensive analysis of volatile products of the pyrolysis of catechol [37], the majority of which were also observed in the M A N U S C R I P T A C C E P T E D ACCEPTED MANUSCRIPT 17 coal products [40].…”

Section: Determination Of F Armentioning

confidence: 99%

Quantitative atomic-scale structure characterization of ordered mesoporous carbon materials by solid state NMR

Wang

Opembe

Kobayashi

et al. 2018

Carbon

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Solid-state (SS)NMR techniques were applied to characterize the atomic-scale structures of ordered mesoporous carbon (OMC) materials prepared using Pluronic F127 as template with resorcinol and formaldehyde as polymerizing precursors. A rigorous quantitative analysis was developed using a combination of 13 C SSNMR spectra acquired with direct polarization and cross polarization on natural abundant and selectively 13 C-enriched series of samples pyrolyzed at various temperatures. These experiments identified and counted the key functional groups present in the OMCs at various stages of preparation and thermal treatment. The chemical evolution of molecular networks, the average sizes of aromatic clusters and the extended molecular structures of OMCs were then inferred by coupling this information with the elemental analysis results. Disciplines Materials Chemistry | Radiochemistry Comments This is a manuscript of an article published as Wang, Zhuoran, Naftali Opembe, Takeshi Kobayashi, Nicholas C. Nelson, Igor I. Slowing, and Marek Pruski. "Quantitative atomic-scale structure characterization of ordered mesoporous carbon materials by solid state NMR." Carbon (2018).

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Thermal Degradation of Polymers to Polymeric Carbon—An Approach to the Synthesis of New Materials

Cited by 42 publications

References 21 publications

A novel approach to dielectrophoresis using carbon electrodes

A novel approach to dielectrophoresis using carbon electrodes

Strengthening Carbon Deposition of Polyolefin Using Combined Catalyst as a General Method for Improving Fire Retardancy

Quantitative atomic-scale structure characterization of ordered mesoporous carbon materials by solid state NMR

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