Biobased Carbon Fibers and Thermosetting Resins for Use in DOD Composites Applications: SERDP WP 1758 Final Report

Current constituent materials used to produce composites for the military are often made from both fibers and resins that are derived from petrochemical feedstocks. The use of biological resources to make advanced fibers and high-performance thermosetting resins will help reduce the dependence of mi...

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Hauptverfasser:	La Scala, John J, Sadler,Joshua, Toulan,Faye R, Lam,Anh-Phuong, Annunziato,Christopher, Ogale,Amod, Zhang,Meng, Greene,Annel, Chambers,Steven, Stanzione,Joseph III, Reno,Kaleigh, Wool,Richard, Hu,Fengshuo, Hernandez,Eric, Koo,Donghun, Palmese,Giuseppe
Format:	Report
Sprache:	eng
Schlagworte:	alkenes CARBON FIBERS chemical reaction properties environmentally friendly fatty acids fiber spinning lignin material degradation processes materials processing plant oils Polymer Chemistry polymeric films renewable resources thermoset THERMOSETTING PLASTICS
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creator	La Scala, John J Sadler,Joshua Toulan,Faye R Lam,Anh-Phuong Annunziato,Christopher Ogale,Amod Zhang,Meng Greene,Annel Chambers,Steven Stanzione,Joseph III Reno,Kaleigh Wool,Richard Hu,Fengshuo Hernandez,Eric Koo,Donghun Palmese,Giuseppe
description	Current constituent materials used to produce composites for the military are often made from both fibers and resins that are derived from petrochemical feedstocks. The use of biological resources to make advanced fibers and high-performance thermosetting resins will help reduce the dependence of military composites on the volatile cost of petroleum, result insignificant technological gains, and reduce toxicity of composite materials. We have used both bacterial and chemical decomposition of lignin to make tractable structures that are capable of fiber spinning. Efforts to stabilize and carbonize lignin have resulted in the highest-performing lignin-based carbon fibers to date. However, new developments in commercial polyacrylonitrile-carbon fiber technology have eliminated the need for lignin-based carbon fibers altogether. Unsaturated polyester, vinyl ester, epoxy, and polyurethane resin thermosets have been developed. Isosorbide-based vinyl ester resins have the highest-ever glass transition temperatures for a vinyl ester system. Bisguaiacol F has very promising properties as a replacement for bisphenol A with significantly reduced toxicity. Furan epoxies have shown high promise with good thermal properties and excellent toughness. Many of these resin systems have low costs and even lower life cycle costs relative to commercial resins, and thus they have good potential for transition to commercial industry.
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The use of biological resources to make advanced fibers and high-performance thermosetting resins will help reduce the dependence of military composites on the volatile cost of petroleum, result insignificant technological gains, and reduce toxicity of composite materials. We have used both bacterial and chemical decomposition of lignin to make tractable structures that are capable of fiber spinning. Efforts to stabilize and carbonize lignin have resulted in the highest-performing lignin-based carbon fibers to date. However, new developments in commercial polyacrylonitrile-carbon fiber technology have eliminated the need for lignin-based carbon fibers altogether. Unsaturated polyester, vinyl ester, epoxy, and polyurethane resin thermosets have been developed. Isosorbide-based vinyl ester resins have the highest-ever glass transition temperatures for a vinyl ester system. Bisguaiacol F has very promising properties as a replacement for bisphenol A with significantly reduced toxicity. 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The use of biological resources to make advanced fibers and high-performance thermosetting resins will help reduce the dependence of military composites on the volatile cost of petroleum, result insignificant technological gains, and reduce toxicity of composite materials. We have used both bacterial and chemical decomposition of lignin to make tractable structures that are capable of fiber spinning. Efforts to stabilize and carbonize lignin have resulted in the highest-performing lignin-based carbon fibers to date. However, new developments in commercial polyacrylonitrile-carbon fiber technology have eliminated the need for lignin-based carbon fibers altogether. Unsaturated polyester, vinyl ester, epoxy, and polyurethane resin thermosets have been developed. Isosorbide-based vinyl ester resins have the highest-ever glass transition temperatures for a vinyl ester system. Bisguaiacol F has very promising properties as a replacement for bisphenol A with significantly reduced toxicity. Furan epoxies have shown high promise with good thermal properties and excellent toughness. Many of these resin systems have low costs and even lower life cycle costs relative to commercial resins, and thus they have good potential for transition to commercial industry.</abstract><oa>free_for_read</oa></addata></record>
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subjects	alkenes CARBON FIBERS chemical reaction properties environmentally friendly fatty acids fiber spinning lignin material degradation processes materials processing plant oils Polymer Chemistry polymeric films renewable resources thermoset THERMOSETTING PLASTICS
title	Biobased Carbon Fibers and Thermosetting Resins for Use in DOD Composites Applications: SERDP WP 1758 Final Report
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