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dc.contributor.authorRyan, Cecily A.
dc.contributor.authorBillington, Sarah L.
dc.contributor.authorCriddle, Craig S.
dc.date.accessioned2017-10-23T13:39:17Z
dc.date.available2017-10-23T13:39:17Z
dc.date.issued2017-07
dc.identifier.citationRyan, Cecily A., Sarah L. Billington, and Craig S. Criddle. "Biocomposite Fiber-Matrix Treatments that Enhance In-Service Performance Can Also Accelerate End-of-Life Fragmentation and Anaerobic Biodegradation to Methane." Journal of Polymers and the Environment (July 2107): 1-12. DOI: 10.1007/s10924-017-1068-4.en_US
dc.identifier.issn1572-8900
dc.identifier.urihttps://scholarworks.montana.edu/xmlui/handle/1/13829
dc.description.abstractBiodegradable resins can enhance the environmental sustainability of wood-plastic composites (WPCs) by enabling methane (CH4) recovery via anaerobic digestion (AD). An under appreciated step in biocomposite AD is the role of cracking and fragmentation due to moisture uptake by the wood fiber (WF) fraction. Here, we use batch microcosms to simulate AD at end-of-life and to assess the effects of fiber-matrix treatments used to retard in-service moisture uptake. The composites evaluated were injection molded poly(hydroxybutyrate-co-hydroxyvalerate) (PHBV) with WF (0, 20%) using two fiber-matrix compatibilization treatments: (1) hydrophobic silane treatment of the wood fiber and (2) grafting of hydrophilic maleic anhydride groups to the PHBV matrix. Both treatments accelerated rates of mass loss and CH4 production by a factor of 1.2–2.3 compared to neat PHBV. The fragmentation rate, as measured by mass loss, increased significantly for treated samples compared to untreated samples. A ranking of test samples from lowest to highest rates of mass loss gave the following sequence: neat PHBV ≈ maleated PHBV < PHBV plus untreated WF < maleated PHBV plus untreated WF < PHBV plus silane-treated WF. Compared to the untreated samples, maleic anhydride treatment increased the mass loss rate by 30%, and silane treatment increased the mass loss rate by 92%. Onset of cracking in silane-treated composites was observed at 2 weeks (using X-ray micro-computed tomography). At the same time, solid mass loss and CH4 production peaked, implicating cracking and physical disintegration as the rate-limiting step for accelerated anaerobic degradation. When modified to account for bioplastic matrix degradation, a previously derived moisture-induced damage model could predict the onset of composite fragmentation at end-of-life. These results are significant for design of bio-WPCs and demonstrate that treatments designed to improve in-service performance can also improve end-of-life options.en_US
dc.description.sponsorshipBioProcess Control; SeaHold LLC; Team Biogas ;NSF CMMI [Grant 0900325]; California EPA Department of Toxic Substances Control [Project Ref. No. 07T3451]; CalRecycle [Contract No. DRRR10020]en_US
dc.titleBiocomposite Fiber-Matrix Treatments that Enhance In-Service Performance Can Also Accelerate End-of-Life Fragmentation and Anaerobic Biodegradation to Methaneen_US
mus.citation.extentfirstpage1en_US
mus.citation.extentlastpage12en_US
mus.citation.journaltitleJournal of Polymers and the Environmenten_US
mus.identifier.categoryLife Sciences & Earth Sciencesen_US
mus.identifier.doi10.1007/s10924-017-1068-4en_US
mus.relation.collegeCollege of Engineeringen_US
mus.relation.departmentMechanical & Industrial Engineering.en_US
mus.relation.universityMontana State University - Bozemanen_US
mus.data.thumbpage3en_US


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