The Facile and Efficient Fabrication of Rice Husk/poly (lactic acid) Foam Composites by Coordinated the Interface Combination and Bubble Hole Structure.
暂无分享,去创建一个
Jiaxun Liu | Beibei Wang | Yao Pang | Yi Liu | H. Guo | Weiye Zhang | Jingmeng Sun | Liang Xu | Zonglin Zhao
[1] Yufeng Sun,et al. PLA composites reinforced with rice residues or glass fiber—a review of mechanical properties, thermal properties, and biodegradation properties , 2022, Journal of Polymer Research.
[2] V. Abetz,et al. Polylactic acid nanocomposites containing functionalized multiwalled carbon nanotubes as antimicrobial packaging materials. , 2022, International journal of biological macromolecules.
[3] P. Olupot,et al. Thermal stability of unmodified and alkali-modified rice husks for flame retardant fiber-reinforced PLA composites , 2022, Journal of Thermal Analysis and Calorimetry.
[4] Junqi Zhao,et al. High interface compatibility and phase change enthalpy of heat storage wood plastic composites as bio-based building materials for energy saving , 2022, Journal of Energy Storage.
[5] M. Madhoushi,et al. Influence of spherical-shaped carbon nanoparticles on the mechanical properties of a foamed sugarcane bagasse/polypropylene composite , 2021, Industrial Crops and Products.
[6] Guangxian Li,et al. Heat insulating PLA/HNTs foams with enhanced compression performance fabricated by supercritical carbon dioxide , 2021 .
[7] I. Ahmad,et al. Comprehensive exploration of natural degradation of poly(lactic acid) blends in various degradation media: A review. , 2021, International journal of biological macromolecules.
[8] Wei Yang,et al. Recent progress on chemical modification of cellulose for high mechanical-performance Poly(lactic acid)/Cellulose composite: A review , 2021 .
[9] L. Turng,et al. Improving Polylactide Toughness by Plasticizing with Low Molecular Weight Polylactide-Poly(Butylene Succinate) Copolymer , 2021 .
[10] Y. Alias,et al. Efficiency of bronsted acidic ionic liquids in the dissolution and depolymerization of lignin from rice husk into high value-added products , 2020 .
[11] V. Jittin,et al. Potential of sugarcane bagasse ash as supplementary cementitious material and comparison with currently used rice husk ash , 2020 .
[12] Caili Zhang,et al. Enhancing gas barrier performance of polylactic acid/lignin composite films through cooperative effect of compatibilization and nucleation , 2020 .
[13] Hao Wang,et al. Current applications of poly(lactic acid) composites in tissue engineering and drug delivery , 2020 .
[14] Vikram Kumar,et al. Effect of gamma irradiation on tensile and thermal properties of poplar wood flour-linear low density polyethylene composites , 2020 .
[15] Lingling Hu,et al. Sustainable use of rice husk ash in cement-based materials: Environmental evaluation and performance improvement , 2020 .
[16] F. Liu,et al. Facile Fabrication of Lightweight Shape Memory Thermoplastic Polyurethane/Polylactide Foams by Supercritical Carbon Dioxide Foaming , 2020 .
[17] Guo-ren Xu,et al. Pyrolysis characteristics, kinetics and evolved volatiles determination of rice-husk-based distiller's grains , 2020 .
[18] A. Sulong,et al. Fabrication of Porous Recycled HDPE Biocomposites Foam: Effect of Rice Husk Filler Contents and Surface Treatments on the Mechanical Properties , 2020, Polymers.
[19] M. Nofar,et al. Ductility improvements of PLA-based binary and ternary blends with controlled morphology using PBAT, PBSA, and nanoclay , 2020 .
[20] Y. Son,et al. Enhanced impact strength of compatibilized poly(lactic acid)/polyamide 11 blends by a crosslinking agent , 2020 .
[21] N. Petchwattana,et al. Combination effects of reinforcing filler and impact modifier on the crystallization and toughening performances of poly(lactic acid) , 2020, Express Polymer Letters.
[22] Y. Ruksakulpiwat,et al. Effect of cellulose nanofibers from cassava pulp on physical properties of poly(lactic acid) biocomposites , 2020, Journal of Thermoplastic Composite Materials.
[23] Carlos Segovia Fernández,et al. Critical aspects in the handling of reactive silica in cementitious materials: Effectiveness of rice husk ash vs nano-silica in mortar dosage , 2019, Construction and Building Materials.
[24] Zhanying Sun,et al. Effects of sol-gel modification on the interfacial and mechanical properties of sisal fiber reinforced polypropylene composites , 2019, Industrial Crops and Products.
[25] P. Olupot,et al. Effect of Alkaline Surface Modification and Carbonization on Biochemical Properties of Rice and Coffee Husks for Use in Briquettes and Fiber-Reinforced Plastics , 2019, Journal of Natural Fibers.
[26] Guoqun Zhao,et al. A green strategy to regulate cellular structure and crystallization of poly(lactic acid) foams based on pre-isothermal cold crystallization and CO2 foaming. , 2019, International journal of biological macromolecules.
[27] Y. H. Li,et al. Improved fracture toughness and ductility of PLA composites by incorporating a small amount of surface-modified helical carbon nanotubes , 2019, Composites Part B: Engineering.
[28] M. Nofar,et al. Rheology of poly (lactic acid)-based systems , 2019, Polymer Reviews.
[29] P. Carreau,et al. Poly (lactic acid) blends: Processing, properties and applications. , 2019, International journal of biological macromolecules.
[30] Chi-Hui Tsou,et al. Fabrication, characterization, and application of biocomposites from poly(lactic acid) with renewable rice husk as reinforcement , 2019, Journal of Polymer Research.
[31] S. Sapuan,et al. Natural fiber reinforced polylactic acid composites: A review , 2019 .
[32] L. Ye,et al. In situ preparation of intrinsic flame retardant urea formaldehyde/aramid fiber composite foam: Structure, property and reinforcing mechanism , 2018, Composites Part A: Applied Science and Manufacturing.
[33] Xiaojian Gao,et al. Recycling of raw rice husk to manufacture magnesium oxysulfate cement based lightweight building materials , 2018, Journal of Cleaner Production.
[34] E. Siswanto,et al. Characterization of the Chemical, Physical, and Mechanical Properties of NaOH-treated Natural Cellulosic Fibers from Corn Husks , 2018 .
[35] Min Liu,et al. Comparison of six WPCs made of organo-montmorillonite-modified fibers of four trees, moso bamboo and wheat straw and poly(lactic acid) (PLA) , 2018 .
[36] K. Palanikumar,et al. Plant fibre based bio-composites: Sustainable and renewable green materials , 2017 .
[37] A. J. Zattera,et al. Poly(lactic acid) foams reinforced with cellulose micro and nanofibers and foamed by chemical blowing agents , 2017 .
[38] M. Fan,et al. Investigation of bulk and in situ mechanical properties of coupling agents treated wood plastic composites , 2017 .
[39] Yuanfeng Pan,et al. Preparation and Characterization of Epoxy Resin Cross-Linked with High Wood Pyrolysis Bio-Oil Substitution by Acetone Pretreatment , 2017, Polymers.
[40] H. Yazıcı,et al. Feasibility of Using Foamed Styrene Maleic Anhydride (SMA) Co-polymer in Wood Based Composites , 2017 .
[41] A. N. Nakagaito,et al. Effect of alkali treatment on interfacial bonding in abaca fiber-reinforced composites , 2016 .
[42] Farkhondeh Hemmati,et al. Microstructure and thermal stability of polypropylene/bagasse composite foams , 2016 .
[43] Qian Wang,et al. Study on the synergistic co-pyrolysis behaviors of mixed rice husk and two types of seaweed by a combined TG-FTIR technique , 2015 .
[44] Shanhui Zhao,et al. Experimental Investigation of Rice Straw and Model Compound Oxidative Pyrolysis by in Situ Diffuse Reflectance Infrared Fourier Transform and Coupled Thermogravimetry–Differential Scanning Calorimetry/Mass Spectrometry Method , 2015 .
[45] J. Benezet,et al. Rice and Einkorn wheat husks reinforced poly(lactic acid) (PLA) biocomposites: Effects of alkaline and silane surface treatments of husks , 2014 .
[46] Chi-Hui Tsou,et al. Crystallisation behaviour and biocompatibility of poly(butylene succinate)/poly(lactic acid) composites , 2014 .
[47] V. Thakur,et al. Progress in Green Polymer Composites from Lignin for Multifunctional Applications: A Review , 2014 .
[48] T. Kuboki. Foaming behavior of cellulose fiber-reinforced polypropylene composites in extrusion , 2014 .
[49] Zhenxiang Xin,et al. Effects of compatibilizers on the physico‐mechanical and foaming properties of polyproylene/wood‐fiber composites , 2013 .
[50] L. Matuana,et al. Strategy To Produce Microcellular Foamed Poly(lactic acid)/Wood-Flour Composites in a Continuous Extrusion Process , 2013 .
[51] Zhixiang Cui,et al. Processing and characterization of solid and microcellular poly(lactic acid)/polyhydroxybutyrate-valerate (PLA/PHBV) blends and PLA/PHBV/Clay nanocomposites , 2013 .
[52] S. M. B. Nachtigall,et al. Effect of chemical and physical foaming additives on the properties of PP/wood flour composites , 2013 .
[53] Chul B. Park,et al. Continuous processing of low-density, microcellular poly(lactic acid) foams with controlled cell morphology and crystallinity , 2012 .
[54] Chul B. Park,et al. Mechanism of extensional stress-induced cell formation in polymeric foaming processes with the presence of nucleating agents , 2012 .
[55] A. Ashori,et al. Effect of extractives on the performance properties of wood flour‐polypropylene composites , 2012 .
[56] R. Rowell,et al. Cold plasma treatment on starch foam reinforced with wood fiber for its surface hydrophobicity , 2011 .
[57] A. Hassan,et al. Comparison of Polylactic Acid/Kenaf and Polylactic Acid/Rise Husk Composites: The Influence of the Natural Fibers on the Mechanical, Thermal and Biodegradability Properties , 2010 .
[58] Luc Avérous,et al. Nano-biocomposites: Biodegradable polyester/nanoclay systems , 2009 .
[59] L. Lim,et al. Processing technologies for poly(lactic acid) , 2008 .
[60] Q.W. Wang,et al. Compatibilizing Effect of Maleic Anhydride Grafted Styrene-Ethylene-Butylene-Styrene (MAH-g-SEBS) on the Polypropylene and Wood Fiber Composites , 2007 .
[61] A. McDonald,et al. The effect of silane coupling agents on radiata pine fibre for use in thermoplastic matrix composites , 2003 .
[62] L. Matuana,et al. Foam extrusion of high density polyethylene/wood-flour composites using chemical foaming agents , 2003 .