Graft Polymerization of Acrylic Monomers onto Lignin with CaCl2–H2O2 as Initiator: Preparation, Mechanism, Characterization, and Application in Poly(lactic acid)

Zong, Enmin; Liu, Xiaohuan; Liu, Lina; Wang, Jifu; Song, Pingan; Ma, Zhongqing; Ding, Jie; Fu, Shenyuan

doi:10.1021/acssuschemeng.7b02599

Cited by 69 publications

(57 citation statements)

References 45 publications

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“…The use of free radical graft polymerization on lignin novel materials has been carried out in various applications, such as in composites [63], cationic flocculants [64,65], binder in lithium-ion batteries [66], heavy metal ion biosorption [67], anticancer [68], UV-absorbent films [69], and corrosion inhibition [70].…”

Section: Lignin-derived Polymersmentioning

confidence: 99%

Lignin Biopolymers in the Age of Controlled Polymerization

2019

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Polymers made from natural biomass are gaining interest due to the rising environmental concerns and depletion of petrochemical resources. Lignin isolated from lignocellulosic biomass is the second most abundant natural polymer next to cellulose. The paper pulp process produces industrial lignin as a byproduct that is mostly used for energy and has less significant utility in materials applications. High abundance, rich chemical functionalities, CO2 neutrality, reinforcing properties, antioxidant and UV blocking abilities, as well as environmental friendliness, make lignin an interesting substrate for materials and chemical development. However, poor processability, low reactivity, and intrinsic structural heterogeneity limit lignins′ polymeric applications in high-performance advanced materials. With the advent of controlled polymerization methods such as ATRP, RAFT, and ADMET, there has been a great interest in academia and industry to make value-added polymeric materials from lignin. This review focuses on recent investigations that utilize controlled polymerization methods to generate novel lignin-based polymeric materials. Polymers developed from lignin-based monomers, various polymer grafting technologies, copolymer properties, and their applications are discussed.

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Section: Lignin-derived Polymersmentioning

confidence: 99%

Lignin Biopolymers in the Age of Controlled Polymerization

2019

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“…However, strong intermolecular interactions were detected using differential scanning calorimetry (DSC) and FT‐IR spectroscopy, concluding that hydrogen bonds between the phenolic hydroxyl groups of lignin and the carbonyl groups of PLA were formed . The compatibility of such blends could be enhanced via reactive grafting of either PLA copolymers or acrylic monomers onto lignin.…”

Section: Lignocellulosic Biomassmentioning

confidence: 99%

Natural Polymers from Biomass Resources as Feedstocks for Thermoplastic Materials

Müller

Zollfrank

Schmid

2019

Macro Materials & Eng

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With the objective of a more sustainable circular economy, one long‐term goal is the utilization of renewable resources as feedstock for the production of polymer‐based materials. In order to successfully process such materials using existing industrial‐scale technologies or even recycling processes, the natural polymers must have thermoplastic properties. With only a few exceptions, natural polymers are not thermoplastic. However, chemical and physical modification techniques are able to induce thermoplasticity in natural polymers from biomass resources such as cellulose, lignin, and chitin. Modification techniques focus on masking the hydroxyl groups to disrupt dense hydrogen bonding and so enable polymer chain mobility upon heating. The introduction of long alkyl chains into the polymer backbone effectively improves the thermoplastic processing of natural polymers. With regard to polymer blending, chemical grafting and graft copolymerization are powerful tools for enhancing compatibility. For both chemical and physical modification, solvents such as ionic liquids and deep eutectic solvents are currently being explored for biomass and fiber processing and show promise for the future development of thermoplastic biopolymers. This review describes possible modifications, potential processing difficulties, and gives a summary of relevant studies described in the scientific literature.

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“…1 Out of the myriads of bio-based polymers, polylactic acid (PLA) is strategically important due to its excellent mechanical properties, biocompatibility, renewability, biodegradability, easy dyeability, and above all, low cost. [2][3][4] Interestingly, PLA is now applicable in areas such as cable insulators, furnishings, high-end fashion items, building and construction, automobiles, and packaging. [5][6][7] Despite the enormous potentials of PLA, notable setbacks such as low thermal resistance, heat distortion temperature and high flammability accompanied by severe melt dripping limits its applications in certain fields.…”

Section: Introductionmentioning

confidence: 99%

Facile preparation of uniform polydopamine particles and its application as an environmentally friendly flame retardant for biodegradable polylactic acid

Tawiah

Yuen

et al. 2020

Journal of Fire Sciences

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The demand for environmentally benign flame retardants for biodegradable polymers has become particularly necessary due to their inherently “green” nature. This work reports intrinsically non-toxic polydopamine (PDA) particles as an efficient and environmentally friendly flame retardant for polylactic acid (PLA). 5 wt% PDA loading resulted in a 22% reduction in the peak heat release rate, 34.7% increase in the fire performance index, and lower CO2 production compared to neat PLA. A limiting oxygen index (LOI) value of 27.5% and a V-2 rating was achieved in the UL-94 vertical burning test. Highly aggregated amorphous particulate char was formed with the increasing content of PDA, and a significant reduction in evolved pyrolysis gaseous products was achieved for the PLA/PDA composites as compared with control PLA. This work provides important insight into the potential commercial application of PDA alone as an efficiently green, environmentally benign flame retardant for bioplastic PLA.

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Graft Polymerization of Acrylic Monomers onto Lignin with CaCl₂–H₂O₂ as Initiator: Preparation, Mechanism, Characterization, and Application in Poly(lactic acid)

Cited by 69 publications

References 45 publications

Lignin Biopolymers in the Age of Controlled Polymerization

Lignin Biopolymers in the Age of Controlled Polymerization

Natural Polymers from Biomass Resources as Feedstocks for Thermoplastic Materials

Facile preparation of uniform polydopamine particles and its application as an environmentally friendly flame retardant for biodegradable polylactic acid

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