Mechanochemical Transformations of Biomass into Functional Materials

Moores, Audrey; Hajiali, Faezeh; Jin, Tony; Yang, Galen; Santos, Madison; Lam, Edmond

doi:10.1002/cssc.202102535

Cited by 30 publications

(24 citation statements)

References 512 publications

(911 reference statements)

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“…In addition to the manipulation of manufactured polymers, ball milling techniques have also been reported to facilitate the depolymerization of biopolymers [35]. On the one hand, the implementation of solvent-free ball milling has enabled to surpass the insolubility and recalcitrant reactivity of cellulose [36,37], chitin [38,39], and lignin (Figure 2) [40,41].…”

Section: Depolymerization Of Biomacromolecules By Mechanical Forcementioning

confidence: 99%

Polymer and small molecule mechanochemistry: closer than ever

Hernández¹

2022

Beilstein J. Org. Chem.

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The formation and scission of chemical bonds facilitated by mechanical force (mechanochemistry) can be accomplished through various experimental strategies. Among them, ultrasonication of polymeric matrices and ball milling of reaction partners have become the two leading approaches to carry out polymer and small molecule mechanochemistry, respectively. Often, the methodological differences between these practical strategies seem to have created two seemingly distinct lines of thought within the field of mechanochemistry. However, in this Perspective article, the reader will encounter a series of studies in which some aspects believed to be inherently related to either polymer or small molecule mechanochemistry sometimes overlap, evidencing the connection between both approaches.

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Section: Depolymerization Of Biomacromolecules By Mechanical Forcementioning

confidence: 99%

Polymer and small molecule mechanochemistry: closer than ever

Hernández¹

2022

Beilstein J. Org. Chem.

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Section: Figurementioning

confidence: 99%

“…Mechanochemistry is rapidly establishing itself as an effective tool to cut on solvent/aqueous waste, [17,18] and it has been explored for the valorization of biomass, in the context of biopolymers deconstruction [19] and functional materials fabrication. [20,21] It is commonly used as pre-treatment to solution-based chemical methods, as a physical means to break bonds. Mechanochemical processes have been used for nanopolysaccharide production, yet are still challenged by the need for heat, solvents, and multiple reaction steps leading to sub-optimal yields and nanomaterial properties, including crystallinity and dispersibility.…”

Section: Introductionmentioning

confidence: 99%

High‐Humidity Shaker Aging to Access Chitin and Cellulose Nanocrystals**

et al. 2022

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To unlock nature's potential for functional biomaterials, many efforts have been devoted to isolating the nanocrystalline domains within the supramolecular structure of polysaccharides. Yet, low reactivity and yield in aqueous systems along with excessive solvent usage hinders its development. In this report, the first solvent‐free pathway to access carboxylated chitin and cellulose nanocrystals with excellent mass balance is described, relying on a new method coined high‐humidity shaker aging (HHSA). The method involves a mild grinding of the polysaccharide with ammonium persulfate followed by an aging phase under high‐humidity and on a shaker plate. Insights into the mechanism were uncovered, which highlighted the unique role of high humidity to afford a gradual uptake of water by the material up to deliquescence when the reaction is complete. This process was then validated for direct synthesis of nanocrystals from biomass sources including crab and soft wood pulp.

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“…28,41 In this context, mechanochemistry appears as a great tool to explore the valorization of biomass with lean energy and material usage. 42,43 Mechanochemistry consists of the use of mechanical milling or shearing to induce chemical reactions and has emerged as an important method to conduct chemical transformations in either the complete absence of solvents 44−46 or the presence of a small amount of liquid (i.e., liquid-assisted grinding, LAG). 47−49 It addresses issues related to solubility, separation, and selectivity, while reducing the overall effluents and energy demands.…”

Section: ■ Introductionmentioning

confidence: 99%

“…In this context, mechanochemistry appears as a great tool to explore the valorization of biomass with lean energy and material usage. , Mechanochemistry consists of the use of mechanical milling or shearing to induce chemical reactions and has emerged as an important method to conduct chemical transformations in either the complete absence of solvents − or the presence of a small amount of liquid (i.e., liquid-assisted grinding, LAG). − It addresses issues related to solubility, separation, and selectivity, while reducing the overall effluents and energy demands . In this context, solid-state aging has also emerged as a low-energy and “solvent-free” alternative to solution-based methods for the production of organic and inorganic materials. − Our group has previously investigated and developed methods based on mechanochemistry and aging for the transformation and functionalization of polymers while preserving their chain structure. − In the specific context of crustacean waste valorization, Yan and Kerton’s groups have explored the use of mechanochemistry for the deacetylation of chitin into chitosan − and our group a combination of mechanochemistry and aging. − However, the use of these methods for chitin extraction remains unexplored.…”

Section: Introductionmentioning

confidence: 99%

Extraction of Chitin from Green Crab Shells by Mechanochemistry and Aging

Hajiali

Vidal

Jin

et al. 2022

ACS Sustainable Chem. Eng.

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Crustacean shell waste is one of the most important chitin sources for commercial use due to its low price and high availability. The extraction of chitin from this residue relies on two removal steps: one for proteins and another one for minerals. Herein, we report a "solvent-free", one-pot process relying on mechanochemistry and aging to convert crustacean shells into chitin with high yields and low ash content. The extraction was performed on European Green Crabs, one of the world's most damaging invasive species, thus converting a serious environmental threat into a biomaterial opportunity. Successful chitin isolation of Green Crabs was achieved by milling of solid acids (i.e., citric, ascorbic, malic, succinic, and salicylic acid) for 10 to 30 min, while a combination of milling and aging was necessary for aqueous acids (i.e., hydrochloric and acetic acid). Milling, aging times, and shell to acid ratios were optimized, while the process could be scaled to 200 g of shell starting materials. This method required limited chemical and energy inputs, which were quantified by sustainability metrics. The process reported is a more sustainable approach for chitin production over the current industrial methods and has the potential to be extended to other chitin sources (e.g., lobster, shrimp, and insects).

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Mechanochemical Transformations of Biomass into Functional Materials

Abstract: This publication is part of a joint Special Collection of Chemistry -Methods and ChemSusChem including invited contributions focusing on "Methods and Applications in Mechanochemistry". Please visit chemsuschem.org/ collections to view all contributions.

Cited by 30 publications

References 512 publications

Polymer and small molecule mechanochemistry: closer than ever

Polymer and small molecule mechanochemistry: closer than ever

High‐Humidity Shaker Aging to Access Chitin and Cellulose Nanocrystals**

Extraction of Chitin from Green Crab Shells by Mechanochemistry and Aging

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