Lignin-Derived Quinone Redox Moieties for Bio-Based Supercapacitors

Jyothibasu, Jincy Parayangattil; Wang, Ruei-Hong; Tien, You-Ching; Kuo, Chi‐Ching; Lee, Rong-Ho

doi:10.3390/polym14153106

Cited by 18 publications

(9 citation statements)

References 86 publications

(100 reference statements)

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“…Recent studies and reviews have concentrated on the electrochemical applications of lignin, such as supercapacitors and electrodes. 21 , 22 , 23 Oxidative depolymerization has been shown to transform lignin into different quinone-like structures, 24 which are key compounds for the electrochemical reactions that take place within a battery. 22 …”

Section: Lignin Transformationmentioning

confidence: 99%

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Recent strides toward transforming lignin into plastics and aqueous electrolytes for flow batteries

Abdelaziz,

Vives,

Mankar

et al. 2024

iScience

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Section: Lignin Transformationmentioning

confidence: 99%

“… 21 , 22 , 23 Oxidative depolymerization has been shown to transform lignin into different quinone-like structures, 24 which are key compounds for the electrochemical reactions that take place within a battery. 22 …”

Section: Lignin Transformationmentioning

confidence: 99%

Recent strides toward transforming lignin into plastics and aqueous electrolytes for flow batteries

Abdelaziz,

Vives,

Mankar

et al. 2024

iScience

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“…Lignocellulosic biomass gives the advantage of being an abundant resource, and its industrial pretreatment allows the separation of lignins, cellulose, and hemicelluloses to use them separately as chemicals 1 . Although the valorization of cellulose and hemicelluloses has been mainly considered and exploited in many fields, such as pharmaceuticals 2 or cosmetics, 3 lignins remain poorly valorized although being the most abundant non‐saccharidic polymer 4 and representing 15%–30% of the organic material in the biosphere 5 . By the use of technical lignins (TL), the sustainability of biorefineries would be increased through the valorization of the whole biomass 6,7 and new multifunctional properties could emerge, differing from other emulsifiers.…”

Section: Introductionmentioning

confidence: 99%

“…1 Although the valorization of cellulose and hemicelluloses has been mainly considered and exploited in many fields, such as pharmaceuticals 2 or cosmetics, 3 lignins remain poorly valorized although being the most abundant non-saccharidic polymer 4 and representing 15%-30% of the organic material in the biosphere. 5 By the use of technical lignins (TL), the sustainability of biorefineries would be increased through the valorization of the whole biomass 6,7 and new multifunctional properties could emerge, differing from other emulsifiers. Lignins' structure is highly heterogeneous 8 because they are derived from three different monolignol precursors, coniferyl alcohol, sinapyl alcohol, and paracoumaryl alcohol, 9 that undergo oxidative oligomerization, forming various interunit linkages.…”

mentioning

confidence: 99%

Controlling stabilization of oil‐in‐water emulsions with lignins through fractionation, functionalization, and formulation

Hadjiefstathiou,

Manière,

Attia

et al. 2024

J of Applied Polymer Sci

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Lignins, heterogeneous assemblies of polyphenolic oligomers present in lignocellulosic plant biomass, are valorized mainly by combustion because of their low solubility in commonly used solvents. However, in addition to antioxidant, anti‐UV and antimicrobial properties, and marked interfacial properties are part of lignins physicochemical properties, thus making them good candidates for sustainable colloids. It is hypothesized that lignins solubility and emulsifying performances could be modulated by fractionation, functionalization, and formulation strategies. The importance of the solvent, and of the pH on lignins solubilization in aqueous phase was investigated. Accordingly, simple O/W emulsions stabilized by different lignins were designed and characterized. The whole results demonstrated that lignins solubility in water can be optimized using appropriate co‐solvent and pH readjustment resulting in a homogeneous dispersion with only 7.2 ± 1.8% wt/wt of insoluble lignins. Both fractionation and biocatalytic modification of lignins allowed increasing stabilization of the oil–water interface by limiting coalescence (23%–24% of relative increase of the D90) compared with non‐fractionated lignins (32%), thus advocating their potential use as multifunctional emulsion stabilizers. As a result, a direct link between the molar mass profile of lignins and their ability to stabilize the oil–water interface as well as to reduce emulsion's sedimentation could be established.

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“…On the other side, the presence of abundant active functional groups on the lignin, such as methoxyl, hydroxyl, carbonyl, and carboxyl groups, can take part in charge transfer via the redox chemistry of quinone/hydroquinone, enhancing the performance of supercapacitors. , Due to the non-conductive nature of lignin, it must to be combined with conductive supports of carbon or conducting polymers. For example, a newly designed electrode is prepared by confining lignin with reduced graphene oxide sheets, which display admirable activity due to the synergistic combination of fast reversible charge transfer from the functional groups of lignin and the electron-conducting graphene sheets.…”

Section: Introductionmentioning

confidence: 99%

Dual Action of Lignin: Electrode and Electrolyte for Sustainable Supercapacitor Application

Khalid

Singh

et al. 2023

ACS Appl. Energy Mater.

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From a sustainability and economic point of view, lignin is a potential biopolymer that can be used as an electrode and electrolyte source for renewable energy applications. In this work, an electrode, i.e., microporous carbon, is prepared from the kraft lignin using a ball-milling method followed by vacuum-assisted carbonization. The milling time of kraft lignin has not only a significant effect on developing large surface area carbon (∼606 m2 g–1) without activation, but at the same time, vacuum-assisted carbonization also minimizes the oxygen content up to ∼1%. The microporous carbon (referred to as KL-8) developed from kraft lignin by optimizing milling time of 8 h in a symmetric supercapacitor displays a specific capacitance of 117.9 F g–1 at a current density of 0.5 A g–1 in lignin-containing 6 M KOH electrolyte (denoted as Lig/6 M KOH) compared to pure 6 M KOH solution (88 F g–1). The enhanced capacitance of a symmetric supercapacitor in Lig/6 M KOH electrolyte is attributed to the electronic carrier transported between the carbon electrode and electrolyte interface by virtue of oxygenated groups of lignin dissolved in the 6 M KOH electrolyte. The symmetric supercapacitor shows ultra-stable performance up to 75,000 repetitive charging–discharging cycles at 5 A g–1 with 98.2% capacitance retention. Furthermore, a lignin-derived gel electrolyte membrane is made and used in a solid-state supercapacitor, which exhibits improved electrochemical performance compared to the state-of-the-art polyvinyl alcohol/KOH-based gel electrolyte. Thus, the formulation of the active electrode and electrolyte from a sustainable source of lignin for supercapacitor applications represents a milestone in functionality.

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Lignin-Derived Quinone Redox Moieties for Bio-Based Supercapacitors

Cited by 18 publications

References 86 publications

Recent strides toward transforming lignin into plastics and aqueous electrolytes for flow batteries

Recent strides toward transforming lignin into plastics and aqueous electrolytes for flow batteries

Controlling stabilization of oil‐in‐water emulsions with lignins through fractionation, functionalization, and formulation

Dual Action of Lignin: Electrode and Electrolyte for Sustainable Supercapacitor Application

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