Anisotropic Muscle-like Conductive Composite Hydrogel Reinforced by Lignin and Cellulose Nanofibrils

Yan, Mengzhen; Cai, Junqi; Fang, Zhiqiang; Wang, Huan; Qiu, Xueqing; Liu, Weifeng

doi:10.1021/acssuschemeng.2c02506

Cited by 27 publications

(22 citation statements)

References 45 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition, the conductivity of the SRT 5:5 -PVA 15 eutectogel perpendicular to the training direction was similar to the original value (1.15 mS cm –1 ), while its conductivity along the training direction increased to 2.63 mS cm –1 (Figure e). This result was attributed to the oriented alignment of the polymer network after training, facilitating the transport of ions along the training direction . In conclusion, our SR-PVA eutectogel can be imparted with a directional muscle-like stretching performance and high conductivity through convenient mechanical training operations, which provided the possibility for its application in soft robotics and artificial muscles.…”

Section: Results and Discussionmentioning

confidence: 75%

“…This result was attributed to the oriented alignment of the polymer network after training, facilitating the transport of ions along the training direction. 45 In conclusion, our SR-PVA eutectogel can be imparted with a directional muscle-like stretching performance and high conductivity through convenient mechanical training operations, which provided the possibility for its application in soft robotics and artificial muscles.…”

Section: Mechanical Trainingmentioning

confidence: 83%

“…The oriented structure of the SRT 5:5 -PVA 15 eutectogel was the result of repeated directional stretching, which significantly affected its performance. 45 As shown in Figure 6d, the stress−strain curve of the SRT 5:5 -PVA 15 eutectogel along the training direction exhibited a musclelike "J" shape. 46,47 Its initial Young's modulus decreased from 2.10 to 0.96 MPa before training, and the tensile strength increased from 1.67 to 3.00 MPa before training (Figure S18).…”

Section: Mechanical Trainingmentioning

confidence: 86%

See 2 more Smart Citations

Facile Solvent Regulation for Highly Strong and Tough Physical Eutectogels with Remarkable Strain Sensitivity

Chen,

Feng

2023

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

Section: Results and Discussionmentioning

confidence: 75%

Section: Mechanical Trainingmentioning

confidence: 83%

Section: Mechanical Trainingmentioning

confidence: 86%

See 1 more Smart Citation

Facile Solvent Regulation for Highly Strong and Tough Physical Eutectogels with Remarkable Strain Sensitivity

Chen,

Feng

2023

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

“…The strategy of using lignin (Kraft lignin, lignosulfonate, or hydrolyzed lignin) AgNPs to trigger a quinone–catechol redox reaction followed by cross-linking to provide multifunctional hydrogels has been further expanded by several research groups. − Lu and co-workers combined the Ag-catalyzed strategy of an oxidative decarboxylation of citric acid and poly(acrylamide- co -acrylic acid), a free radical polymerization of acrylic acid, and a quinone–catechol redox reaction to engineer a versatile hydrogel . Besides the multifunctionality of the hydrogel, it was also injectable through a needle and fabricated by electrospinning to create micro/nanofibers.…”

Section: Combined Catalysis: An Innovative and Sustainable Tool For E...mentioning

confidence: 99%

Combined Catalysis: A Powerful Strategy for Engineering Multifunctional Sustainable Lignin-Based Materials

Afewerki

Edlund

2023

ACS Nano

View full text Add to dashboard Cite

The production and engineering of sustainable materials through green chemistry will have a major role in our mission of transitioning to a more sustainable society. Here, combined catalysis, which is the integration of two or more catalytic cycles or activation modes, provides innovative chemical reactions and material properties efficiently, whereas the single catalytic cycle or activation mode alone fails in promoting a successful reaction. Polyphenolic lignin with its distinctive structural functions acts as an important template to create materials with versatile properties, such as being tough, antimicrobial, self-healing, adhesive, and environmentally adaptable. Sustainable lignin-based materials are generated by merging the catalytic cycle of the quinone–catechol redox reaction with free radical polymerization or oxidative decarboxylation reaction, which explores a wide range of metallic nanoparticles and metal ions as the catalysts. In this review, we present the recent work on engineering lignin-based multifunctional materials devised through combined catalysis. Despite the fruitful employment of this concept to material design and the fact that engineering has provided multifaceted materials able to solve a broad spectrum of challenges, we envision further exploration and expansion of this important concept in material science beyond the catalytic processes mentioned above. This could be accomplished by taking inspiration from organic synthesis where this concept has been successfully developed and implemented.

show abstract

“…Flexible wearable electronic devices have attracted a significant amount of interest in the fields of human motion detection, health monitoring, electronic skins, flexible sensors, and soft robotics because of their large mechanical flexibility and their ability to adapt to different working environments to a certain extent and meet different deformation requirements. − Among a wide variety of sensing materials, hydrogels show great application potential due to their functionality, formability, and chemical editability. − Although the application value of hydrogel sensors in detecting body movement and vital signs has been proven, their practical application is still significantly limited, which is mainly caused by the inherent properties of hydrogels. − The first inherent property that hinders the practical application of hydrogels as flexible wearable electronic devices is swelling behavior. Hydrogel is a kind of soft material composed of a three-dimensional polymer framework with high water content. − For obtaining good biocompatibility, this three-dimensional polymer framework is generally designed as hydrophilic polymer segments, which will lead to the swelling behavior of the hydrogel in the aqueous environment. − Swelling behavior is usually accompanied by the introduction of a large number of solvent substances and the dilution or loss of functional molecules. − Meanwhile, the decrease of hydrogel density caused by swelling behavior also has a significant negative impact on the mechanical properties of hydrogels. − The second inherent property is the low-temperature phase transition behavior of hydrogels. A large number of water molecules contained in hydrogels will phase-change at low temperatures to form ice without flexibility, which is negative for applications in low-temperature environments.…”

Section: Introductionmentioning

confidence: 99%

Novel Lignin Hydrogel Sensors with Antiswelling, Antifreezing, and Anticreep Properties

Han

Che

et al. 2023

ACS Sustainable Chem. Eng.

View full text Add to dashboard Cite

Hydrogel shows great potential as a flexible wearable electronic device. However, the practical application of hydrogel is still significantly limited due to the poor functional stability caused by swelling behavior, non-frost resistance caused by high water content, and obvious creep behavior under repeated external force. In this work, macromolecular lignin with a threedimensional network structure, and active functional groups are introduced into the hydrogel through the esterification grafting reaction of methacryloyl chloride. The introduction of lignin effectively improves the antiswelling, antifreezing, and creep resistance of the hydrogel sensor, while maintaining the mechanical properties (elongation at break > 350%, tensile strength > 1.5 MPa) and electrical conductivity (10 S/m). Under extreme environments, the toughness, tensile strength, and elongation at break of the hydrogel remain at more than 96%. Furthermore, the antifreezing, creep resistance, and conductivity of hydrogel sensors are not significantly affected after immersion in water for a long time (72 h). This work proposes a simple strategy to improve the antiswelling, antifreezing, and anticreep properties of hydrogels, which has guiding significance for the preparation of high-performance flexible wearable electronic materials.

show abstract

Anisotropic Muscle-like Conductive Composite Hydrogel Reinforced by Lignin and Cellulose Nanofibrils

Cited by 27 publications

References 45 publications

Facile Solvent Regulation for Highly Strong and Tough Physical Eutectogels with Remarkable Strain Sensitivity

Facile Solvent Regulation for Highly Strong and Tough Physical Eutectogels with Remarkable Strain Sensitivity

Combined Catalysis: A Powerful Strategy for Engineering Multifunctional Sustainable Lignin-Based Materials

Novel Lignin Hydrogel Sensors with Antiswelling, Antifreezing, and Anticreep Properties

Contact Info

Product

Resources

About