Strong, tough, ionic conductive, and freezing-tolerant all-natural hydrogel enabled by cellulose-bentonite coordination interactions

Wang, Siheng; Yu, Le; Wang, Shanshan; Zhang, Lei; Chen, Lü; Xu, Xu; Song, Zhicheng; Liu, He; Chen, Chaoji

doi:10.1038/s41467-022-30224-8

Cited by 163 publications

(93 citation statements)

References 46 publications

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“…The high moisture content of the hydrogels will form ice crystals at subzero temperatures, which makes it difficult for polymer chains to move, causing hydrogel electronics to lose their excellent performance, including conductivity, transparency, and flexibility. , Therefore, the development of freezing-resistant hydrogels is greatly significant for the stable operation of hydrogel-based electronics at subzero temperatures. Efforts have been devoted to improving the freezing resistance of the conductive hydrogel via the introduction of inorganic salts, such as NaCl, CaCl 2 , LiCl, and so forth. , Inorganic salts could significantly lower the freezing point by weakening the internal hydrogen bonding between water molecules . Suo et al developed a double network hydrogel by soaking the polyacrylamide sodium alginate hydrogel in the high-concentration solution of CaCl 2 .…”

Section: Introductionmentioning

confidence: 99%

Rapid Preparation of Antifreezing Conductive Hydrogels for Flexible Strain Sensors and Supercapacitors

Song

Niu

et al. 2023

ACS Appl. Mater. Interfaces

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Conductive hydrogels have shown great promise in flexible electronics, but their practical applications may be impeded by the time-consuming and energy-consuming polymerization process. We proposed a sodium lignosulfonate−Fe (SLS−Fe) strategy to address this challenge and took advantage of carboxymethyl cellulose (CMC) and poly(acrylic acid) to prepare the CMC/PAA/Fe 3+ /LiCl interpenetrating conductive hydrogels with good self-healing properties, antifreezing properties, and a 6fold increase in conductivity in this study. The hydrogel-based flexible strain sensors demonstrated a broad detection range (400%), high sensitivity (GF = 6.19 at 200−400%), and human motion detection capability. The hydrogel-based supercapacitor exhibited a single-electrode specific capacitance of 122.36 F g −1 which successfully powered LEDs. Furthermore, the supercapacitor showed a single-electrode specific capacitance of 83.16 F g −1 at −23 °C (68% of the one exhibited at 25 °C). Therefore, the multifunctional performance of the CMC/PAA/Fe 3+ /LiCl hydrogel is anticipated to play an exemplary role in a new generation of flexible electronics.

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Section: Introductionmentioning

confidence: 99%

Rapid Preparation of Antifreezing Conductive Hydrogels for Flexible Strain Sensors and Supercapacitors

Song

Niu

et al. 2023

ACS Appl. Mater. Interfaces

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“…27 In such ion-conductive gels, a significant amount of electrolyte is added to improve the system conductivity; however, electrolyte overload then compromises the mechanical properties of the gels. 27–30 For instance, Ouyang's group developed an iTE gel composed of an organic polymer (waterborne polyurethane, WPU) and electrolyte (1-ethyl-3-methylimidazolium dicyanamide, EMIM:DCA), where increasing EMIM:DCA loading increased the ionic conductivity of the gel from 0.08 (10 wt% loading) to 11.7 mS cm −1 (50 wt% loading). However, the mechanical strength of the as-prepared iTE gel decreased from 4.2 to 0.6 MPa when EMIM:DCA amount increased from 20 wt% to 40 wt%.…”

Section: Introductionmentioning

confidence: 99%

Rarely negative-thermovoltage cellulose ionogel with simultaneously boosted mechanical strength and ionic conductivity via ion-molecular engineering

et al. 2023

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“…However, most hydrogels, including tough ones, have an elastic modulus on the kPa level, − which cannot provide sufficient structural stiffness and generate thrust force for continuous motions of hydrogel-based underwater soft robots. In recent years, various tough and stiff hydrogels with a wide spectrum of mechanical performances have been developed and recognized as a new kind of engineering material to construct versatile soft machines. − However, there is no report on the design of underwater soft robots with tough hydrogels as the structural elements.…”

Section: Introductionmentioning

confidence: 99%

Manta Ray Inspired Soft Robot Fish with Tough Hydrogels as Structural Elements

Zhang

Zou

et al. 2022

ACS Appl. Mater. Interfaces

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The design of soft robots capable of navigation underwater has received tremendous research interest due to the robots' versatile applications in marine explorations. Inspired by marine animals such as jellyfish, scientists have developed various soft robotic fishes by using elastomers as the major material. However, elastomers have a hydrophobic network without embedded water, which is different from the gel-state body of the prototypes and results in high contrast to the surrounding environment and thus poor acoustic stealth. Here, we demonstrate a manta ray-inspired soft robot fish with tailored swimming motions by using tough and stiff hydrogels as the structural elements, as well as a dielectric elastomer as the actuating unit. The switching between actuated and relaxed states of this unit under wired power leads to the flapping of the pectoral fins and swimming of the gel fish. This robot fish has good stability and swims with a fast speed (∼10 cm/s) in freshwater and seawater over a wide temperature range (4−50 °C). The high water content (i.e., ∼70 wt %) of the robot fish affords good optical and acoustic stealth properties under water. The excellent mechanical properties of the gels also enable easy integration of other functional units/systems with the robot fish. As proof-of-concept examples, a temperature sensing system and a soft gripper are assembled, allowing the robot fish to monitor the local temperature, raise warning signals by lighting, and grab and transport an object on demand. Such a robot fish should find applications in environmental detection and execution tasks under water. This work should also be informative for the design of other soft actuators and robots with tough hydrogels as the building blocks.

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Strong, tough, ionic conductive, and freezing-tolerant all-natural hydrogel enabled by cellulose-bentonite coordination interactions

Cited by 163 publications

References 46 publications

Rapid Preparation of Antifreezing Conductive Hydrogels for Flexible Strain Sensors and Supercapacitors

Rapid Preparation of Antifreezing Conductive Hydrogels for Flexible Strain Sensors and Supercapacitors

Rarely negative-thermovoltage cellulose ionogel with simultaneously boosted mechanical strength and ionic conductivity via ion-molecular engineering

Manta Ray Inspired Soft Robot Fish with Tough Hydrogels as Structural Elements

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