Anti-Freezing, Non-Drying, Localized Stiffening, and Shape-Morphing Organohydrogels

Shen, Jiayan; Du, Shutong; Xu, Ziyao; Gan, Tiansheng; Handschuh‐Wang, Stephan; Zhang, Xueli

doi:10.3390/gels8060331

Cited by 3 publications

(3 citation statements)

References 56 publications

(67 reference statements)

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“…[ 39 ] In addition, one of the major challenges in using hydrogels as substrates is water evaporation, which alters the mechanical and surface properties of the hydrogel over time. [ 40 ] Therefore, our initial attempts to print the circuit over the hydrogel substrate failed due to these problems.…”

Section: Resultsmentioning

confidence: 99%

“…The immersion time plays an important role in the long-term stability of the hydrogels because by improving weight retention, which depends on the wt.% of glycerol incorporated. [40,41] To verify the liquid retention ability, the hydrogels were evaluated by weight measurements during 30 days of storage at 22 °C and 60% humidity (Figure 2A-C). As expected, the water-based hydrogels exhibited low water retention (20.8 wt.% after 1 day), which resulted in compromised mechanical properties (tensile strain, modulus, and flexibility) and caused a mechanical deformation (Figure 2B, Figure S1, Supporting Information).…”

Section: Synthesis and Properties Of Photodegradable Dn Hydrogelsmentioning

confidence: 99%

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Photodegradable Non‐Drying Hydrogel Substrates for Liquid Metal Based Sustainable Soft‐Matter Electronics

Fonseca

Hajalilou

Freitas

et al. 2023

Adv Materials Technologies

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The increasing interest in disposable electronics such as wearable patches, e‐textiles, and smart packaging, warns emergence of another man‐made disaster. A paradigm shift toward a more sustainable future through the development of soft material architectures that are robust and durable, but also degradable by external stimuli is proposed. Hydrogels, a class of soft polymers with exceptional properties, and high water content are rarely used as substrates, mainly due to lack of ink‐adhesion and rapid dehydration. Herein, photodegradable hydrogels are tailor‐made that are nondrying, robust, adhesive to ink, and permit triggerable degradation, making them suitable substrates for sustainable electronics. These hydrogels are prepared by reversible ionic crosslinking between sodium alginate and divalent cations (Ca2+) and light‐responsive crosslinking of poly(acrylamide) (PAAm) chains through synthesized ortho‐nitrobenzyl (ONB)‐based crosslinkers. By displacing the water molecules in the hydrogels by immersion in glycerol, the drying problem and printability of conductive ink are addressed. It is demonstrated that digital printing of a liquid metal (LM)‐based stretchable ink over the developed substrate, shows several body‐worn printed wearable sensors, and demonstrates their degradation and recycling of the expensive metals. This work lays the foundation for the use of hydrogels as promising substrates for the next generation of environmentally friendly electronics.

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Section: Resultsmentioning

confidence: 99%

Section: Synthesis and Properties Of Photodegradable Dn Hydrogelsmentioning

confidence: 99%

Photodegradable Non‐Drying Hydrogel Substrates for Liquid Metal Based Sustainable Soft‐Matter Electronics

Fonseca

Hajalilou

Freitas

et al. 2023

Adv Materials Technologies

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show abstract

“…However, most hydrogels tend to dehydrate gradually under ambient conditions and freeze at subzero temperatures. − To overcome these problems, strategies such as solvent replacement , and salt treatment method have been developed . Although using organic solvents such as polyols (e.g., glycerol and glycol) as partial substitutes for water in hydrogels can improve their resistance to freezing and dehydration, polyols often exhibit insulating properties, which can restrict the electronic applications of hydrogels . In contrast, salts such as LiBr, MgCl 2 , and CaCl 2 can not only confer hydrogels with antifreezing and dehydration properties but also improve their ionic conductivities. , However, the application of salt-treated hydrogels in temperature sensing has received limited exploration …”

Section: Introductionmentioning

confidence: 99%

Highly Sensitive Temperature Detection Based on a Frost- and Dehydration-Resistive Ion-Doped Hydrogel-MXene Composite

Wang

Zou

Yang

et al. 2023

ACS Appl. Mater. Interfaces

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Wearable temperature sensors with high sensitivity and stability hold great potential for human health monitoring. However, hydrogels, which are commonly used for wearable devices, often show poor thermal and electrical conductivity and are susceptible to dehydration and freezing. Herein, we developed a frost- and dehydration-resistive temperature sensor based on Fe2+/Ti2CT x /κ-carrageenan (CA)-polyacrylamide (PAM) hydrogel. The Fe2+ ions within the hydrogel existed in two forms: as free ions and bonded ions. The free Fe2+ ions could complex with water molecules, resulting in the improved resistance to dehydration and freezing, as well as enhanced ionic conductivity in the hydrogel. On the other hand, the remaining Fe2+ ions acted as linkers to form coordination bonds with the sulfate groups of CA chains, resulting in the greatly enhanced mechanical strength of the hydrogel. In addition, the Ti2CT x nanosheet-based fillers formed a well-defined porous laminar structure, which reduced the phonon scattering and improved the phonon adsorption within the hydrogel. The Fe2+/Ti2CT x /CA-PAM hydrogel sensor exhibited excellent temperature sensing performance including a good linearity (R 2 = 0.998) within a broad working range (−10 to 60 °C), high resolution (0.1 °C), and good repeatability. Furthermore, the sensor was integrated into a wireless system for continuous monitoring of body temperature, demonstrating its potential in healthcare monitoring, electronic skins, and intelligent robots.

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A Review on Thermal Properties of Hydrogels for Electronic Devices Applications

Xin

Lyu

2022

Gels

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Hydrogels, as a series of three-dimensional, crosslinked, hydrophilic network polymers, exhibit extraordinary properties in softness, mechanical robustness and biocompatibility, which have been extensively utilized in various fields, especially for electronic devices. However, since hydrogels contain plenty of water, the mechanical and electrochemical properties are susceptible to temperature. The thermal characteristics of hydrogels can significantly affect the performance of flexible electronic devices. In this review, recent research on the thermal characteristics of hydrogels and their applications in electronic devices is summarized. The focus of future work is also proposed. The thermal stability, thermoresponsiveness and thermal conductivity of hydrogels are discussed in detail. Anti-freezing and anti-drying properties are the critical points for the thermal stability of hydrogels. Methods such as introducing soluble ions and organic solvents into hydrogels, forming ionogels, modifying polymer chains and incorporating nanomaterials can improve the thermal stability of hydrogels under extreme environments. In addition, the critical solution temperature is crucial for thermoresponsive hydrogels. The thermoresponsive capacity of hydrogels is usually affected by the composition, concentration, crosslinking degree and hydrophilic/hydrophobic characteristics of copolymers. In addition, the thermal conductivity of hydrogels plays a vital role in the electronics applications. Adding nanocomposites into hydrogels is an effective way to enhance the thermal conductivity of hydrogels.

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Anti-Freezing, Non-Drying, Localized Stiffening, and Shape-Morphing Organohydrogels

Cited by 3 publications

References 56 publications

Photodegradable Non‐Drying Hydrogel Substrates for Liquid Metal Based Sustainable Soft‐Matter Electronics

Photodegradable Non‐Drying Hydrogel Substrates for Liquid Metal Based Sustainable Soft‐Matter Electronics

Highly Sensitive Temperature Detection Based on a Frost- and Dehydration-Resistive Ion-Doped Hydrogel-MXene Composite

A Review on Thermal Properties of Hydrogels for Electronic Devices Applications

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