Strong and tough polyvinyl alcohol hydrogels with high intrinsic thermal conductivity

Junliang Zhang; Chenyang Tang; Qingqing Kong; Mukun He; Peng Lv; Hua Guo; Yongqiang Guo; Xuetao Shi; Junwei Gu

doi:10.20517/ss.2024.72

Soft Science ›› 2025, Vol. 5 ›› Issue (1) :9 DOI: 10.20517/ss.2024.72

Research Article

Strong and tough polyvinyl alcohol hydrogels with high intrinsic thermal conductivity

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Abstract

Although polyvinyl alcohol (PVA) hydrogels display huge potential in tissue engineering, flexible and wearable electronic devices and soft robotics, their low intrinsic thermal conductivity and weak mechanical properties severely limit their wider applications in these areas. Herein, a Hofmeister effect-assisted “directional freezing-stretching” tactic is employed for simultaneously enhancing the intrinsic thermal conduction and mechanical properties of PVA hydrogels. The hydrogels are obtained through directional freezing followed by salting-out treatment and subsequent mechanical stretching and salting-out (DFS). The DFS PVA hydrogel with 15 wt% of PVA and a stretching ratio of 4 (DFS4) exhibits the highest thermal conductivity of 1.25 W/(m·K), which is 2.4 and 2.8 times that of PVA hydrogel prepared through frozen-thawed (FT) [0.52 W/(m·K)] and frozen-salted out (FS) [0.45 W/(m·K)] methods, respectively. The DFS4 PVA hydrogel also possesses greatly improved mechanical performances, exhibiting an elongation at break of 163.1%. In addition, the tensile strength, toughness, and elastic modulus of DFS4 PVA hydrogel significantly increase to 27.1 MPa, 25.3 MJ·m^-3, and 21.5 MPa from 0.4 MPa, 0.32 MJ·m^-3, and 0.07 MPa for FT PVA hydrogels, respectively. It is elucidated that the salting-out effect generates hydrophobic and crystalline regions, while directional freezing and stretching enhance the chain orientation in the DFS strategy. These effects synergistically contribute to the improvement of thermal conductivity and mechanical properties of PVA hydrogels.

Keywords

Intrinsic thermal conductivity / polyvinyl alcohol hydrogels / directional freezing / salting-out / Hofmeister effect

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Junliang Zhang, Chenyang Tang, Qingqing Kong, Mukun He, Peng Lv, Hua Guo, Yongqiang Guo, Xuetao Shi, Junwei Gu. Strong and tough polyvinyl alcohol hydrogels with high intrinsic thermal conductivity. Soft Science, 2025, 5(1): 9 DOI:10.20517/ss.2024.72

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Zhang YS.Advances in engineering hydrogels.Science2017;356:eaaf3627 PMCID:PMC5841082

[2]	Ke X,Chen S.Reduced graphene oxide reinforced PDA-Gly-PVA composite hydrogel as strain sensors for monitoring human motion.Soft Sci2023;3:1-12

[3]	Wu Y,Wu H.Solvent-exchange-assisted wet annealing: a new strategy for superstrong, tough, stretchable, and anti-fatigue hydrogels.Adv Mater2023;35:e2210624

[4]	Kim SD,Lee S.Injectable and tissue-conformable conductive hydrogel for MRI-compatible brain-interfacing electrodes.Soft Sci2023;3:18

[5]	Xu Q,Zhao W.Strategies in the preparation of conductive polyvinyl alcohol hydrogels for applications in flexible strain sensors, flexible supercapacitors, and triboelectric nanogenerator sensors: an overview.Adv Compos Hybrid Mater2023;6:783

[6]	Liu D,Jiang P.Tough, transparent, and slippery PVA hydrogel led by syneresis.Small2023;19:e2206819

[7]	Lei D,Shao L,Jiang Y.Dual-stimuli-responsive and anti-freezing conductive ionic hydrogels for smart wearable devices and optical display devices.ACS Appl Mater Interfaces2023;15:24175-85

[8]	Jing L,Tay RY.Biocompatible hydroxylated boron nitride nanosheets/poly(vinyl alcohol) interpenetrating hydrogels with enhanced mechanical and thermal responses.ACS Nano2017;11:3742-51

[9]	Zhao L,Cao P.Fast water transport reversible CNT/PVA hybrid hydrogels with highly environmental tolerance for multifunctional sport headband.Compos Part B Eng2021;211:108661

[10]	Wu S,Alsaid Y.Poly(vinyl alcohol) hydrogels with broad-range tunable mechanical properties via the hofmeister effect.Adv Mater2021;33:e2007829

[11]	Chen X,Zhang Y,Li R.Tropocollagen-inspired hierarchical spiral structure of organic fibers in epoxy bulk for 3D high thermal conductivity.Adv Mater2022;34:e2206088

[12]	Yang J,Yang W.Templating strategies for 3D-structured thermally conductive composites: recent advances and thermal energy applications.Prog Mater Sci2023;133:101054

[13]	Ren L,Kang L,Lv R.Lightweight, electrical insulating, and high thermally conductive all-polymer composites with reinforced interfaces.Compos Sci Technol2023;240:110080

[14]	Guo C,Yao Y.Bifunctional liquid metals allow electrical insulating phase change materials to dual-mode thermal manage the Li-ion batteries. Nano-Micro Lett. 2022, 14, 202. PMCID:PMC9551009

[15]	Yun J.Recent progress in thermal management for flexible/wearable devices.Soft Sci2023;3:12

[16]	Zhang H,Zhao Y.Liquid crystal-engineered polydimethylsiloxane: enhancing intrinsic thermal conductivity through high grafting density of mesogens.Angew. Chem. Int. Ed.2025;e202500173

[17]	Lin Y,Liu Y.Flexible, highly thermally conductive and electrically insulating phase change materials for advanced thermal management of 5G base stations and thermoelectric generators. Nano-Micro Lett. 2023, 15, 31. PMCID:PMC9829950

[18]	He M,Lu X.Excellent low-frequency microwave absorption and high thermal conductivity in polydimethylsiloxane composites endowed by hydrangea-like CoNi@BN heterostructure fillers.Adv Mater2024;36:e2410186

[19]	Miao D,Wang X,Ding B.Integration of Janus wettability and heat conduction in hierarchically designed textiles for all-day personal radiative cooling.Nano Lett2022;22:680-7

[20]	Zhang F,Zhang K.Highly thermally conductive liquid crystalline epoxy resin vitrimers with reconfigurable, shape-memory, photo-thermal, and closed-loop recycling performance.Adv Sci2025;12:e2410362 PMCID:PMC11744650

[21]	Guo Y,Zhang H.Consistent thermal conductivities of spring-like structured polydimethylsiloxane composites under large deformation.Adv Mater2024;36:e2404648

[22]	Qin M,Han G.Three-dimensional boron nitride network/polyvinyl alcohol composite hydrogel with solid-liquid interpenetrating heat conduction network for thermal management.J Mater Sci Technol2022;127:183-91

[23]	Tian R,Bai Y,Song H.Fluorinated graphene thermally conductive hydrogel with a solid-liquid interpenetrating heat conduction network.ACS Appl Mater Interfaces2024;16:1451-60

[24]	Kazimierska-Drobny K,Kaczmarek M.Determination of mechanical and hydraulic properties of PVA hydrogels.Mater Sci Eng C Mater Biol Appl2015;48:48-54

[25]	Li W,Zheng Y.Preparation, mechanical properties, fatigue and tribological behavior of double crosslinked high strength hydrogel.J Mech Behav Biomed Mater2022;126:105009

[26]	Duan S,Hong J.Water-modulated biomimetic hyper-attribute-gel electronic skin for robotics and skin-attachable wearables. ACS Nano 2023, 1355-71.

[27]	Ji D,Im P,Kim J.Thermal interface hydrogel composites mechanically compliant with curvy skins and rigid electronic modules.Adv Funct Mater2024;34:2402144

[28]	Xu S,Liu Z.Thermal conductivity of polyacrylamide hydrogels at the nanoscale.ACS Appl Mater Interfaces2018;10:36352-60

[29]	Zhang Z,Bao Z,Wang C.Thermal conductivity of PNIPAm hydrogels and heat management as smart windows.Macro Mater Eng2023;308:2200566

[30]	Zhang M,Li M.Toughening double-network hydrogels by polyelectrolytes.Adv Mater2023;35:e2301551

[31]	Singh V,Weathers A.High thermal conductivity of chain-oriented amorphous polythiophene.Nat Nanotechnol2014;9:384-90

[32]	Tu H,Lin X.Superior strength and highly thermoconductive cellulose/boron nitride film by stretch-induced alignment.J Mater Chem A2021;9:10304-15

[33]	Candadai AA,Marconnet AM.Thermal conductivity of ultrahigh molecular weight polyethylene: from fibers to fabrics.ACS Appl Polym Mater2020;2:437-47

[34]	Zhang Y,Zhou K.Controlled distributed Ti₃C₂T_x hollow microspheres on thermally conductive polyimide composite films for excellent electromagnetic interference shielding.Adv Mater2023;35:e2211642

[35]	Han Y,He X.Highly thermally conductive aramid nanofiber composite films with synchronous visible/infrared camouflages and information encryption.Angew Chem Int Ed2024;63:e202401538

[36]	Uetani K,Oyama HT.In-plane anisotropic thermally conductive nanopapers by drawing bacterial cellulose hydrogels.ACS Macro Lett2017;6:345-9

[37]	Wu T,Yu H,Yang W.Stretch induced thermal conduction anisotropy of hydrogel.Int J Heat Mass Transfer2022;185:122445

[38]	Lin S,Liu X.Muscle-like fatigue-resistant hydrogels by mechanical training.Proc Natl Acad Sci U S A2019;116:10244-9 PMCID:PMC6535018

[39]	Chen Y,Luo L.Super strong and tough PVA hydrogel fibers based on an ordered-to-disordered structural construction strategy targeting artificial ligaments. Adv. Funct. Mater. 2024.

[40]	Mredha MTI,Nonoyama T,Kurokawa T.A facile method to fabricate anisotropic hydrogels with perfectly aligned hierarchical fibrous structures.Adv Mater2018;30:1704937

[41]	Gu L,Hu J.Scalable spider-silk-like supertough fibers using a pseudoprotein polymer.Adv Mater2019;31:e1904311

[42]	Wang W,Zheng J.A vasculatural hydrogel combined with Prussian blue for solar-driven vapor generation.J Mater Chem A2022;10:12608-15

[43]	Zhang L,Weng S.Super strong and tough anisotropic hydrogels through synergy of directional freeze-casting, metal complexation and salting out.Chem Eng J2023;463:142414

[44]	Mredha MTI,Tran VT,Cui J.Anisotropic tough multilayer hydrogels with programmable orientation.Mater Horiz2019;6:1504-11

[45]	Wei W.Hofmeister effects shine in nanoscience.Adv Sci2023;10:e2302057 PMCID:PMC10401134

[46]	Lo Nostro P, Ninham BW. Hofmeister phenomena: an update on ion specificity in biology.Chem Rev2012;112:2286-322

[47]	Zou H,Zhao X.Hofmeister effect-enhanced hydration chemistry of hydrogel for high-efficiency solar-driven interfacial desalination.Adv Mater2023;35:e2207262

[48]	Sun X,Yu Z,Jiang F.A biomimetic “salting out-alignment-locking” tactic to design strong and tough hydrogel.Adv Mater2024;36:e2400084

[49]	Lin X,Nie Z.A highly aligned X-shaped hydrogel fiber via cooperative roles of amorphous and crystalline network mediated by Hofmeister effect.Polymer2024;292:126538

[50]	He Q,Wang S.Hofmeister effect-assisted one step fabrication of ductile and strong gelatin hydrogels.Adv Funct Mater2018;28:1705069

[51]	Zhang J,Zhang F,Kong Q.Effect of the structure of epoxy monomers and curing agents: toward making intrinsically highly thermally conductive and low-dielectric epoxy resins. JACS Au. 2023, 3, 3424-35. PMCID:PMC10751775

[52]	Rodríguez-Martínez X,Dörling B.On the thermal conductivity of conjugated polymers for thermoelectrics.Adv Energy Mater2024;14:2401705

[53]	Wang Z,Weng L.A roadmap review of thermally conductive polymer composites: critical factors, progress, and prospects.Adv Funct Mater2023;33:2301549

[54]	Yuan SJ,Rong MZ.Enhancement of intrinsic thermal conductivity of liquid crystalline epoxy through the strategy of interlocked polymer networks.Mater Chem Front2022;6:1137-49

[55]	Hossain MM,Jeong H.Diacetylene-containing dual-functional liquid crystal epoxy resin: strategic phase control for topochemical polymerization of diacetylenes and thermal conductivity enhancement.Macromolecules2022;55:4402-10

[56]	He M,Ruan K.Functionalized aluminum nitride for improving hydrolysis resistances of highly thermally conductive polysiloxane composites. Nano-Micro Lett. 2025.