Abstract
Functional hydrogel materials with large-scale deformation induced by ultra-low salinity as an external stimulus have promising applications in seawater osmotic energy harvesting, stimulus-responsive separation materials, intelligent sensors, and actuators. A salt-responsive hydrogel undergoing large volumetric changes (∼1/60) with the use of dilute salt solution (0.01–0.6 wt% NaCl) is designed via facile random copolymerization of polyelectrolyte and zwitterionic polymer chains in this study. The salt-responsive swelling/deswelling properties, morphologies, and mechanical properties of the prepared hydrogels are systematically examined. Internal reconfiguration of distinct polymeric networks is characterized by different salinity percentages via Raman spectroscopy. Subsequently, a portable ion-detection device comprising easy-to-access capillary tubes and salt-responsive hydrogel is successfully designed and compared with a commercial water quality monitoring device. Moreover, intelligent liquid valves with autosensing and actuating functions are developed for the regulation of liquid leakage and transport using the same salt-sensitive hydrogel. It is highly expected that these salinity ultra-sensitive ionic hydrogels would have great potential in monitoring and regulating freshwater resources, seawater osmotic energy harvesting, stimulus-responsive separation materials, and intelligent soft robotics and electronics.
摘要
对超低浓度盐溶液响应产生大尺度形变的功能水凝胶在海水渗 透能收集、刺激响应分离材料、智能传感和致动器等方面具有广阔的 应用前景. 本文结合聚电解质和两性离子聚合物开发了一种盐度超敏 感离子水凝胶. 以稀盐作为分散介质时, 水凝胶体积缩小为原来1/60. 本文研究了盐响应水凝胶的溶胀、形态和力学性能, 并基于拉曼光谱 对聚合物网络盐响应重构行为进行了表征. 此外, 利用毛细管和盐响应 水凝胶成功设计了一种可视化、便携离子检测计, 可媲美商用水质监 测计. 同时开发了具有传感和致动功能的智能液阀, 用于自动感应调节 液体的流出和输送. 该盐敏感水凝胶在淡水监测和调控、海水渗透能 收集、刺激响应分离材料、智能软机器人和电子穿戴等方面具有很大 的应用潜力.
References
Jiang Y, Lee A, Chen J, et al. Crystal structure and mechanism of a calcium-gated potassium channel. Nature, 2002, 417: 515–522
Cifuentes F, Vergara J, Hidalgo C. Sodium/calcium exchange in amphibian skeletal muscle fibers and isolated transverse tubules. Am J Physiol Cell Physiol, 2000, 279: C89–C97
Eisner DA, Caldwell JL, Kistamás K, et al. Calcium and excitation-contraction coupling in the heart. Circ Res, 2017, 121: 181–195
Wang X, Kültz D. Osmolality/salinity-responsive enhancers (OSREs) control induction of osmoprotective genes in euryhaline fish. Proc Natl Acad Sci USA, 2017, 114: E2729–E2738
Sharma S, Jain P, Tiwari S. Dynamic imine bond based chitosan smart hydrogel with magnified mechanical strength for controlled drug delivery. Int J Biol Macromolecules, 2020, 160: 489–495
Cai Y, Liu C, Gong K, et al. Mussel-inspired quaternary composite hydrogels with high strength and high tissue adhesion for transdermal drug delivery: Synergistic hydrogen bonding and drug release mechanism. Chem Eng J, 2023, 465: 142942
Wang Y, Tebyetekerwa M, Liu Y, et al. Extremely stretchable and healable ionic conductive hydrogels fabricated by surface competitive coordination for human-motion detection. Chem Eng J, 2021, 420: 127637
Qin Y, Mo J, Liu Y, et al. Stretchable triboelectric self-powered sweat sensor fabricated from self-healing nanocellulose hydrogels. Adv Funct Mater, 2022, 32: 2201846
Li CY, Zheng SY, Hao XP, et al. Spontaneous and rapid electro-actuated snapping of constrained polyelectrolyte hydrogels. Sci Adv, 2022, 8: eabm9608
Yang F, Hlushko R, Wu D, et al. Ocean salinity sensing using long-period fiber gratings functionalized with layer-by-layer hydrogels. ACS Omega, 2019, 4: 2134–2141
Xiao S, Yang Y, Zhong M, et al. Salt-responsive bilayer hydrogels with pseudo-double-network structure actuated by polyelectrolyte and antipolyelectrolyte effects. ACS Appl Mater Interfaces, 2017, 9: 20843–20851
Cui Y, Li D, Gong C, et al. Bioinspired shape memory hydrogel artificial muscles driven by solvents. ACS Nano, 2021, 15: 13712–13720
Ma Y, Hua M, Wu S, et al. Bioinspired high-power-density strong contractile hydrogel by programmable elastic recoil. Sci Adv, 2020, 6: eabd2520
Liu A, Gao X, Xie X, et al. Stiffness switchable supramolecular hydrogels by photo-regulating crosslinking status. Dyes Pigments, 2020, 177: 108288
Dai L, Ma M, Xu J, et al. All-lignin-based hydrogel with fast pH-stimuli responsiveness for mechanical switching and actuation. Chem Mater, 2020, 32: 4324–4330
Ding H, Zhang XN, Zheng SY, et al. Hydrogen bond reinforced poly(1-vinylimidazole-co-acrylic acid) hydrogels with high toughness, fast self-recovery, and dual pH-responsiveness. Polymer, 2017, 131: 95–103
Chen W, Li D, Bu Y, et al. Design of strong and tough methylcellulose-based hydrogels using kosmotropic Hofmeister salts. Cellulose, 2020, 27: 1113–1126
Wu S, Hua M, Alsaid Y, et al. Poly(vinyl alcohol) hydrogels with broad-range tunable mechanical properties via the Hofmeister effect. Adv Mater, 2021, 33: 2007829
Luo F, Sun TL, Nakajima T, et al. Oppositely charged polyelectrolytes form tough, self-healing, and rebuildable hydrogels. Adv Mater, 2015, 27: 2722–2727
Sun TL, Kurokawa T, Kuroda S, et al. Physical hydrogels composed of polyampholytes demonstrate high toughness and viscoelasticity. Nat Mater, 2013, 12: 932–937
Andrade F, Roca-Melendres MM, Durán-Lara EF, et al. Stimuli-responsive hydrogels for cancer treatment: The role of pH, light, ionic strength and magnetic field. Cancers, 2021, 13: 1164
Liu L, Tanguy NR, Yan N, et al. Anisotropic cellulose nanocrystal hydrogel with multi-stimuli response to temperature and mechanical stress. Carbohydrate Polyms, 2022, 280: 119005
Wu J, Shin H, Lee J, et al. Preparation of external stimulus-free gelatin-catechol hydrogels with injectability and tunable temperature responsiveness. ACS Appl Mater Interfaces, 2022, 14: 236–244
Wang X, Qiu H, Wu Q, et al. Salt-enhanced CO2-responsiveness of microgels. ACS Macro Lett, 2020, 9: 1611–1616
Gao M, Gawel K, Stokke BT. Polyelectrolyte and antipolyelectrolyte effects in swelling of polyampholyte and polyzwitterionic charge balanced and charge offset hydrogels. Eur Polym J, 2014, 53: 65–74
Zhang D, Fu Y, Huang L, et al. Integration of antifouling and antibacterial properties in salt-responsive hydrogels with surface regeneration capacity. J Mater Chem B, 2018, 6: 950–960
Zheng B, Avni Y, Andelman D, et al. Charge regulation of polyelectrolyte gels: Swelling transition. Macromolecules, 2023, 56: 5217–5224
Bui TQ, Cao VD, Do NBD, et al. Salinity gradient energy from expansion and contraction of poly(allylamine hydrochloride) hydrogels. ACS Appl Mater Interfaces, 2018, 10: 22218–22225
Yu HC, Zheng SY, Fang L, et al. Reversibly transforming a highly swollen polyelectrolyte hydrogel to an extremely tough one and its application as a tubular grasper. Adv Mater, 2020, 32: 2005171
Na H, Kang YW, Park CS, et al. Hydrogel-based strong and fast actuators by electroosmotic turgor pressure. Science, 2022, 376: 301–307
Aleid S, Wu M, Li R, et al. Salting-in effect of zwitterionic polymer hydrogel facilitates atmospheric water harvesting. ACS Mater Lett, 2022, 4: 511–520
Das Mahapatra R, Imani KBC, Yoon J. Integration of macro-cross-linker and metal coordination: A super stretchable hydrogel with high toughness. ACS Appl Mater Interfaces, 2020, 12: 40786–40793
Chen Q, Yan X, Zhu L, et al. Improvement of mechanical strength and fatigue resistance of double network hydrogels by ionic coordination interactions. Chem Mater, 2016, 28: 5710–5720
Henderson KJ, Zhou TC, Otim KJ, et al. Ionically cross-linked triblock copolymer hydrogels with high strength. Macromolecules, 2010, 43: 6193–6201
Lowe AB, McCormick CL. Synthesis and solution properties of zwitterionic polymers. Chem Rev, 2002, 102: 4177–4190
Wang A, Fang W, Zhang J, et al. Zwitterionic nanohydrogels-decorated microporous membrane with ultrasensitive salt responsiveness for controlled water transport. Small, 2020, 16: 1903925
Zhang C, Liu C, Xue X, et al. Salt-responsive self-assembly of luminescent hydrogel with intrinsic gelation-enhanced emission. ACS Appl Mater Interfaces, 2014, 6: 757–762
Li P, Wang Z, Lin X, et al. Muscle-inspired ion-sensitive hydrogels with highly tunable mechanical performance for versatile industrial applications. Sci China Mater, 2022, 65: 229–236
Xiao S, Zhang M, He X, et al. Dual salt- and thermoresponsive programmable bilayer hydrogel actuators with pseudo-interpenetrating double-network structures. ACS Appl Mater Interfaces, 2018, 10: 21642–21653
Shao Z, Wu S, Zhang Q, et al. Salt-responsive polyampholyte-based hydrogel actuators with gradient porous structures. Polym Chem, 2021, 12: 670–679
Wu S, Shao Z, Xie H, et al. Salt-mediated triple shape-memory ionic conductive polyampholyte hydrogel for wearable flexible electronics. J Mater Chem A, 2021, 9: 1048–1061
Li X, Luo F, Sun TL, et al. Effect of salt on dynamic mechanical behaviors of polyampholyte hydrogels. Macromolecules, 2023, 56: 535–544
Arens L, Weißenfeld F, Klein CO, et al. Osmotic engine: Translating osmotic pressure into macroscopic mechanical force via poly(acrylic acid) based hydrogels. Adv Sci, 2017, 4: 1700112
Zavahir S, Krupa I, AlMaadeed SA, et al. Polyzwitterionic hydrogels in engines based on the antipolyelectrolyte effect and driven by the salinity gradient. Environ Sci Technol, 2019, 53: 9260–9268
Zhang S, Lin S, Zhao X, et al. Thermodynamic analysis and material design to enhance chemo-mechanical coupling in hydrogels for energy harvesting from salinity gradients. J Appl Phys, 2020, 128: 044701
Hong Y, Wang Y, Tian Y, et al. Extracting salinity gradient energy via antifouling poly(acrylic acid- co-acrylamide) hydrogels in natural water. ACS Appl Polym Mater, 2021, 3: 6513–6523
Ahmed M, Namboodiri V, Singh AK, et al. How ions affect the structure of water: A combined Raman spectroscopy and multivariate curve resolution study. J Phys Chem B, 2013, 117: 16479–16485
Gao H, Mao J, Cai Y, et al. Euryhaline hydrogel with constant swelling and salinity-enhanced mechanical strength in a wide salinity range. Adv Funct Mater, 2020, 31: 2007664
Perera PN, Browder B, Ben-Amotz D. Perturbations of water by alkali halide ions measured using multivariate Raman curve resolution. J Phys Chem B, 2009, 113: 1805–1809
Schmidt P, Dybal J, Trchová M. Investigations of the hydrophobic and hydrophilic interactions in polymer-water systems by ATR FTIR and Raman spectroscopy. Vibal Spectr, 2006, 42: 278–283
Acknowledgements
This work was financially supported by the National Natural Science Foundation of China (21905009) and the 2023 Beijing Technology and Business University graduate research capacity improvement program project.
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Author contributions Gao H and Cai Y designed and adjusted the experimental program; Yan X, Shi Q, and Tong Y performed the experiments; Yan X processed the data and wrote the manuscript; Gao H, Wu J and Weng Y revised the original manuscript. All authors contributed to the general discussion.
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Conflict of interest The authors declare that they have no conflict of interest.
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Supplementary information Experimental details and supporting data are available in the online version of the paper.
Hainan Gao is currently an associate professor at Beijing Technology and Business University (BTBU). She received her PhD degree from Jilin University in 2014 under the supervision of Prof. Bai Yang. She then worked as a postdoctor in Prof. Lei Jiang’s group at the Institute of Chemistry, Chinese Academic Sciences from 2014 to 2018. Her current research interests focus on basic and applied research on polymer gel-based materials with heteronetworks, mainly including the design, preparation and application of bio-inspired materials.
Xiaocao Yan is currently a Master’s student at BTBU. Her main research interests are the preparation of ionic hydrogels and the study of their salinity sensitivity and tolerance properties.
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Synthesis of salinity ultra-sensitive ionic hydrogels for visual salinity detection and usage as an intelligent liquid valve
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Yan, X., Shi, Q., Cai, Y. et al. Synthesis of salinity ultra-sensitive ionic hydrogels for visual salinity detection and usage as an intelligent liquid valve. Sci. China Mater. 67, 321–330 (2024). https://doi.org/10.1007/s40843-023-2688-y
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DOI: https://doi.org/10.1007/s40843-023-2688-y