Hydrovoltaic Power Generation Depend on Wettability at the Liquid-Solid Interface: Mechanisms, Materials, and Applications With Various Resource

Yejin Lee; Minwoo Lee; Junwoo Lee; Ho Won Jang; Ji-Soo Jang

doi:10.1002/EXP.70007

Exploration ›› 2025, Vol. 5 ›› Issue (2) : 70007 DOI: 10.1002/EXP.70007

REVIEW

Hydrovoltaic Power Generation Depend on Wettability at the Liquid-Solid Interface: Mechanisms, Materials, and Applications With Various Resource

Author information +

History +

PDF

Abstract

With the global increase in energy consumption, there is a growing demand for green energy production, which has prompted the development of novel renewable energy sources. Recently, significant momentum has been observed in research on new energy harvesting methods suitable for small devices. In this context, hydrovoltaic power generation, utilizing water due to its ubiquitous presence and easy availability, has emerged as a promising technology. Hydrovoltaic power generation operates by converting the potential energy of water into electrical energy through the interaction between water and materials capable of inducing an electrical potential gradient. The control of material surface wettability, which determines the interaction with water, plays a crucial role in enhancing the electrical output and long-term stability of power generation systems. This review categorizes the mechanisms of hydrovoltaic power generation into flow and diffusion mechanisms, discussing respective case studies based on hydrophobic and hydrophilic substrates. Additionally, representative materials used in hydrovoltaic power generation are discussed and the potential to expand this technology across various fields based on the diverse resources of water is demonstrated. The review concludes with future perspectives, highlighting the applications of hydrovoltaic power generation across multiple domains and outlining directions for future research and development.

Keywords

energy harvesting / water energy harvesting / hydrovoltaic power generation

Cite this article

Download citation ▾

Yejin Lee, Minwoo Lee, Junwoo Lee, Ho Won Jang, Ji-Soo Jang. Hydrovoltaic Power Generation Depend on Wettability at the Liquid-Solid Interface: Mechanisms, Materials, and Applications With Various Resource. Exploration, 2025, 5(2): 70007 DOI:10.1002/EXP.70007

登录浏览全文

4963

注册一个新账户忘记密码

References

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

[1]

(a)J. Yin, J. Zhou, S. Fang, and W. Guo, “Hydrovoltaic Energy on the Way,” Joule 4 (2020): 1852. (b) L. Li, S. Feng, Y. Bai, et al., “Enhancing Hydrovoltaic Power Generation Through Heat Conduction Effects,” Nature Communications 13 (2022): 1043. (c) H. Lim, M. S. Kim, Y. Cho, et al., “Hydrovoltaic Electricity Generator With Hygroscopic Materials: A Review and New Perspective,” Advanced Materials 36 (2024): 2301080.

[2]	E. F. Moran, M. C. Lopez, N. Moore, N. Müller, and D. W. Hyndman, “Sustainable Hydropower in the 21st Century,” PNAS 115 (2018): 11891.

[3]	G. J. Herbert, S. Iniyan, E. Sreevalsan, and S. Rajapandian, “A Review of Wind Energy Technologies,” Renewable and Sustainable Energy Reviews 11 (2007): 1117.

[4]	A. Roberts, B. Thomas, P. Sewell, Z. Khan, S. Balmain, and J. Gillman, “Current Tidal Power Technologies and Their Suitability for Applications in Coastal and Marine Areas,” Journal of Ocean Engineering and Marine Energy 2 (2016): 227.

[5]

(a)J. Khan and M. H. Arsalan, “Solar Power Technologies for Sustainable Electricity Generation—A Review,” Renewable and Sustainable Energy Reviews 55 (2016): 414. (b) D. Zheng, T. Pauporté, C. Schwob, and L. Coolen, “Models of Light Absorption Enhancement in Perovskite Solar Cells by Plasmonic Nanoparticles,” Exploration 4 (2024): 20220146.

[6]

(a)Y. Lv, “Transitioning to Sustainable Energy: Opportunities, Challenges, and the Potential of Blockchain Technology,” Frontiers in Energy Research 11 (2023): 1258044. (b) M. Bošnjaković, R. Santa, Z. Crnac, and T. Bošnjaković, “Environmental Impact of PV Power Systems,” Sustainability 15 (2023): 11888.

[7]	B. Ramasubramanian, S. Sundarrajan, R. P. Rao, M. Reddy, V. Chellappan, and S. Ramakrishna, “Novel Low-Carbon Energy Solutions for Powering Emerging Wearables, Smart Textiles, and Medical Devices,” Energy & Environmental Science 15 (2022): 4928.

[8]	S. A. Hashemi, S. Ramakrishna, and A. G. Aberle, “Recent Progress in Flexible-Wearable Solar Cells for Self-Powered Electronic Devices,” Energy & Environmental Science 13 (2020): 685.

[9]	W. Ren, Y. Sun, D. Zhao, et al., “High-Performance Wearable Thermoelectric Generator With Self-Healing, Recycling, and Lego-Like Reconfiguring Capabilities,” Science Advances 7 (2021): eabe0586.

[10]	C. Zhang, W. Fan, S. Wang, Q. Wang, Y. Zhang, and K. Dong, “Recent Progress of Wearable Piezoelectric Nanogenerators,” ACS Applied Electronic Materials 3 (2021): 2449.

[11]	D. G. Dassanayaka, T. M. Alves, N. D. Wanasekara, I. G. Dharmasena, and J. Ventura, “Recent Progresses in Wearable Triboelectric Nanogenerators,” Advanced Functional Materials 32 (2022): 2205438.

[12]	(a)H. Su, A. Nilghaz, D. Liu, et al., “Harnessing the Power of Water: A Review of Hydroelectric Nanogenerators,” Nano Energy 116 (2023): 108819. (b) M. Li, C. Li, B. R. Blackman, and E. Saiz, “Energy Conversion Based on Bio-Inspired Superwetting Interfaces,” Matter 4 (2021): 3400.

[13]	H. Wang, Y. Sun, T. He, et al., “Bilayer of Polyelectrolyte Films for Spontaneous Power Generation in Air Up To an Integrated 1000 V Output,” Nature Nanotechnology 16 (2021): 811.

[14]	T. G. Yun, J. Bae, A. Rothschild, and I.-D. Kim, “Transpiration Driven Electrokinetic Power Generator,” ACS Nano 13 (2019): 12703.

[15]	J. Drelich, E. Chibowski, D. D. Meng, and K. Terpilowski, “Hydrophilic and Superhydrophilic Surfaces and Materials,” Soft Matter 7 (2011): 9804.

[16]

(a)G. Xue, Y. Xu, T. Ding, et al., “Water-Evaporation-Induced Electricity With Nanostructured Carbon Materials,” Nature Nanotechnology 12 (2017): 317. (b) L. Li, S. Gao, M. Hao, et al., “A Novel, Flexible Dual-Mode Power Generator Adapted for Wide Dynamic Range of the Aqueous Salinity,” Nano Energy 85 (2021): 105970.

[17]	F. Taherian, V. Marcon, N. F. van der Vegt, and F. Leroy, “What Is the Contact Angle of Water on Graphene?,” Langmuir 29 (2013): 1457.

[18]	A. S. Aji, R. Nishi, H. Ago, and Y. Ohno, “High Output Voltage Generation of Over 5 V From Liquid Motion on Single-Layer MoS2,” Nano Energy 68 (2020): 104370.

[19]

(a)Z. Liu, C. Liu, Z. Chen, et al., “Recent Advances in Two-Dimensional Materials for Hydrovoltaic Energy Technology,” Exploration 3 (2023): 20220061. (b) J. Wang, C.-F. Du, Y. Xue, et al., “MXenes as a Versatile Platform for Reactive Surface Modification and Superior Sodium-Ion Storages,” Exploration 1 (2021): 20210024.

[20]

(a)Y. Guo, K. Xu, C. Wu, J. Zhao, and Y. Xie, “Surface Chemical-Modification for Engineering the Intrinsic Physical Properties of Inorganic Two-Dimensional Nanomaterials,” Chemical Society Reviews 44 (2015): 637. (b) J. Li, J. Liu, C. Chen, et al., “Pt Nanoclusters Anchored on Ordered Macroporous Nitrogen-Doped Carbon for Accelerated Water Dissociation Toward Superior Alkaline Hydrogen Production,” Chemical Engineering Journal 436 (2022): 135186.

[21]	O. Okolie, A. Kumar, C. Edwards, et al., “Bio-Based Sustainable Polymers and Materials: From Processing to Biodegradation,” Journal of Composites Science 7 (2023): 213.

[22]

(a)Y. Yang, H. Deng, and Q. Fu, “Recent Progress on PEDOT:PSS Based Polymer Blends and Composites for Flexible Electronics and Thermoelectric Devices,” Materials Chemistry Frontiers 4 (2020): 3130. (b) X. Y. D. Soo, S. Y. Tan, A. K. H. Cheong, et al., “Electrospun PEO/PEG Fibers as Potential Flexible Phase Change Materials for Thermal Energy Regulation,” Exploration 4 (2024): 20230016.

[23]	B. Koul, D. Yadav, S. Singh, M. Kumar, and M. Song, “Insights Into the Domestic Wastewater Treatment (DWWT) Regimes: A Review,” Water 14 (2022): 3542.

[24]	M. Elimelech and W. A. Phillip, “The Future of Seawater Desalination: Energy, Technology, and the Environment,” Science 333 (2011): 712.

[25]	J. Heikenfeld, A. Jajack, B. Feldman, et al., “Accessing Analytes in Biofluids for Peripheral Biochemical Monitoring,” Nature Biotechnology 37 (2019): 407.

[26]	T. Zhong, H. Guan, Y. Dai, et al., “A Self-Powered Flexibly-Arranged Gas Monitoring System With Evaporating Rainwater as Fuel for Building Atmosphere Big Data,” Nano Energy 60 (2019): 52.

[27]

(a)W. Li, Z. Zheng, H. Liu, and X. Wang, “A Solar-Driven Seawater Desalination and Electricity Generation Integrating System Based on Carbon Black-Decorated Magnetic Phase-Change Composites,” Desalination 562 (2023): 116713. (b) G. M. Xiong, A. T. Do, J. K. Wang, C. L. Yeoh, K. S. Yeo, and C. Choong, “Development of a Miniaturized Stimulation Device for Electrical Stimulation of Cells,” Journal of Biological Engineering 9 (2015): 14.

[28]

(a)J.-M. Zheng, W.-C. Chin, E. Khijniak, E. Khijniak Jr, and G. H. Pollack, “Surfaces and Interfacial Water: Evidence that hydrophilic Surfaces Have Long-Range Impact,” Advances in Colloid and Interface Science 127 (2006): 19. (b) M. A. Henderson, “The Interaction of Water With Solid Surfaces: Fundamental Aspects Revisited,” Surface Science Reports 46 (2002): 1.

[29]	G. A. H. Elton, “Theory of the Streaming Potential,” Nature 161 (1948): 847.

[30]	H.-J. Butt and M. Kappl, “Normal Capillary Forces,” Advances in Colloid and Interface Science 146 (2009): 48.

[31]	D. C. Grahame, “The Electrical Double Layer and the Theory of Electrocapillarity,” Chemical Reviews 41 (1947): 441.

[32]	R. J. Hunter, Zeta Potential in Colloid Science: Principles and Applications (Academic Press, 2013).

[33]

(a)X. Zhou, W. Zhang, C. Zhang, et al., “Harvesting Electricity From Water Evaporation Through Microchannels of Natural Wood,” ACS Applied Materials & Interfaces 12 (2020): 11232. (b) X. Zhao, J. Feng, M. Xiao, et al., “A Simple High Power, Fast Response Streaming Potential/Current-Based Electric Nanogenerator Using a Layer of Al₂O₃ Nanoparticles,” ACS Applied Materials & Interfaces 13 (2021): 27169.

[34]	M. Wu, M. Peng, Z. Liang, et al., “Printed Honeycomb-Structured Reduced Graphene Oxide Film for Efficient and Continuous Evaporation-Driven Electricity Generation From Salt Solution,” ACS Applied Materials & Interfaces 13 (2021): 26989.

[35]	A. Fick, “Ueber Diffusion,” Annalen der Physik 170 (1855): 59.

[36]	Y. Li, J. Cui, H. Shen, et al., “Useful Spontaneous Hygroelectricity From Ambient Air by Ionic Wood,” Nano Energy 96 (2022): 107065.

[37]	H. Cheng, Y. Huang, F. Zhao, et al., “Spontaneous Power Source in Ambient Air of a Well-Directionally Reduced Graphene Oxide Bulk,” Energy & Environmental Science 11 (2018): 2839.

[38]

(a)I. Langmuir, “Surface Electrification Due to the Recession of Aqueous Solutions From Hydrophobic Surfaces,” Journal of the American Chemical Society 60 (1938): 1190. (b) Z. L. Wang and A. C. Wang, “On the Origin of Contact-Electrification,” Materials Today 30 (2019): 34. (c) Z.-H. Lin, G. Cheng, L. Lin, S. Lee, and Z. L. Wang, “Water-Solid Surface Contact Electrification and Its Use for Harvesting Liquid-Wave Energy,” Angewandte Chemie International Edition 52 (2013): 12545.

[39]	J. Yin, X. Li, J. Yu, Z. Zhang, J. Zhou, and W. Guo, “Generating Electricity by Moving a Droplet of Ionic Liquid Along Graphene,” Nature Nanotechnology 9 (2014): 378.

[40]	W. Xu, H. Zheng, Y. Liu, et al., “A Droplet-Based Electricity Generator With High Instantaneous Power Density,” Nature 578 (2020): 392.

[41]	C. Sendner, D. Horinek, L. Bocquet, and R. R. Netz, “Interfacial Water at Hydrophobic and Hydrophilic Surfaces: Slip, Viscosity, and Diffusion,” Langmuir 25 (2009): 10768.

[42]	Z. Sun, L. Feng, X. Wen, L. Wang, X. Qin, and J. Yu, “Ceramic Nanofiber-Based Water-Induced Electric Generator,” ACS Applied Materials & Interfaces 13 (2021): 56226.

[43]	Q. Ma, Q. He, P. Yin, et al., “Rational Design of MOF-Based Hybrid Nanomaterials for Directly Harvesting Electric Energy From Water Evaporation,” Advanced Materials 32 (2020): 2003720.

[44]	P. Xiao, J. He, F. Ni, et al., “Exploring Interface Confined Water Flow and Evaporation Enables Solar-Thermal-Electro Integration Towards Clean Water and Electricity Harvest Via Asymmetric Functionalization Strategy,” Nano Energy 68 (2020): 104385.

[45]	C. Liu, C. Ye, Y. Wu, et al., “Atomic-Scale Engineering Of Cation Vacancies in Two-Dimensional Unilamellar Metal Oxide Nanosheets for Electricity Generation From Water Evaporation,” Nano Energy 110 (2023): 108348.

[46]	C. Shao, B. Ji, T. Xu, et al., “Large-Scale Production of Flexible, High-Voltage Hydroelectric Films Based on Solid Oxides,” ACS Applied Materials & Interfaces 11 (2019): 30927.

[47]	H. Kong, P. Si, M. Li, et al., “Enhanced Electricity Generation From Graphene Microfluidic Channels for Self-Powered Flexible Sensors,” Nano Letters 22 (2022): 3266.

[48]	G. Zhang, Z. Duan, X. Qi, et al., “Harvesting Environment Energy From Water-Evaporation Over Free-Standing Graphene Oxide Sponges,” Carbon 148 (2019): 1.

[49]	X. Liu, H. Gao, J. E. Ward, et al., “Power Generation From Ambient Humidity Using Protein Nanowires,” Nature 578 (2020): 550.

[50]	Q. Hu, Y. Ma, G. Ren, B. Zhang, and S. Zhou, “Water Evaporation-Induced Electricity With Geobacter Sulfurreducens Biofilms,” Science Advances 8 (2022): eabm8047.

[51]	B. Shao, Z. Song, X. Chen, et al., “Bioinspired Hierarchical Nanofabric Electrode for Silicon Hydrovoltaic Device With Record Power Output,” ACS Nano 15 (2021): 7472.

[52]	T. G. Yun, J. Bae, H. G. Nam, et al., “Ion-Permselective Conducting Polymer-Based Electrokinetic Generators With Maximized Utility of Green Water,” Nano Energy 94 (2022): 106946.

[53]

(a)A. Feng, B. J. McCoy, Z. A. Munir, and D. Cagliostro, “Wettability of Transition Metal Oxide Surfaces,” Materials Science and Engineering: A 242 (1998): 50. (b) W. Yang, Y. Zhao, S. Chen, et al., “Defective Indium/Indium Oxide Heterostructures for Highly Selective Carbon Dioxide Electrocatalysis,” Inorganic Chemistry 59 (2020): 12437.

[54]	T. Zhong, H. Li, T. Zhao, H. Guan, L. Xing, and X. Xue, “Self-Powered/Self-Cleaned Atmosphere Monitoring System From Combining Hydrovoltaic, Gas Sensing and Photocatalytic Effects of TiO₂ Nanoparticles,” Journal of Materials Science and Technology 76 (2021): 33.

[55]	J. Bae, T. G. Yun, B. L. Suh, J. Kim, and I.-D. Kim, “Self-Operating Transpiration-Driven Electrokinetic Power Generator With an Artificial Hydrological Cycle,” Energy & Environmental Science 13 (2020): 527.

[56]	Y. Huang, H. Cheng, C. Yang, P. Zhang, Q. Liao, H. Yao, G. Shi, and L. Qu, “Interface-Mediated Hygroelectric Generator With an Output Voltage Approaching 1.5 Volts,” Nature Communications 9 (2018): 4166.

[57]	X. Huangfu, Y. Guo, S. M. Mugo, and Q. Zhang, “Hydrovoltaic Nanogenerators for Self-Powered Sweat Electrolyte Analysis,” Small 19 (2023): 2207134.

[58]	J. S. Jang, Y. Lim, H. Shin, J. Kim, and T. G. Yun, “Bidirectional Water-Stream Behavior on a Multifunctional Membrane for Simultaneous Energy Generation and Water Purification,” Advanced Materials 35 (2023): 2209076.

[59]	(a)S. L.e Bonté, M.-N. Pons, O. Potier, and P. Rocklin, “Relation Between Conductivity and Ion Content in Urban Waste Water,” Revue des Sciences de l'Eau 21 (2008): 429; (b) R. Michalski, “Ion Chromatography Applications in Wastewater Analysis,” Separations 5 (2018): 16.

[60]

(a)J. F. Anthoni, “The Chemical Composition of Seawater,” Magnesium 2701 (2006): e9062; (b) F. J. Millero, R. Feistel, D. G. Wright, and T. J. McDougall, “The Composition of Standard Seawater and the Definition of the Reference-Composition Salinity Scale,” Deep Sea Research Part I: Oceanographic Research Papers 55 (2008): 50.

[61]	Z. Khurshid, I. Warsi, S. F. Moin, P. D. Slowey, M. Latif, S. Zohaib, and M. S. Zafar, “Biochemical Analysis of Oral Fluids for Disease Detection,” Advances in Clinical Chemistry 100 (2021): 205.

[62]	J. Park, S. M. Chang, J. Shin, I. W. Oh, D. G. Lee, H. S. Kim, H. Kang, Y. S. Park, S. Hur, C. Y. Kang, J. M. Baik, J. S. Jang, and H. C. Song, “Bio-Physicochemical Dual Energy Harvesting Fabrics for Self-Sustainable Smart Electronic Suits,” Advanced Energy Materials 13 (2023): 2300530.

[63]	T. Oki and S. Kanae, “Global Hydrological Cycles and World Water Resources,” Science 313 (2006): 1068.

[64]	N. Bizon, N. M. Tabatabaei, F. Blaabjerg, and E. Kurt, Energy Harvesting and Energy Efficiency (Springer, 2017).

[65]	H. Feng, C. Zhao, P. Tan, R. Liu, X. Chen, and Z. Li, “Nanogenerator for Biomedical Applications,” Advanced Healthcare Materials 7 (2018): 1701298.

[66]	R. G. Neo and B. C. Khoo, “Towards a Larger Scale Energy Harvesting from Falling Water Droplets with an Improved Electrode Configuration,” Applied Energy 285 (2021): 116428.

[67]	M. Khondoker, S. Mandal, R. Gurav, and S. Hwang, “Freshwater Shortage, Salinity Increase, and Global Food Production: A Need for Sustainable Irrigation Water Desalination—A Scoping Review,” Earth 4 (2023): 223.

[68]

(a)H. Gul, W. Raza, J. Lee, M. Azam, M. Ashraf, and K.-H. Kim, “Progress in Microbial Fuel Cell Technology for Wastewater Treatment and Energy Harvesting,” Chemosphere 281 (2021): 130828; (b) S. Okabe, “Domestic Wastewater Treatment and Energy Harvesting by Serpentine Up-Flow MFCS Equipped With PVDF-Based Activated Carbon Air-Cathodes and a Low Voltage Booster,” Chem. Eng. J. 380 (2020): 122443.

[69]

(a)B. Shi, Z. Li, and Y. Fan, “Implantable Energy-Harvesting Devices,” Advanced Materials 30 (2018): 1801511; (b) S. Panda, S. Hajra, K. Mistewicz, P. In-na, M. Sahu, P. M. Rajaitha, and H. J. Kim, “Piezoelectric Energy Harvesting Systems for Biomedical Applications,” Nano Energy 100 (2022): 107514.

[70]

(a)R. Luo, J. Dai, J. Zhang, and Z. Li, “Accelerated Skin Wound Healing by Electrical Stimulation,” Advanced Healthcare Materials 10 (2021): 2100557; (b) G. Thakral, J. LaFontaine, B. Najafi, T. K. Talal, P. Kim, and L. A. Lavery, “Electrical Stimulation to Accelerate Wound Healing,” Diabetic Foot & Ankle 4 (2013): 22081.