Ionic Power Generation on a Scalable Cellulose@polypyrrole Membrane: The Role of Water and Thermal Gradients

Chenyu Liu, Jixiang Gui, Danhong Li, Zhongxin Liu, Yijun Shen, Wei Huang, Huihui Wang, Xinlong Tian

Advanced Fiber Materials ›› 2024, Vol. 6 ›› Issue (1) : 243-251. DOI: 10.1007/s42765-023-00353-w
Research Article

Ionic Power Generation on a Scalable Cellulose@polypyrrole Membrane: The Role of Water and Thermal Gradients

Author information +
History +

Abstract

The integration of ionic power generation with solar-driven water evaporation presents a promising solution to the critical global problems of freshwater scarcity and clean energy deficiency. In this work, a scalable normal temperature chemical vapor deposition (CVD) method is applied for the first time to the fabrication of a cellulose@polypyrrole (CC@PPy) membrane with efficient ionic power generation performance. The excellent ionic power generation is intimately related to the water and thermal gradients across the membrane, which not only induces fast water evaporation but also synergistically promotes the transport of counterions in charged nanochannels, and the corresponding mechanism is attributed to the streaming potential resulting from the ionic electrokinetic effect and the ionic thermoelectric potential originating from the Soret effect. Under one sun illumination, the CC@PPy film can produce a sustained voltage output of ~ 0.7 V and a water evaporation rate up to 1.67 kg m−2 h−1 when an adequate water supply is available. This study provides new methods for the scalable fabrication of ionic power generation membranes and a design strategy for high-performance solar power generators.

Keywords

Ionic power generation / Water gradient / Thermal gradient / Electrokinetic effect / Soret effect

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾
Chenyu Liu, Jixiang Gui, Danhong Li, Zhongxin Liu, Yijun Shen, Wei Huang, Huihui Wang, Xinlong Tian. Ionic Power Generation on a Scalable Cellulose@polypyrrole Membrane: The Role of Water and Thermal Gradients. Advanced Fiber Materials, 2024, 6(1): 243‒251 https://doi.org/10.1007/s42765-023-00353-w

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1.]
Chen CJ, Kuang YD, Hu LB. Challenges and opportunities for solar evaporation. Joule, 2019, 3: 683,
CrossRef Google scholar
[2.]
Gao MM, Zhu LL, Peh CK, Ho GW. Solar absorber material and system designs for photothermal water vaporization towards clean water and energy production. Energy Environ Sci, 2019, 12: 841,
CrossRef Google scholar
[3.]
Xue GB, Xu Y, Ding TP, Li J, Yin J, Fei WW, Cao YZ, Yu J, Yuan LY, Gong L, Chen J, Deng SZ, Zhou J, Guo WL. Water-evaporation-induced electricity with nanostructured carbon materials. Nat Nanotechnol, 2017, 12: 317,
CrossRef Pubmed Google scholar
[4.]
Gui JX, Li CC, Cao Y, Liu ZX, Shen YJ, Huang W, Tian XL. Hybrid solar evaporation system for water and electricity co-generation: Comprehensive utilization of solar and water energy. Nano Energy, 2023, 107,
CrossRef Google scholar
[5.]
Zhang L, Xu ZY, Zhao L, Bhatia B, Zhong Y, Gong S, Wang EN. Passive, high-efficiency thermally-localized solar desalination. Energy Environ Sci, 2021, 14: 1771,
CrossRef Google scholar
[6.]
Yin J, Zhou JX, Fang SM, Guo WL. Hydrovoltaic energy on the way. Joule, 2020, 4: 1852,
CrossRef Google scholar
[7.]
Liu J, Gui JX, Zhou WT, Tian XL, Liu ZX, Wang JQ, Liu J, Yang L, Zhang P, Huang W, Tu JC, Cao Y. Self-regulating and asymmetric evaporator for efficient solar water-electricity generation. Nano Energy, 2021, 86,
CrossRef Google scholar
[8.]
Zhou XB, Zhang WL, Zhang CL, Tan Y, Guo JC, Sun ZN, Deng X. Harvesting electricity from water evaporation through microchannels of natural wood. ACS Appl Mater Interfaces, 2020, 12: 11232,
CrossRef Pubmed Google scholar
[9.]
van der Heyden FH, Bonthuis DJ, Stein D, Meyer C, Dekker C. Electrokinetic energy conversion efficiency in nanofluidic channels. Nano Lett, 2006, 6: 2232,
CrossRef Pubmed Google scholar
[10.]
Wu YD, Qian YC, Niu B, Chen JJ, He XF, Yang LS, Kong XY, Zhao YF, Lin XB, Zhou T, Jiang L, Wen LP. Surface charge regulated asymmetric ion transport in nanoconfined space. Small, 2021, 17: 2101099,
CrossRef Google scholar
[11.]
Grahame DC. The electrical double layer and the theory of electrocapillarity. Chem Rev, 1947, 41: 441,
CrossRef Pubmed Google scholar
[12.]
Gong BY, Yang HC, Wu SH, Tian YK, Guo XZ, Xu CX, Kuang WH, Yan JH, Cen KF, Bo Z, Ostrikov K. Multifunctional solar bamboo straw: multiscale 3D membrane for self-sustained solar-thermal water desalination and purification and thermoelectric waste heat recovery and storage. Carbon, 2021, 171: 359,
CrossRef Google scholar
[13.]
Fang SM, Chu WC, Tan J, Guo WL. The mechanism for solar irradiation enhanced evaporation and electricity generation. Nano Energy, 2022, 101,
CrossRef Google scholar
[14.]
Zhou SY, Qiu Z, Strømme M, Xu C. Solar-driven ionic power generation via a film of nanocellulose @ conductive metal–organic framework. Energy Environ Sci, 2021, 14: 900,
CrossRef Google scholar
[15.]
He N, Wang HN, Li F, Jiang B, Tang DW, Li L. Ion engines in hydrogels boosting hydrovoltaic electricity generation. Energy Environ Sci. 2023.
[16.]
Gan WT, Chen CJ, Giroux M, Zhong G, Goyal MM, Wang YL, Ping WW, Song JW, Xu SM, He SM, Jiao ML, Wang C, Hu LB. Conductive wood for high-performance structural electromagnetic interference shielding. Chem Mater, 2020, 32: 5280,
CrossRef Google scholar
[17.]
Lu K, Liu C, Liu J, He Y, Tian X, Liu Z, Cao Y, Shen Y, Huang W, Zhang K. Hierarchical natural pollen cell-derived composite sorbents for efficient atmospheric water harvesting. ACS Appl Mater Interfaces, 2022, 14: 33032,
CrossRef Google scholar
[18.]
Wang X, Liu Q, Wu S, Xu B, Xu H. Multilayer polypyrrole nanosheets with self-organized surface structures for flexible and efficient solar-thermal energy conversion. Adv Mater, 2019, 31,
CrossRef Pubmed Google scholar
[19.]
Wang XF, Lin FR, Wang X, Fang SM, Tan J, Chu WC, Rong R, Yin J, Zhang ZH, Liu YP, Guo WL. Hydrovoltaic technology: from mechanism to applications. Chem Soc Rev, 2022, 51: 4902,
CrossRef Pubmed Google scholar
[20.]
Shao BB, Song ZH, Chen X, Wu YF, Li YJ, Song CC, Yang F, Song T, Wang YS, Lee S-T, Sun B. Bioinspired hierarchical nanofabric electrode for silicon hydrovoltaic device with record power output. ACS Nano, 2021, 15: 7472,
CrossRef Pubmed Google scholar
[21.]
Sun ZY, Wen X, Wang LM, Yu JY, Qin XH. Capacitor-inspired high-performance and durable moist-electric generator. Energy Environ Sci, 2022, 15: 4584,
CrossRef Google scholar
[22.]
Zhu ZP, Wang DY, Tian Y, Jiang L. Ion/molecule transportation in nanopores and nanochannels: from critical principles to diverse functions. J Am Chem Soc, 2019, 141: 8658,
CrossRef Pubmed Google scholar
[23.]
Wu YD, Zhou T, Wang Y, Qian YC, Chen WP, Zhu CC, Niu B, Kong XY, Zhao YF, Lin XB, Jiang L, Wen LP. The synergistic effect of space and surface charge on nanoconfined ion transport and nanofluidic energy harvesting. Nano Energy, 2022, 92,
CrossRef Google scholar
[24.]
Xiao K, Jiang L, Antonietti M. Ion transport in nanofluidic devices for energy harvesting. Joule, 2019, 3: 2364,
CrossRef Google scholar
[25.]
Xie JH, Wang YF, Chen SG. Textile-based asymmetric hierarchical systems for constant hydrovoltaic electricity generation. Chem Eng J, 2022, 431,
CrossRef Google scholar
[26.]
He XY, Gu JT, Hao YN, Zheng MR, Wang LM, Yu JY, Qin XH. Continuous manufacture of stretchable and integratable thermoelectric nanofiber yarn for human body energy harvesting and self-powered motion detection. Chem Eng J, 2022, 450,
CrossRef Google scholar
[27.]
He XY, Shi J, Hao YN, He MT, Cai JX, Qin XH, Wang LM, Yu JY. Highly stretchable, durable, and breathable thermoelectric fabrics for human body energy harvesting and sensing. Carbon Energy, 2022, 4: 621,
CrossRef Google scholar
[28.]
Zhao D, Wang H, Khan ZU, Chen JC, Gabrielsson R, Jonsson MP, Berggren M, Crispin X. Ionic thermoelectric supercapacitors. Energy Environ Sci, 2016, 9: 1450,
CrossRef Google scholar
[29.]
Wang H, Ail U, Gabrielsson R, Berggren M, Crispin X. Ionic seebeck effect in conducting polymers. Adv Energy Mater, 2015, 5: 1500044,
CrossRef Google scholar
[30.]
Wang LM, He XY, Hao Y, Zheng MR, Wang RW, Yu JY, Qin XH. Rational design of stretchable and highly aligned organic/inorganic hybrid nanofiber films for multidirectional strain sensors and solar-driven thermoelectrics. Sci China Mater, 2023, 66: 707,
CrossRef Google scholar
[31.]
Li L, Feng S, Bai Y, Yang X, Liu M, Hao M, Wang S, Wu Y, Sun F, Liu Z, Zhang T. Enhancing hydrovoltaic power generation through heat conduction effects. Nat Commun, 2022, 13: 1043, pmcid: 8873497
CrossRef Pubmed Google scholar
[32.]
Liu YF, Cui MW, Ling W, Cheng LK, Lei H, Li WZ, Huang Y. Thermo-electrochemical cells for heat to electricity conversion: from mechanisms, materials, strategies to applications. Energy Environ Sci, 2022, 15: 3670,
CrossRef Google scholar
[33.]
Lin YW, Xu H, Shan XL, Di YS, Zhao AQ, Hu YJ, Gan ZX. Solar steam generation based on photothermal effect: from designs to applications, and beyond. J Mater Chem A, 2019, 7: 19203,
CrossRef Google scholar
[34.]
Shen D, Duley WW, Peng P, Xiao M, Feng J, Liu L, Zou G, Zhou YN. Moisture-enabled electricity generation: from physics and materials to self-powered applications. Adv Mater, 2020, 32,
CrossRef Pubmed Google scholar
[35.]
Huang W, Hu GY, Tian C, Wang XH, Tu JC, Cao Y, Zhang KX. Nature-inspired salt resistant polypyrrole-wood for highly efficient solar steam generation. Sustain Energy Fuels, 2019, 3: 3000,
CrossRef Google scholar
Funding
National Natural Science Foundation of China(22368019); Key Research and Development Project of Hainan Province(ZDYF2022SHFZ053); Science and Technology Innovation Talent Platform Fund for South China Sea New Star of Hainan Province(NHXXRCXM202305); Open Research Project of State Key Laboratory of Marine Resource Utilization in South China Sea(MRUKF2023020)

Accesses

Citations

Detail
Sections
Recommended

/