Portable Integrated Composite Aerogels for High-Power Electricity Generation and Efficient Seawater Desalination

Rong Chen; Shengze Hu; Junye Chen; Enhao Zhang; Wei Chen; Yutong Huang; Wenjie Dou; Chaohui Wang; Xuyang Tang; Weitong Chen; Quanzhen Zhang; Baofei Hou; Denan Kong; Haifei Wu; Qiaojun Cao; Xianbao Wang; Xu Han; Weidong Dou

doi:10.1021/acs.nanolett.6c00700

Portable Integrated Composite Aerogels for High-Power Electricity Generation and Efficient Seawater Desalination

Rong Chen
, Shengze Hu
, Junye Chen
, Enhao Zhang
, Wei Chen
, Yutong Huang
, Wenjie Dou
, Chaohui Wang
, Xuyang Tang
, Weitong Chen
, Quanzhen Zhang
, Baofei Hou^*
, Denan Kong^*
, Haifei Wu
, Qiaojun Cao
, Xianbao Wang^*
, Xu Han
, Weidong Dou^*

^*Corresponding author for this work

Shaoxing University
Beijing Institute of Technology
Hubei University
National University of Singapore

Research output: Contribution to journal › Letter › peer-review

Abstract

Hydrovoltaic generators (HVGs) harness energy from ubiquitous water to generate electricity, offering a promising strategy for a next-generation energy conversion system. However, the integration of power generation and seawater desalination remains challenging. This work demonstrates an integrated-aerogel-based hydrovoltaic generator (IA-HVG) constructed by a sponge-like architecture and asymmetric copper–aluminum electrodes, enabling both evaporation-driven electricity generation and seawater desalination. The porous structure combined with an asymmetric electrode design promotes water transport and interfacial interaction, enhancing ion generation and directional migration. Notably, the IA-HVG device achieves a seawater evaporation rate of 1.76 kg m^–2 h^–1 under 1 sun and exhibits a remarkable power density of 657.80 μW cm^–2, representing an order-of-magnitude improvement over conventional HVGs. Furthermore, its output can be readily scaled up in different configurations. This work offers a simple and efficient approach for evaporation-driven water–electricity cogeneration systems.

Original language	English
Pages (from-to)	5839-5847
Number of pages	9
Journal	Nano Letters
Volume	26
Issue number	17
DOIs	https://doi.org/10.1021/acs.nanolett.6c00700
Publication status	Published - 6 May 2026
Externally published	Yes

Keywords

integrated-aerogel-based hydrovoltaic generator
seawater desalination
sponge-like architecture
water evaporation

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10.1021/acs.nanolett.6c00700

Cite this

Chen, R., Hu, S., Chen, J., Zhang, E., Chen, W., Huang, Y., Dou, W., Wang, C., Tang, X., Chen, W., Zhang, Q., Hou, B., Kong, D., Wu, H., Cao, Q., Wang, X., Han, X., & Dou, W. (2026). Portable Integrated Composite Aerogels for High-Power Electricity Generation and Efficient Seawater Desalination. Nano Letters, 26(17), 5839-5847. https://doi.org/10.1021/acs.nanolett.6c00700

@article{3ef4da97dca946f39affaeab80914e9f,

title = "Portable Integrated Composite Aerogels for High-Power Electricity Generation and Efficient Seawater Desalination",

abstract = "Hydrovoltaic generators (HVGs) harness energy from ubiquitous water to generate electricity, offering a promising strategy for a next-generation energy conversion system. However, the integration of power generation and seawater desalination remains challenging. This work demonstrates an integrated-aerogel-based hydrovoltaic generator (IA-HVG) constructed by a sponge-like architecture and asymmetric copper–aluminum electrodes, enabling both evaporation-driven electricity generation and seawater desalination. The porous structure combined with an asymmetric electrode design promotes water transport and interfacial interaction, enhancing ion generation and directional migration. Notably, the IA-HVG device achieves a seawater evaporation rate of 1.76 kg m–2 h–1 under 1 sun and exhibits a remarkable power density of 657.80 μW cm–2, representing an order-of-magnitude improvement over conventional HVGs. Furthermore, its output can be readily scaled up in different configurations. This work offers a simple and efficient approach for evaporation-driven water–electricity cogeneration systems.",

keywords = "integrated-aerogel-based hydrovoltaic generator, seawater desalination, sponge-like architecture, water evaporation",

author = "Rong Chen and Shengze Hu and Junye Chen and Enhao Zhang and Wei Chen and Yutong Huang and Wenjie Dou and Chaohui Wang and Xuyang Tang and Weitong Chen and Quanzhen Zhang and Baofei Hou and Denan Kong and Haifei Wu and Qiaojun Cao and Xianbao Wang and Xu Han and Weidong Dou",

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doi = "10.1021/acs.nanolett.6c00700",

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TY - JOUR

T1 - Portable Integrated Composite Aerogels for High-Power Electricity Generation and Efficient Seawater Desalination

AU - Chen, Rong

AU - Hu, Shengze

AU - Chen, Junye

AU - Zhang, Enhao

AU - Chen, Wei

AU - Huang, Yutong

AU - Dou, Wenjie

AU - Wang, Chaohui

AU - Tang, Xuyang

AU - Chen, Weitong

AU - Zhang, Quanzhen

AU - Hou, Baofei

AU - Kong, Denan

AU - Wu, Haifei

AU - Cao, Qiaojun

AU - Wang, Xianbao

AU - Han, Xu

AU - Dou, Weidong

PY - 2026/5/6

Y1 - 2026/5/6

N2 - Hydrovoltaic generators (HVGs) harness energy from ubiquitous water to generate electricity, offering a promising strategy for a next-generation energy conversion system. However, the integration of power generation and seawater desalination remains challenging. This work demonstrates an integrated-aerogel-based hydrovoltaic generator (IA-HVG) constructed by a sponge-like architecture and asymmetric copper–aluminum electrodes, enabling both evaporation-driven electricity generation and seawater desalination. The porous structure combined with an asymmetric electrode design promotes water transport and interfacial interaction, enhancing ion generation and directional migration. Notably, the IA-HVG device achieves a seawater evaporation rate of 1.76 kg m–2 h–1 under 1 sun and exhibits a remarkable power density of 657.80 μW cm–2, representing an order-of-magnitude improvement over conventional HVGs. Furthermore, its output can be readily scaled up in different configurations. This work offers a simple and efficient approach for evaporation-driven water–electricity cogeneration systems.

AB - Hydrovoltaic generators (HVGs) harness energy from ubiquitous water to generate electricity, offering a promising strategy for a next-generation energy conversion system. However, the integration of power generation and seawater desalination remains challenging. This work demonstrates an integrated-aerogel-based hydrovoltaic generator (IA-HVG) constructed by a sponge-like architecture and asymmetric copper–aluminum electrodes, enabling both evaporation-driven electricity generation and seawater desalination. The porous structure combined with an asymmetric electrode design promotes water transport and interfacial interaction, enhancing ion generation and directional migration. Notably, the IA-HVG device achieves a seawater evaporation rate of 1.76 kg m–2 h–1 under 1 sun and exhibits a remarkable power density of 657.80 μW cm–2, representing an order-of-magnitude improvement over conventional HVGs. Furthermore, its output can be readily scaled up in different configurations. This work offers a simple and efficient approach for evaporation-driven water–electricity cogeneration systems.

KW - integrated-aerogel-based hydrovoltaic generator

KW - seawater desalination

KW - sponge-like architecture

KW - water evaporation

UR - https://www.scopus.com/pages/publications/105037952922

U2 - 10.1021/acs.nanolett.6c00700

DO - 10.1021/acs.nanolett.6c00700

M3 - Letter

AN - SCOPUS:105037952922

SN - 1530-6984

VL - 26

SP - 5839

EP - 5847

JO - Nano Letters

JF - Nano Letters

IS - 17

ER -

Portable Integrated Composite Aerogels for High-Power Electricity Generation and Efficient Seawater Desalination

Abstract

Keywords

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