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- Title
Electricity generation from carbon dioxide adsorption by spatially nanoconfined ion separation.
- Authors
Wang, Zhuyuan; Hu, Ting; Tebyetekerwa, Mike; Zeng, Xiangkang; Du, Fan; Kang, Yuan; Li, Xuefeng; Zhang, Hao; Wang, Huanting; Zhang, Xiwang
- Abstract
Selective ion transport underpins fundamental biological processes for efficient energy conversion and signal propagation. Mimicking these 'ionics' in synthetic nanofluidic channels has been increasingly promising for realizing self-sustained systems by harvesting clean energy from diverse environments, such as light, moisture, salinity gradient, etc. Here, we report a spatially nanoconfined ion separation strategy that enables harvesting electricity from CO2 adsorption. This breakthrough relies on the development of Nanosheet-Agarose Hydrogel (NAH) composite-based generators, wherein the oppositely charged ions are released in water-filled hydrogel channels upon adsorbing CO2. By tuning the ion size and ion-channel interactions, the released cations at the hundred-nanometer scale are spatially confined within the hydrogel network, while ångström-scale anions pass through unhindered. This leads to near-perfect anion/cation separation across the generator with a selectivity (D-/D+) of up to 1.8 × 106, allowing conversion into external electricity. With amplification by connecting multiple as-designed generators, the ion separation-induced electricity reaching 5 V is used to power electronic devices. This study introduces an effective spatial nanoconfinement strategy for widely demanded high-precision ion separation, encouraging a carbon-negative technique with simultaneous CO2 adsorption and energy generation. Nanogenerators have promising applications in energy and environment-related fields. Here, the authors developed Nanosheet-Agarose Hydrogel generators to enable near-perfect anion/cation separation, leading to simultaneously CO2 adsorption and energy generation.
- Subjects
CARBON dioxide adsorption; ELECTRIC power production; ION channels; IONS; ENERGY harvesting; CLEAN energy; WATER salinization; HYDROGELS
- Publication
Nature Communications, 2024, Vol 15, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-024-47040-x