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HYDROVOLTAIC ENERGY HARVESTING FROM NUT SHELLS
  • +3
  • NAZMUL HOSSAIN,
  • Roozbeh Abbasi,
  • Weinan Zhao,
  • Xiaoye Zhao,
  • Aiping Yu,
  • Norman Y. Zhou
NAZMUL HOSSAIN
University of Waterloo

Corresponding Author:n3hossai@uwaterloo.ca

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Roozbeh Abbasi
University of Waterloo
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Weinan Zhao
University of Waterloo
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Xiaoye Zhao
University of Waterloo
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Aiping Yu
University of Waterloo
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Norman Y. Zhou
University of Waterloo
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Abstract

Water-induced Electric Generators (WEGs) exhibit tremendous promise as sustainable energy sources harvesting electricity through the interaction between materials and water utilizing the hydrovoltaic effect, an innovative green energy harvesting method. However, existing WEG devices predominantly rely on inorganic materials with limited research on naturally available, bio-based materials for hydrovoltaic energy harvesting. This study introduces a novel nutshell-based hydrovoltaic WEG for the first time. This low-cost, organic, and efficient renewable energy source can generate a voltage above 600 mV with a power density exceeding 5.96 µW·cm−2 utilizing streaming and evaporation potential methodologies, which can be sustained for more than a week. Notably, after further chemical treatments and combining the physical and chemical phenomena, output voltage and maximum current density reach a record high of 1.21 V and 347.2 µA·cm−2respectively, which outperforms most inorganic and organic materials based WEGs. By connecting two units in series and parallel this eco-friendly WEG can power an LCD calculator without the assistance of any rectifier. We believe that this novel nutshell-based WEG provides a significant advancement in WEG technology by offering a sustainable solution for powering electronic devices utilizing agricultural waste.
17 Sep 2024Submitted to Energy & Environmental Materials
19 Sep 2024Submission Checks Completed
19 Sep 2024Assigned to Editor
22 Sep 2024Review(s) Completed, Editorial Evaluation Pending
29 Sep 2024Reviewer(s) Assigned
11 Dec 2024Editorial Decision: Revise Minor