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Hauptverfasser: Guo, Jiarui, Hao, Xuanzhang, Yang, Yuxia, Huang, Shaoqi, Qian, Zhihao, Yang, Minhui, Wu, Hanming, Qu, Liangti, S, Novoselov Kostya, Lin, Shisheng
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2507.03874
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author Guo, Jiarui
Hao, Xuanzhang
Yang, Yuxia
Huang, Shaoqi
Qian, Zhihao
Yang, Minhui
Wu, Hanming
Qu, Liangti
S, Novoselov Kostya
Lin, Shisheng
author_facet Guo, Jiarui
Hao, Xuanzhang
Yang, Yuxia
Huang, Shaoqi
Qian, Zhihao
Yang, Minhui
Wu, Hanming
Qu, Liangti
S, Novoselov Kostya
Lin, Shisheng
contents Harnessing energy from ubiquitous water resources via molecular-scale mechanisms remains a critical frontier in sustainable energy research. Herein, we present a novel evaporation-driven power generator based on a dynamic diode architecture that continuously harvests direct current (DC) electricity by leveraging the flipping of the strong built-in electric field (up to 10E10 V/cm) generated by polar molecules such as water to drive directional carrier migration. In our system, water molecules undergo sequential polarization and depolarization at the graphene-water-silicon interface, triggering cycles of charge trapping and release. This nonionic mechanism is driven primarily by the Fermi level difference between graphene and silicon, augmented by the intrinsic dipole moment of water molecules. Structural optimization using graphene enhances evaporation kinetics and interfacial contact, yielding an open-circuit voltage of 0.35 V from a 2 cm * 1 cm device. When four units are connected in series, the system delivers a stable 1.2V output. Unlike ion-mediated energy harvesters, this corrosion-free architecture ensures long-term stability and material compatibility. Our work introduces a fundamentally new approach to water-based power generation, establishing interfacial polarization engineering as a scalable strategy for low-cost, sustainable electricity production from ambient water.
format Preprint
id arxiv_https___arxiv_org_abs_2507_03874
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Water evaporation-driven dynamic diode for direct electricity generation
Guo, Jiarui
Hao, Xuanzhang
Yang, Yuxia
Huang, Shaoqi
Qian, Zhihao
Yang, Minhui
Wu, Hanming
Qu, Liangti
S, Novoselov Kostya
Lin, Shisheng
Atomic Physics
Harnessing energy from ubiquitous water resources via molecular-scale mechanisms remains a critical frontier in sustainable energy research. Herein, we present a novel evaporation-driven power generator based on a dynamic diode architecture that continuously harvests direct current (DC) electricity by leveraging the flipping of the strong built-in electric field (up to 10E10 V/cm) generated by polar molecules such as water to drive directional carrier migration. In our system, water molecules undergo sequential polarization and depolarization at the graphene-water-silicon interface, triggering cycles of charge trapping and release. This nonionic mechanism is driven primarily by the Fermi level difference between graphene and silicon, augmented by the intrinsic dipole moment of water molecules. Structural optimization using graphene enhances evaporation kinetics and interfacial contact, yielding an open-circuit voltage of 0.35 V from a 2 cm * 1 cm device. When four units are connected in series, the system delivers a stable 1.2V output. Unlike ion-mediated energy harvesters, this corrosion-free architecture ensures long-term stability and material compatibility. Our work introduces a fundamentally new approach to water-based power generation, establishing interfacial polarization engineering as a scalable strategy for low-cost, sustainable electricity production from ambient water.
title Water evaporation-driven dynamic diode for direct electricity generation
topic Atomic Physics
url https://arxiv.org/abs/2507.03874