Chenyang Wu scite author profile

Harvesting energy from water, in the form of raindrops, river, and ocean waves, is of considerable importance and has potential applications in self‐powered electronic devices and large‐scale energy needs. Recently, the droplet‐based electricity generator has shown an increase by several orders of magnitude in electrical output, overcoming the drawback of traditional droplet‐based device limited by interfacial effects. Despite this exciting result, the output performance of this novel droplet‐based electricity generator is limited by relatively low frequency of impinging droplets owing to the formation of a continuous liquid film at high impact frequency, which might hinder its practical applications. To overcome this challenge, here, we report the design of a superhydrophobic surface based droplet electricity generator, referred to as SHS‐DEG, which can timely shed water droplets from the surface without the formation of liquid film at high impact frequency, and thereby generating enhanced average electrical output. Moreover, our SHS‐DEG exhibits many distinctive advantages over conventional design including robustness, long‐term durability, and power generation stability even in harsh environments. We envision that the ability to harvest electrical energy from water droplets at high impact frequency has promising applications in various energy‐harvesting systems.

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Electrochemical reactivity of Co–Li2S nanocomposite for lithium-ion batteries

Zhou

Zhang

et al. 2007

Electrochimica Acta

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Hydrogen storage properties of MgH2/SWNT composite prepared by ball milling

Wang

Yao

et al. 2006

Journal of Alloys and Compounds

127

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A novel photoacoustic nanoprobe of ICG@PEG-Ag₂S for atherosclerosis targeting and imaging in vivo

Zhang

et al. 2016

Nanoscale

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Atherosclerosis is a major cause of cardiovascular and cerebrovascular diseases that have high mortality and disability rates. Because of its unclear pathogenic mechanism and heterogeneous distribution feature, it is still a big challenge to achieve precise diagnosis and therapy of atherosclerosis at its early stage in vivo. Herein, we fabricated a new ICG@PEG-Ag2S nanoprobe by a simple self-assembly of DT-Ag2S QDs, amphipathic C18/PEG polymer molecules and ICG. The ICG@PEG-Ag2S nanoprobe showed relatively long blood retention and was selectively accumulated in the region of atherosclerotic plaque due to the lipophilicity of the C18 chain to the atherosclerosis microenvironment, and thus the atherosclerosis was real-time monitored by high contrast-enhanced photoacoustic (PA) imaging of ICG. Combining the high signal-to-noise ratio (SNR) and high spatial resolution fluorescence imaging of Ag2S QDs in the second near-infrared window (NIR-II) and related histological assessment in vitro, the feasibility of this new nanoprobe for atherosclerosis targeting in an Apoe(-/-) mouse model was verified. Additionally, hemolysis and coagulation assays of the ICG@PEG-Ag2S revealed its decent hemocompatibility and no histological changes were observed in the main organs of the mouse. Such a simple, multifunctional nanoprobe for targeting and PA imaging of atherosclerosis will have a great potential for future clinical applications.

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Chenyang Wu

Bioinspired Multifunctional Anti-icing Hydrogel

Highly efficient solar anti-icing/deicing via a hierarchical structured surface

Effect of carbon/noncarbon addition on hydrogen storage behaviors of magnesium hydride

Design of ultra-stretchable, highly adhesive and self-healable hydrogels via tannic acid-enabled dynamic interactions

Harvesting energy from high‐frequency impinging water droplets by a droplet‐based electricity generator

Electrochemical reactivity of Co–Li2S nanocomposite for lithium-ion batteries

Hydrogen storage properties of MgH2/SWNT composite prepared by ball milling

A novel photoacoustic nanoprobe of ICG@PEG-Ag₂S for atherosclerosis targeting and imaging in vivo

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Chenyang Wu

Bioinspired Multifunctional Anti-icing Hydrogel

Highly efficient solar anti-icing/deicing via a hierarchical structured surface

Effect of carbon/noncarbon addition on hydrogen storage behaviors of magnesium hydride

Design of ultra-stretchable, highly adhesive and self-healable hydrogels via tannic acid-enabled dynamic interactions

Harvesting energy from high‐frequency impinging water droplets by a droplet‐based electricity generator

Electrochemical reactivity of Co–Li2S nanocomposite for lithium-ion batteries

Hydrogen storage properties of MgH2/SWNT composite prepared by ball milling

A novel photoacoustic nanoprobe of ICG@PEG-Ag2S for atherosclerosis targeting and imaging in vivo

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A novel photoacoustic nanoprobe of ICG@PEG-Ag₂S for atherosclerosis targeting and imaging in vivo