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微重力环境下高效太阳能氢气生产的实验方法

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Experimental Methods for Efficient Solar Hydrogen Production in Microgravity Environment

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微重力环境下高效太阳能氢气生产的实验方法

DOI:

10.3791/59122-v

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11:38 min

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December 03, 2019

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Katharina Brinkert², Ömer Akay, Matthias H. Richter⁴, Janine Liedtke, Katherine T. Fountaine⁶, Hans-Joachim Lewerenz, Michael Giersig⁸

¹Division of Chemistry and Chemical Engineering,California Institute of Technology, ²European Space Agency/ ESTEC, ³Department of Physics,Freie Universitat Berlin, ⁴Applied Physics and Sensors,Brandenburg University of Technology Cottbus, ⁵Resnick Sustainability Institute,California Institute of Technology, ⁶NG Next,Northrop Grumman Corporation, ⁷Division of Engineering and Applied Science and Joint Center for Artificial Photosynthesis,California Institute of Technology, ⁸International Academy of Optoelectronics at Zhaoqing,South China Normal University

Chapters

00:04Title
00:51Preparation of p-InP (p-type Indium Phosphide) Photoelectrodes
02:38Fabrication of Rhodium Nanostructures
04:23Photoelectrodeposition of Rhodium Nanoparticles
05:22Photoelectrochemical Experiments in Microgravity
08:43Results: p-InP Surface Modification
10:43Conclusion

Summary

자동 번역

最近在不来梅下降塔微重力环境中的光电半电池中实现了高效的太阳能-氢生产。这里，我们报告制造半导体电催化剂装置的实验程序，在落体胶囊的实验设置的细节和自由落体期间的实验序列。

Tags

Keywords: Microgravity Solar Hydrogen Production Nanostructured Photoelectrodes Electrochemical Gas Bubbles Catalyst Hotspots Indium Phosphide Shadow Nanosphere Lithography Rhodium Nanostructures Photoelectrochemical Conditioning

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