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Prof. Liangti QU

Prof. Liangti QU

Professor

Tsinghua University

  • lqu@mail.tsinghua.edu.cn
  • Carbon nanomaterials, graphene, carbon nanotubes, conductive and functional polymers

簡歷

 

Liangti QU is a Professor of Chemistry at Tsinghua University. Research interest in material chemistry mainly focuses on controllable preparation, functional modification and assembly of conductive and functional polymers, and carbon nano materials, such as graphene and carbon nanotubes., and meanwhile to explore their applications in advanced functional materials, efficient energy conversion and storage. The research fields include nano chemistry and material chemistry, electrochemistry, green energy, flexible electronics and energy storage devices. Examples include graphene superstructure, intelligent response polymer, seawater desalination, air power generation, new electrochemical batteries / capacitors, micro energy devices and flexible devices. He has published more than 300 SCI papers in international important journals such as Science, Nature Nanotechnology, Nature Communications, Advanced Materials, Journal of the American Chemical Society, etc., with more than 20000 citations and more than 2600 citations for a single paper. He is one of the most cited researchers in materials science (Elsevier).

Moisture Power: A New Type of Clean Energy

 

Abstract

Harvesting energy from clean and renewable sources has boomed the development of diverse electrical generators to satisfy the growing demand of electricity in our daily life. Moisture enabled electric generator (MEG) is proposed as a means to produce electric power from air by absorbing gaseous or vaporous water molecules, which are ubiquitous in the atmosphere. In this regard, we designed and developed a series of graphene based MEGs with a heterogeneous structure and interface mediation between electrodes/materials with Schottky junctions. Benefiting from the functional groups-reconfiguration and inner protons asymmetrical distribution, the asymmetric porous graphene oxide membrane can proactively generate a sustained electrical voltage approaching 1.5 V. High voltage of up to 1000 V can be easily reached by simply scaling up the number of MEG units in series, enough to drive many commercial electronic devices such as liquid crystal displays (LCD) and light-emitting diodes (LED). This work provides insight for the design and development of MEGs that may promote the efficient conversion of potential energy in the environmental atmosphere to electricity for practical applications.

 

 

 

 

 

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