Nano Science and Technology Institute
Nanotech 2005 Vol. 2
Nanotech 2005 Vol. 2
Technical Proceedings of the 2005 NSTI Nanotechnology Conference and Trade Show, Volume 2
 
Chapter 3: Carbon Nano Structures
 

Amorphous Diamond Electron Emission for Thermal Generation of Electricity

Authors:J.C-M Sung, K. Kan, M. Sung, J-L Huang, E. Sung, C-P Chen, K-H Hsu and M-F Tai
Affilation:Kinik Company, TW
Pages:193 - 196
Keywords:amorphous diamond, solar cell, diamond electrode, heat spreader
Abstract:Amorphous diamond represents a class of material of its own. It may be viewed to be a composite of metal (graphite) and insulator (diamond), but together they form a unique passage for electrons to flow through and to emit in vacuum. Amorphous diamond contains much defect so its electrical resistance is intermediate between metal and semiconductor. However, its ability to emit electrons in vacuum as cold cathode outstrips almost any class of materials. The easiness for electrons to flow through amorphous diamond and fly toward an anode across vacuum makes it an ideal material for electrical generator. In fact, the electricity generation can be so easy that amorphous diamond may become the most efficient solar cell ever invented. Moreover, by reversing the role of electricity generation, an amorphous diamond film may become an electron radiator. Such a radiator may dissipate heat much faster than the most advanced heat spreader (e.g., diamond substrate or heat pipe) currently being investigated. Recent experimental results has confirmed that the current of electron emission in vacuum has increased two orders of magnitude when amorphous diamond is heated to 300 oC. Such a dramatic increase of current indicates that thermal energy can indeed shake off electrons in carbon atoms and accelerate them toward an anode across a vacuum. This phenomenon is consistent with the proposal that amorphous diamond can indeed be made of solar cells and/or heat spreaders.
Amorphous Diamond Electron Emission for Thermal Generation of ElectricityView PDF of paper
ISBN:0-9767985-1-4
Pages:808
Hardcopy:$109.95
 
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