This paper reports on the deposition of crystalline single-helix carbon microcoils, in the as-deposited state, by the hot-wire chemical vapor deposition process without any special preparation of nano-sized transition metal catalysts and subsequent post-deposition annealing. Tungsten, originating from the heated tungsten filament, is identified as the catalyst material responsible for the growth of the microcoils. High-resolution transmission spectroscopy, combined with Raman spectroscopy, confirm that the as-deposited microcoils are crystalline, which is induced by the high deposition temperature in the vicinity of the heated filament. These results suggest a simplified, less tedious deposition process for the growth of carbon microcoils, once the process has been optimized.
Reference:
Oliphant, CJ, Arendse, CJ, Malgas, GF et al. 2009. Dual catalytic purpose of the tungsten filament during the synthesis of single-helix carbon microcoils by hot-wire CVD. Journal of Nanoscience and Nanotechnology, Vol. 9(10), pp 5870-5873
Oliphant, C., Arendse, C., Malgas, G., Motaung, D., Muller, T., & Knoesen, D. (2009). Dual catalytic purpose of the tungsten filament during the synthesis of single-helix carbon microcoils by hot-wire CVD. http://hdl.handle.net/10204/3726
Oliphant, CJ, CJ Arendse, GF Malgas, DE Motaung, TFG Muller, and D Knoesen "Dual catalytic purpose of the tungsten filament during the synthesis of single-helix carbon microcoils by hot-wire CVD." (2009) http://hdl.handle.net/10204/3726
Oliphant C, Arendse C, Malgas G, Motaung D, Muller T, Knoesen D. Dual catalytic purpose of the tungsten filament during the synthesis of single-helix carbon microcoils by hot-wire CVD. 2009; http://hdl.handle.net/10204/3726.
Copyright: 2009 American Scientific Publishers. This is the author's version of the work. It is posted here by permission of American Scientific Publishers for your personal use. Not for redistribution. The definitive version was published in the Journal of Nanoscience and Nanotechnology, Vol. 9(10), pp 5870-5873
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