Improving the synthetic efficiency of single-wall carbon nanotube forests using a gas-analysis-designed mixed carbon feedstock
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Title
Improving the synthetic efficiency of single-wall carbon nanotube forests using a gas-analysis-designed mixed carbon feedstock
Authors
Keywords
SWCNT, Forest, Carbon feedstock, Gas analysis, Conversion efficiency
Journal
CARBON
Volume 170, Issue -, Pages 59-65
Publisher
Elsevier BV
Online
2020-08-16
DOI
10.1016/j.carbon.2020.08.001
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- (2018) I. Mitchell et al. CARBON
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- (2011) Satoshi Yasuda et al. NANO LETTERS
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- (2008) L. Qu et al. SCIENCE
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