Abstract
Carbon nanotube (CNT) growth has been demonstrated recently using a number of nonmetallic semiconducting and metal oxide nanoparticles, opening up pathways for direct CNT synthesis from a number of more desirable templates without the need for metallic catalysts. However, CNT growth mechanisms using these nonconventional catalysts has been shown to largely differ and reamins a challenging synthesis route. In this contribution we show CNT growth from partially oxidized silicon nanocrystals (Si NCs) that exhibit quantum confinement effects using a microwave plasma enhanced chemical vapor deposition (PECVD) method. On the basis of solvent and a postsynthesis frgamentation process, we show that oxidation of our Si NCs can be easily controlled. We determine experimentally and explain with theoretical simulations that the Si NCs morphology together with a necessary shell oxide of ∼1 nm is vital to allow for the nonmetallic growth of CNTs. On the basis of chemical analysis post-CNT-growth, we give insight into possible mechanisms for CNT nucleation and growth from our partially oxidized Si NCs. This contribution is of significant importance to the improvement of nonmetallic catalysts for CNT growth and the development of Si NC/CNT interfaces.
Highlights
Two of the most environmentally friendly and abundant elements are carbon (C) and silicon (Si)
We demonstrate in this study the synthesis and production of a nanoscale composite of Si nanocrystals (Si NCs)/Carbon nanotube (CNT) using a microwave plasma-enhanced chemical vapor deposition (PECVD) process
It is known that SiO2 does not have the carbon solubility and catalytic function to decompose hydrocarbons, which is typical in metal catalysts used for CNT growth, carbon solubility in metal catalysts such as Fe has been shown to be extremely sensitive to changes in temperature and catalyst size.[52]
Summary
Two of the most environmentally friendly and abundant elements are carbon (C) and silicon (Si). Once Si nanocrystals (Si NCs) are synthesized with diameters that are comparable to or below the Bohr radius (
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