Abstract
Non-classical crystallization suggests that crystals can grow with nanoparticles as a building block. In this case, the crystallization behavior depends on the size and charge of the nanoparticles. If charged nanoparticles (CNPs) are small enough, they become liquid-like and tend to undergo epitaxial recrystallization. Here, the size effect of SiC CNPs on film crystallinity was studied in the hot-wire chemical vapor deposition process. To do this, SiC nanoparticles were captured under different processing conditions—in this case, wire temperature, precursor concentration and the filament bias. Increasing the temperature of tungsten wires and decreasing the ratio of (SiH4 + CH4)/H2 reduced the size of the SiC nanoparticles. When the nanoparticles were small enough, an epitaxial SiC film approximately 100-nm-thick was grown, whereas larger nanoparticles produced polycrystalline SiC films. These results suggest that the size of the CNPs is an important process variable when growing films by means of non-classical crystallization.
Highlights
A new mechanism of crystal growth has been proposed, in which crystals grow by nanosized-building blocks instead of growing by atoms, molecules or ions [1,2,3,4,5]
In order to explain the deposition of dense films or nanostructures without voids as well as epitaxial film growth via the building block of charged nanoparticles (CNPs), Hwang [10] suggested that the presence of a charge should make the nanoparticles liquid-like, especially when they are small enough
We investigated the effect of the size of charged nanoparticles on the crystallinity of SiC films in the HWCVD process based on non-classical crystallization
Summary
A new mechanism of crystal growth has been proposed, in which crystals grow by nanosized-building blocks instead of growing by atoms, molecules or ions [1,2,3,4,5]. A diamond film grows on a silicon substrate, whereas a porous skeletal soot structure grows on an iron substrate under identical conditions in the diamond chemical vapor deposition (CVD) process using hot wires or plasma [6,7,8]. This new mechanism is called the ‘theory of charged nanoparticles’ (TCN) [9]. In order to explain the deposition of dense films or nanostructures without voids as well as epitaxial film growth via the building block of CNPs, Hwang [10] suggested that the presence of a charge should make the nanoparticles liquid-like, especially when they are small enough
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