Abstract
Vertically oriented graphene (VG) has attracted attention for years, but the growth mechanism is still not fully revealed. The electric field may play a role, but the direct evidence and exactly what role it plays remains unclear. Here, we conduct a systematic study and find that in plasma-enhanced chemical vapor deposition, the VG growth preferably occurs at spots where the local field is stronger, for example, at GaN nanowire tips. On almost round-shaped nanoparticles, instead of being perpendicular to the substrate, the VG grows along the field direction, that is, perpendicular to the particles’ local surfaces. Even more convincingly, the sheath field is screened to different degrees, and a direct correlation between the field strength and the VG growth is observed. Numerical calculation suggests that during the growth, the field helps accumulate charges on graphene, which eventually changes the cohesive graphene layers into separate three-dimensional VG flakes. Furthermore, the field helps attract charged precursors to places sticking out from the substrate and makes them even sharper and turn into VG. Finally, we demonstrate that the VG-covered nanoparticles are benign to human blood leukocytes and could be considered for drug delivery. Our research may serve as a starting point for further vertical two-dimensional material growth mechanism studies.
Highlights
Oriented graphene (VG) or so called carbon nanowalls are three-dimensional (3D), self-supported, interconnected networks of free-standing graphene sheets, whose orientations are approximately perpendicular to the substrate surface
Trying to grow Vertically oriented graphene (VG) on sharp surfaces is the best way to clarify whether the local electric field is a factor for promoting the VG growth or not
The VG is deposited on GaN nanowires, and it is found that the VG prefers to grow at the sharp tips, where the local electric field is the strongest
Summary
Oriented graphene (VG) or so called carbon nanowalls are three-dimensional (3D), self-supported, interconnected networks of free-standing graphene sheets, whose orientations are approximately perpendicular to the substrate surface. Besides the fact that it possesses extraordinary properties of ordinary graphene, VG itself has unique properties of high specific surface area, mechanical stability, open reactive graphene edges, easy functionalization, and special optical, thermal, and electrical properties.[1−7] Due to these properties, VG has a high potential in a wide range of applications. It has caught a lot of interest in various sectors such as field emission, gas- and bio-sensors, blackbody coating, spintronics, and so forth.[8−14].
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