Jun Mok Ha, Seoung Ho Lee, Daehyeon Park, Young Jun Yoon, In Mok Yang, Junhyeok Seo, Yong Seok Hwang, Chan Young Lee, Jae Kwon Suk, Jun Kue Park, Sunmog Yeo
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引用次数: 0
Abstract
We present the first work of the synthesis mechanism from graphene quantum dots (GQDs) to carbon nanotubes (CNTs) by an ion-sputtering assisted chemical vapor deposition. During the annealing process, a Pt thin film deposited by the ion-sputtering was dewetted and agglomerated to form many nanometer-sized particles, leading to Pt nanoparticles (PtNPs) that can act as catalysts for creating carbon allotropes. The shape of the allotropes can be effectively tailored from GQDs to CNTs by controlling three key parameters such as the dose of catalytic ions (D), amounts of carbon source (S), and thermal energy (T). In our work, it was clearly proved that the growth control from GQDs to CNTs has a comparably proportional relationship with D and S, but has a reverse proportional relationship with T. Furthermore, high-purity GQDs without any other by-products and the CNTs with the cap of PtNPs were generated. Their shapes were appropriately controlled, respectively, based on the established synthesis mechanism.
我们首次介绍了离子溅射辅助化学气相沉积法从石墨烯量子点(GQDs)到碳纳米管(CNTs)的合成机理。在退火过程中,离子溅射沉积的铂薄膜会脱水并团聚成许多纳米尺寸的颗粒,从而形成铂纳米颗粒(PtNPs),可作为催化剂生成碳异质体。通过控制三个关键参数,如催化离子的剂量(D)、碳源的数量(S)和热能(T),可以有效地定制从 GQDs 到 CNTs 的同素异形体的形状。我们的研究清楚地证明,从 GQDs 到 CNTs 的生长控制与 D 和 S 成比例关系,但与 T 成反比关系。根据既定的合成机制,它们的形状分别得到了适当的控制。
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