Uchida Yuki, Nakandakari Sho, Kawahara Kenji, Yamasaki Shigeto, Mitsuhara Masatoshi, Ago Hiroki
ACS Nano. 2018 Jun 26;12(6):6236-6244. doi: 10.1021/acsnano.8b03055. Epub 2018 Jun 12.
Multilayer hexagonal boron nitride (h-BN) is an ideal insulator for two-dimensional (2D) materials, such as graphene and transition metal dichalcogenides, because h-BN screens out influences from surroundings, allowing one to observe intrinsic physical properties of the 2D materials. However, the synthesis of large and uniform multilayer h-BN is still very challenging because it is difficult to control the segregation process of B and N atoms from metal catalysts during chemical vapor deposition (CVD) growth. Here, we demonstrate CVD growth of multilayer h-BN with high uniformity by using the Ni-Fe alloy film and borazine (BHN) as catalyst and precursor, respectively. Combining Ni and Fe metals tunes the solubilities of B and N atoms and, at the same time, allows one to engineer the metal crystallinity, which stimulates the uniform segregation of multilayer h-BN. Furthermore, we demonstrate that triangular WS grains grown on the h-BN show photoluminescence stronger than that grown on a bare SiO substrate. The PL line width of WS/h-BN (the minimum and mean widths are 24 and 43 meV, respectively) is much narrower than those of WS/SiO (44 and 67 meV), indicating the effectiveness of our CVD-grown multilayer h-BN as an insulating layer. Large-area, multilayer h-BN realized in this work will provide an excellent platform for developing practical applications of 2D materials.
多层六方氮化硼(h-BN)是二维(2D)材料(如石墨烯和过渡金属二卤化物)的理想绝缘体,因为h-BN能屏蔽周围环境的影响,使人们能够观察二维材料的固有物理性质。然而,合成大面积且均匀的多层h-BN仍然极具挑战性,因为在化学气相沉积(CVD)生长过程中,很难控制硼和氮原子从金属催化剂中的分离过程。在此,我们分别使用镍铁合金薄膜和硼嗪(BHN)作为催化剂和前驱体,展示了具有高均匀性的多层h-BN的CVD生长。结合镍和铁金属可调节硼和氮原子的溶解度,同时还能调控金属的结晶度,从而促进多层h-BN均匀分离。此外,我们证明在h-BN上生长的三角形WS晶粒的光致发光比在裸露的SiO衬底上生长的更强。WS/h-BN的光致发光线宽(最小和平均宽度分别为24和43 meV)比WS/SiO的(44和67 meV)窄得多,这表明我们通过CVD生长的多层h-BN作为绝缘层的有效性。这项工作中实现的大面积多层h-BN将为二维材料的实际应用开发提供一个出色的平台。
