Hybridized Graphene(杂化石墨烯)研究综述
Hybridized Graphene 杂化石墨烯 - Using first-principles computations, we proposed a novel design of a nickel single atom catalyst (Ni-SAC) supported by a hybridized graphene–boron nitride monolayer (BCN), to work as a highly active bi-functional electrocatalyst for both HER and OER. [1]使用第一性原理计算,我们提出了一种由杂化石墨烯-氮化硼单层 (BCN) 支持的镍单原子催化剂 (Ni-SAC) 的新设计,可用作 HER 和 OER 的高活性双功能电催化剂. [1]
Sp2 Hybridized Graphene Sp2杂化石墨烯
112 eV) from the sp2 hybridized graphene structures, therefore very good Li-storage performance is expected, indicating that bct-C40 can be used as a high-performance anode material for lithium ion batteries. [1] The exceptional electrical, thermal, optical and mechanical properties have made two dimensional sp2 hybridized graphene a material of choice in both academic as well as industrial research. [2]112 eV) 的 sp2 杂化石墨烯结构,因此有望获得非常好的锂存储性能,表明 bct-C40 可用作锂离子电池的高性能负极材料。 [1] 卓越的电学、热学、光学和机械性能使二维 sp2 杂化石墨烯成为学术和工业研究的首选材料。 [2]
hybridized graphene nanocomposite 杂化石墨烯纳米复合材料
Inspired by this insight, molybdenum carbide hybridized graphene nanocomposite is developed as an anode material for microbial fuel cell through a facile layer-by-layer electrostatic assembly followed by high-temperature carburization approach. [1] A ternary photocatalyst Cu doped (0 to 10 wt%) ZnO-hybridized Graphene nanocomposite (GZCu) was prepared by hydrothermal method. [2]受此启发,碳化钼杂化石墨烯纳米复合材料通过简单的逐层静电组装和高温渗碳方法被开发为微生物燃料电池的阳极材料。 [1] 采用水热法制备了三元光催化剂Cu掺杂(0~10wt%)ZnO杂化石墨烯纳米复合材料(GZCu)。 [2]