Towards understanding the lower CH 4 selectivity of HCP-Co than FCC-Co in Fischer-Tropsch synthesis.
Dan LuoXiaoqiang LiuTong ChangJiawei BaiWenping GuoWentao ZhengXiao-Dong WenPublished in: Physical chemistry chemical physics : PCCP (2024)
In Fischer-Tropsch synthesis (FTS), the cobalt catalyst has higher C 5+ and lower CH 4 selectivity in the hcp phase than in the fcc phase. However, a detailed explanation of the intrinsic mechanism is still missing. The underlying reason was explored combining density functional theory, Wulff construction, and a particle-level descriptor based on the slab model of surfaces that are prevalent in the Wulff shape to provide single-particle level understanding. Using a particle-level indicator of the reaction rates, we have shown that it is more difficult to form CH 4 on hcp-Co than on fcc-Co, due to the larger effective barrier difference of CH 4 formation and C-C coupling on hcp-Co particles, which leads to the lower CH 4 selectivity of hcp-Co in FTS. Among the exposed facets of fcc-Co, the (311) surface plays a pivotal role in promoting CH 4 formation. The reduction of CH 4 selectivity in cobalt-based FTS is achievable through phase engineering of Co from fcc to hcp or by tuning the temperature and size of the particles.