Catalysts in Coronas: A Surface Spatial Confinement Strategy for High-Performance Catalysts in Methane Dry Reforming

Abstract: One of the grand challenges in industrial catalytic processes is the inevitable sintering and aggregation of conventional supported catalysts to large particles, leading to the decrease of activity and even deactivation with time. Herein, a surface spatial confinement strategy was employed to design high-performing catalysts for the dry reforming of methane (DRM). Specifically, active nickel (Ni) nanoparticles (NPs) were confined on the surface of a dendritic mesoporous silica (DMS) in the form of the “catalys… Show more

“…Precious metals (e.g., Ru, Rh) exhibit superior activity but are limited and expensive, and thus R&D efforts have been shifted towards abundant and active metals like Ni. 92,94,96,222,343,344 To increase the catalyst performance while retaining its stability and resistance to coke formation, several approaches such as carbon gasification 221,[345][346][347] through introducing redox or basic materials, alloying active metals (e.g., Ni) with other metals, 228,[348][349][350][351] and enhancing the thermal stability of active metal particles by strong interaction with the support or confinement inside stable structures [352][353][354][355] have been attempted. In order to reduce coke formation and improve catalyst stability/activity, numerous strategies involving modification in the catalyst surface composition and metalsupport interaction have been attempted.…”

Mechanistic and multiscale aspects of thermo-catalytic CO₂conversion to C₁products

“…Precious metals (e.g., Ru, Rh) exhibit superior activity but are limited and expensive, and thus R&D efforts have been shifted towards abundant and active metals like Ni. 92,94,96,222,343,344 To increase the catalyst performance while retaining its stability and resistance to coke formation, several approaches such as carbon gasification 221,[345][346][347] through introducing redox or basic materials, alloying active metals (e.g., Ni) with other metals, 228,[348][349][350][351] and enhancing the thermal stability of active metal particles by strong interaction with the support or confinement inside stable structures [352][353][354][355] have been attempted. In order to reduce coke formation and improve catalyst stability/activity, numerous strategies involving modification in the catalyst surface composition and metalsupport interaction have been attempted.…”

Mechanistic and multiscale aspects of thermo-catalytic CO₂conversion to C₁products

“…有序介孔材 料, 如分子筛MCM-41 [149] 、SBA-15 [150] 、KIT-6 [151] 等 都可以被用于Ni基DRM催化剂的载体. 例如, Zhang ; (g) TGA研究催化剂积碳 [148] (网络版彩图) 及花状载 体 [178] 也被用于稳定Ni颗粒, 并在DRM反应中表现出 良好的性能.…”

CH<sub>4</sub>-CO<sub>2</sub> reforming: challenges and outlook

“…14,15 Recently, confined catalysis in emerging porous materials, such as metal-organic frameworks (MOFs), covalent organic frameworks (COFs), and polymer layers, has been considered as an effective strategy in modulating the diffusion and transport of reactants to promote catalysis. 10,16,17 The comprehensive discussion of confinement effects in conventional thermal catalysis can be found elsewhere, 15,16,18 and is beyond the scope of this article.…”

Electrocatalysis in confined spaces: interplay between well-defined materials and the microenvironment