Catalytic and photocatalytic epoxidation over microporous titanosilicates with nanosheet or layered structure

Bulky epoxides are industrially produced by organic synthesis in multistep procedures, generating significant amounts of waste products in the process. Efficient catalyst in combination with a simple oxidant (H2O2 or O2) would significantly reduce the waste production. Four types of microporous titanosilicates with extra-large pores (Ti-UTL), and shortened diffusion pathways (L-TS, Ti-MCM-22, and Ti-SPP) were prepared and investigated in the epoxidation of cyclooctene with H2O2 and photocatalytic oxidation using O2. Ti-UTL is a zeolite possessing 14-12-ring channel system. L-TS-1 and Ti-MCM-22 are composed of aggregates of titanosilicate nanosheets with the thickness of ca. 2 nm and hexagonal thin platelets, respectively. Ti-SPP is composed of olive-like aggregates with approximately length of 0.88-1.12 mu m and width of 0.44-0.68 mu m consisting of intergrown (self-pillared) nanosheets having 13-70 nm in size. In the epoxidation with H2O2 as an oxidant, Ti-MCM-22 showed the highest catalytic activity due to the wide interlayer space, which enhanced the accessibility of cyclooctene to active titanium site. While, in the photocatalytic epoxidation in the presence of O2 instead of H2O2, Ti-UTL showed the highest activity. The incorporated germanium atoms, which is indispensable component for the construction of extra-large pores, may affect the electronic properties of active titanium species, leading to high photocatalytic activity.

Automated summary

By conducting experiments, it was found that four types of microporous titanosilicates exhibit different catalytic activities in the epoxidation process. Ti-MCM-22 showed the highest activity in epoxidation with H2O2 due to its wide interlayer space, while Ti-UTL exhibited the highest activity in photocatalytic epoxidation with O2, possibly influenced by the incorporated germanium atoms.