Transition Metal Oxodiperoxo Complex Modified Metal-Organic Frameworks as Catalysts for the Selective Oxidation of Cyclohexane

In this work, a series of modified metal-organic frameworks (MOFs) have been prepared by pre- and post-treatment with transition metal oxodiperoxo complexes (MoO(O₂)₂, WO(O₂)₂, and KVO(O₂)₂). The obtained materials are characterized by XRD, FTIR, SEM, TEM, inductively coupled plasma atomic emission spectrometry (ICP-AES), and X-ray photoelectron spectroscopy (XPS), as well as by N₂ adsorption/desorption measurement. The characterization results show that transition metal oxodiperoxo complexes are uniformly incorporated into the MOF materials without changing the basic structures. The performance of cyclohexane oxidation on metal oxodiperoxo complex modified MOFs are evaluated. UiO-67-KVO(O₂)₂ shows the best performance for cyclohexane oxidation, with 78% selectivity to KA oil (KA oil refers to a cyclohexanol and cyclohexanone mixture) at 9.4% conversion. The KA selectivity is found to depend on reaction time, while hot-filtration experiments indicates that the catalytic process is heterogeneous with no leaching of metal species.

Direct glycol assisted synthesis of an amorphous mesoporous silicate with framework incorporated Co2+: characterization and catalytic application in ethylbenzene oxidation

Exclusive Co²⁺ incorporation into the framework of a TUD-1 type silicate was obtained using tetraethylene glycol (TEG) as a non-surfactant structure directing agent which was shown to be active for ethylbenzene oxidation.

TUD-1: synthesis and application of a versatile catalyst, carrier, material…

Mesoporous TUD-1 and M-TUD-1 are straightforward to prepare via an environmentally benign synthesis. The resulting materials are excellent catalysts for oxidations, C–C bond forming reactions and photocatalysis. Furthermore the materials have shown potential for the slow release of drugs and as contrast agents.

The three-dimensional sponge-like mesoporous material TUD-1 is straightforward to prepare. Its synthesis can readily be modified to introduce metals into the framework of TUD-1, imparting many different catalytic activities. M-TUD-1 catalysts have proven to be very active, unlimited by diffusion and very stable. By combining two metals into one TUD-1 catalyst, synergy between Lewis and Brønsted acid sites could be induced; incorporation of zeolites similarly gave rise to synergy. In addition to successful applications in redox-, acid- and photo-catalysis TUD-1 proved to be an excellent carrier material for catalysts, enabling new applications. TUD-1 was used as a contrast agent and drug delivery system, indicating that this material is but at the beginning of its potential applications.