Publications

Two-fold interpenetration zinc-based metal-organic framework/graphene oxide (TMU-16-NH2/GO) nanohybrid materials were synthesized under a green, simple and large-scale sonochemical preparation method at room temperature and atmospheric pressure. Moreover, the role of concentrations of graphene oxide on size and morphology of nanostructures TMU-16-NH2/GO hybrid have been studied.

This review gives a useful overview on the catalytic applications of MOFs regarding their structural developments toward catalyst fabrication. The emphasis has been made on discussing the stability of the MOFs, their reusability and in providing a comparison of the performance of MOFs with respect to other homogeneous and heterogeneous catalysts.

Here, we report the exploration of fluorescent Zn-based amine/azine-functionalized MOF, TMU-17-NH2, ([Zn(NH2-BDC)(4-bpdb)].2DMF) for highly selective and sensitive detection of Fe3+ in DMF solution.

Here, we report the exploration of highly luminescent three-dimensional microporous metal–organic framework, [Zn2(oba)2(bpy)], synthesized by sonochemistry for highly selective and sensitive detection of Fe3+ in MeOH solution via a fluorescence quenching mechanism.

Graphene oxide-[Zn2(oba)2(bpfb)]·(DMF)5 metal-organic framework nanocomposite (GO-TMU-23) is prepared through a simple and large-scale sonochemical preparation method at room temperature. The absorption ability of GO-TMU-23 nanocomposite toward cationic dye methylene blue was also performed.

This review highlights the literature reported on MOFs with amide-decorated pores for CO₂ capture, showing the effects of amide groups on uptake capacity, selectivity and adsorption enthalpies of CO₂.

In this article, we report the green, simple and large-scale ultrasonic synthesis of nanocomposites of graphene oxide with three-dimensional two-fold interpenetration azine-functionalized MOF, TMU-16/GOn (n = the percentage of GO), at room temperature and atmospheric pressure.