and Akron Avenue, Lubbock, TX 79409.
AbstractReplacing precious noble-metal catalysts with non-precious metal ones is a well-recognized strategy for reducing the cost of catalytic water treatment. The implementation of this strategy is, however, challenging. To reduce the cost by using non-precious metal catalysts, the reactivity ratio between non-precious and precious metal catalysts must exceed their price ratio. Here, we report for the first timethat the parity condition has been surpassedfor cobalt (Co), in comparison to the most active precious metal catalyst made of palladium,in the catalytic reduction of pnitrophenol with borohydride. This is achieved by affixing Co nanoparticles on two-dimensional layered double oxide (LDO) nanodisks through thermal phase transformation of cobaltmagnesium-aluminum layered double hydroxide precursors. We show that the catalytic activity of LDO-Co is a function of Co molar fraction among metal cations.The highest reactivity is achieved at a molar fraction of 28%, giving a pseudo first order rate constant of 86(±3) min -1 at 25 o C for a catalyst dose of 1 g L -1 (as Co) and an initial p-nitrophenol concentration of 0.2 mM.Compared to other Co nano-catalysts described in the literature, the LDO-Co design has improved the reactivity of cobalt by at least 49 times. We further show that the high reactivity of LDO-Co remains after repeated reuse as well as after borohydride is replaced by formate, a moderate reductant and hydrogen donor. We propose that the high reactivity and superior longevity of LDO-Co are results of the heteroepitaxial fixation of cobalt on LDO through cobaltoxygen bonds that are similar to those in spinel cobalt oxide.