Extraordinary synergy on 3D hierarchical porous Co-Cu nanocomposite for catalytic elimination of VOCs at low temperature and high space velocity.

It is still a challenge to develop hierarchically nanostructured catalysts with simple approaches to enhance the low-temperature catalytic activity. Herein, a set of mesoporous Co-Cu binary metal oxides with different morphologies were successfully prepared via a facile ammonium bicarbonate precipitation method without any templates or surfactants, which were further applied for catalytic removal of carcinogenic toluene. Among the catalysts with different ratios, the CoCu composite oxide presented the best performance, where the temperature required for 90% conversion of toluene was only 237°C at the high weight hour space velocity (WHSV) of 240,000 mL/(g·hr). Meanwhile, compared to the related Co-Cu composite oxides prepared by using different precipitants (NaOH and HCO), the NHHCO-derived CoCu sample exhibited better catalytic efficiency in toluene oxidation, while the T were 22 and 28°C lower than those samples prepared by NaOH and HCO routes, respectively. Based on various characterizations, it could be deduced that the excellent performance was related to the small crystal size (6.7 nm), large specific surface area (77.0 m/g), hollow hierarchical nanostructure with abundant high valence Co ions and adsorbed oxygen species. In situ DRIFTS further revealed that the possible reaction pathway for the toluene oxidation over CoCu catalyst followed the route of absorbed toluene → benzyl alcohol → benzaldehyde → benzoic acid → carbonate → CO and HO. In addition, CoCu sample could keep stable with long-time operation and occur little inactivation under humid condition (5 vol.% water), which revealed that the NHHCO-derived CoCu nanocatalyst possessed great potential in industrial applications for VOCs abatement.