Low temperature and high pressure are thermodynamically
more favorable
conditions to achieve high conversion and high methanol selectivity
in CO2 hydrogenation. However, low-temperature activity
is generally very poor due to the sluggish kinetics, and thus, designing
highly selective catalysts active below 200 °C is a great challenge
in CO2-to-methanol conversion. Recently, Re/TiO2 has been reported as a promising catalyst. We show that Re/TiO2 is indeed more active in continuous and high-pressure (56
and 331 bar) operations at 125–200 °C compared to an industrial
Cu/ZnO/Al2O3 catalyst, which suffers from the
formation of methyl formate and its decomposition to carbon monoxide.
At lower temperatures, precise understanding and control over the
active surface intermediates are crucial to boosting conversion kinetics.
This work aims at elucidating the nature of active sites and active
species by means of in situ/operando X-ray absorption
spectroscopy, Raman spectroscopy, ambient-pressure X-ray photoelectron
spectroscopy (AP-XPS), and diffuse reflectance infrared Fourier transform
spectroscopy (DRIFTS). Transient operando DRIFTS
studies uncover the activation of CO2 to form active formate
intermediates leading to methanol formation and also active rhenium
carbonyl intermediates leading to methane over cationic Re single
atoms characterized by rhenium tricarbonyl complexes. The transient
techniques enable us to differentiate the active species from the
spectator one on TiO2 support, such as less reactive formate
originating from spillover and methoxy from methanol adsorption. The
AP-XPS supports the fact that metallic Re species act as H2 activators, leading to H-spillover and importantly to hydrogenation
of the active formate intermediate present over cationic Re species.
The origin of the unique reactivity of Re/TiO2 was suggested
as the coexistence of cationic highly dispersed Re including single
atoms, driving the formation of monodentate formate, and metallic
Re clusters in the vicinity, activating the hydrogenation of the formate
to methanol.