Pt-TiO₂ Catalyst for Aqueous-Phase Water–Gas Shift Reaction Constructed by Utilizing Strong Metal–Support Interaction

Aqueous-phase water–gas shift reaction (AP-WGSR, CO (g) + H₂O (l) = H₂ (g) + CO₂ (g)) refers to the reaction between gas-phase carbon monoxide and aqueous-phase water that produces gas-phase hydrogen and carbon dioxide. Its Gibbs free energy value is more negative, and therefore, the conversion of CO would be more complete compared with the traditional gas-phase water–gas shift reaction (CO (g) + H₂O (g) = H₂ (g) + CO₂ (g)). Herein, Pt-TiO₂ catalysts reduced at different temperatures for AP-WGSR are prepared and the relationship between the catalytic activity for AP-WGSR and the structure of Pt-TiO₂ catalysts reduced at different temperatures was studied. Pt-TiO₂ catalyst reduced at 600 °C (Pt-TiO₂-600R) exhibits the best catalytic performance and accomplishes the objective of catalyzing AP-WGSR. The low-temperature H₂ formation rate of Pt-TiO₂-600R reaches 20.3 μmol g_cat^–1 s^–1 (170 °C, CO partial pressure of 4.5 MPa), which is almost 17 times larger than that of the Pt-TiO₂ catalyst reduced at 300 °C (Pt-TiO₂-300R, 1.2 μmol g_cat^–1 s^–1). In addition, the Pt-TiO₂-600R catalyst is hydrothermally stable and the CO conversion remains stable over six consecutive reactions at 180 °C. Characterizations reveal that a strong metal–support interaction (SMSI) occurs on the Pt-TiO₂ catalysts reduced at high temperatures. TiO_x species cover the Pt particle, and oxygen vacancies are formed at the Pt-TiO_x interface. Mechanism studies indicate that AP-WGSR undergoes a redox mechanism with low apparent activation energies on the Pt-TiO₂ catalyst containing Pt partially covered by TiO_x species and an associative mechanism with high apparent activation energies on the Pt-TiO₂ catalyst containing bare Pt, respectively.