Frustrated Lewis Pairs Boosting CO<sub>2</sub> Capture and In Situ Methanation over Ni/CaO Dual-Functional Materials
Pu Huang, Jie Chu, Zhouzhou Zhang, Huan He, Yafei Guo, Yingju Yang, Chuanwen Zhao
Abstract
In this study, a Ni/CaO dual-functional material with a frustrated Lewis pair (FLP) structure was synthesized through the codoping of Al and Zr for integrated CO 2 capture and methanation applications. The formation of FLPs was confirmed using CO 2 -TPD, EPR, and NH 3 -TPD, which showed enhanced acid–base properties due to the creation of oxygen vacancies (acting as Lewis bases) and the introduction of Zr 4+ (acting as a Lewis acid). This unique acid–base environment facilitated efficient CO 2 activation and proton transfer. In situ diffuse reflectance infrared Fourier transform spectroscopy identified key intermediates such as CO*, indicating that in situ methanation follows a dissociation path. DFT calculations demonstrated that the FLP structure lowers the energy barrier for COOH* to CO* conversion, while Zr 4+ accelerated the C–H bond formation. Compared to the pristine Ni/CaO material without FLP structures, the Ni 10 Ca 80 Al 5 Zr 5 material with FLP structures exhibits a significant enhancement in performance, with CO 2 adsorption capacity increasing from 9.89 to 12.51 mmol/g and CH 4 yield rising from 3.68 to 7.46 mmol/g. Over 20 cycles, the CO 2 conversion rate and CH 4 selectivity of Ni 10 Ca 80 Al 5 Zr 5 only slightly decreased by 0.45 and 4.6%, respectively. The CO 2 adsorption capacity decreased to 9.35 mmol/g in the first 15 cycles and then remained stable. This study demonstrates that Al and Zr codoping improves the cyclic stability and methanation activity of Ni/CaO dual-functional materials.