Converting CO₂ into valueadded chemicals is a key strategy for reducing greenhouse gas emissions. Coupling CO₂ hydrogenation with toluene alkylation offers an atomeconomic route to produce paraxylene (PX), an important platform chemical for synthetic fibers, resins, and rubbers. However, conventional ZSM5 catalysts possess strong Brønsted acidity that triggers uncontrollable side reactions including dealkylation, deep alkylation, and xylene isomerization, limiting PX selectivity.
In a study published in ENG. Chem. Eng., researchers at Taiyuan University of Technology report a bifunctional catalyst system that addresses these challenges using silanol nestenriched silicalite1 (AS1) as the alkylation component, combined with ZnZrOₓ (ZZO) as the CO₂ hydrogenation catalyst.
The AS1 zeolite exhibits a total acidity of only 38 μmol·g⁻¹, far lower than that of ZSM5 (443 μmol·g⁻¹). This moderate acidity originates from silanol nests rather than framework aluminum, effectively suppressing side reactions. Compared to ZSM5, AS1 reduces benzene selectivity from 6.04 % to 0.5 % and increases PX selectivity from 23.6 % to 33 %. In situ DRIFTS and GCMS analyses confirmed that the mild acidity of AS1 significantly reduces coke formation, as the spent AS1 catalyst showed minimal soluble coke compared to the dark, heavily coked ZSM5.
Systematic optimization of the ZZO:AS1 mass ratio revealed a volcanoshaped trend in toluene conversion, with the best performance at a 1:4 ratio (toluene conversion: 13.2 %). Optimizing the particle sizes (ZZO: 20–40 mesh, AS1: 80–100 mesh) further increased toluene conversion to 16.3 %. Proximity studies showed that powder mixing enhanced contact and shortened diffusion paths, yielding superior performance compared to physically separated dualbed configurations.
To enhance shape selectivity, an epitaxial silicalite1 shell was grown on AS1. The AS1@25 %S1 sample achieved a PX selectivity of 44.4 %, while maintaining a toluene conversion of 15.2 %. However, thicker shells (50 % and 100 %) introduced excessive diffusion limitations, reducing toluene conversion.
Ammonium hexafluorosilicate (AHFS) treatment was employed to generate mesopores and improve diffusion. The 16 h treated sample showed increased mesopore volume (from 0.02 to 0.08 cm³·g⁻¹) and enhanced toluene conversion to 20.9 %, though PX selectivity decreased to 31.3 % due to promoted isomerization.
Finally, the depositionprecipitation method was used to load ZZO onto AS1@S1, maximizing dispersion and minimizing intermediate diffusion distances. The integrated ZZO/AS1@25 %S1 catalyst (1:2 loading ratio) achieved a CO₂ conversion of 9.5 %, toluene conversion of 15 %, and PX selectivity of 42.7 %. Under reduced pressure (0.5 MPa), PX selectivity reached 57.5 %. Stability tests over 48 h showed that the integrated catalyst maintained stable performance, with toluene conversion decreasing only from 16.2 % to 13 %, attributed to the S1 shell mitigating Zn migration poisoning.
This work provides novel insights into designing bifunctional catalysts for CO₂ hydrogenation coupled with toluene alkylation, offering a sustainable route for both greenhouse gas utilization and highvalue aromatic production.
DOI
10.1007/s11705-026-2674-2