Engineering of Core–Shell Pd/SSZ-13@Al<sub>2</sub>O<sub>3</sub> Zeolite: Unlocking Superior NO<sub><i>x</i></sub> Adsorption and Chemical Durability
Xiaoxin Chen, Maiyan Nan, Jun Huang, Lin Li, Zunhao Zhang, Guoju Yang
Abstract
Pd-zeolites are promising passive NO x adsorber (PNA) materials for mitigating cold-start emissions from lean-burn engines. However, their practical deployment is constrained by insufficient densities and dispersion of isolated Pd 2+ active sites as well as their susceptibility to hydrothermal degradation and phosphorus poisoning encountered in vehicle exhaust environments. Herein, we develop a rationally engineered core–shell Pd/SSZ-13@Al 2 O 3 composite, featuring a Pd/SSZ-13 core encapsulated within a mesoporous Al 2 O 3 shell. This hierarchical architecture facilitates the controlled migration and dispersion of Pd 2+ species, significantly enriching and stabilizing isolated Pd active sites within the zeolite core. Comprehensive characterization and density functional theory calculations confirm that the Al 2 O 3 shell serves as a robust barrier, forming stable aluminum phosphate species that prevent phosphorus infiltration and safeguard both the zeolite framework integrity and Pd 2+ active sites from environmental degradation. Catalytic evaluations revealed that Pd/SSZ-13@Al 2 O 3 exhibited superior NO x adsorption capacity, favorable NO x desorption behavior, and exceptional stability under hydrothermal and phosphorus poisoning conditions, outperforming conventional Pd-zeolite catalysts. This work establishes a generalizable core–shell design strategy for stabilizing atomically dispersed active sites in harsh environments, offering broad implications for the development of durable catalytic materials in air pollution control and environmental remediation.