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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

2025Environmental Science & Technology8 citationsDOI

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.

Topics & Concepts

ZeoliteAdsorptionHydrothermal circulationCatalysisMaterials scienceDispersion (optics)Chemical engineeringMesoporous materialDurabilityPhosphateDegradation (telecommunications)Chemical stabilityPollutionDesorptionEnvironmental sciencePhosphorusEnvironmental pollutionReusabilityHydrothermal synthesisWaste managementInfiltration (HVAC)PollutantCatalytic Processes in Materials ScienceCatalysis and Oxidation ReactionsCatalysis and Hydrodesulfurization Studies
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 | Litcius