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Cold-Start NO x Mitigation by Passive Adsorption Using Pd-Exchanged Zeolites: From Material Design to Mechanism Understanding and System Integration.

Ying LiDongdong ChenXin XuXinyu WangRunning KangMingli FuYanbing GuoPeirong ChenYongdan LiDaiqi Ye
Published in: Environmental science & technology (2023)
It remains a major challenge to abate efficiently the harmful nitrogen oxides (NO x ) in low-temperature diesel exhausts emitted during the cold-start period of engine operation. Passive NO x adsorbers (PNA), which could temporarily capture NO x at low temperatures (below 200 °C) and release the stored NO x at higher temperatures (normally 250-450 °C) to downstream selective catalytic reduction unit for complete abatement, hold promise to mitigate cold-start NO x emissions. In this review, recent advances in material design, mechanism understanding, and system integration are summarized for PNA based on palladium-exchanged zeolites. First, we discuss the choices of parent zeolite, Pd precursor, and synthetic method for the synthesis of Pd-zeolites with atomic Pd dispersions, and review the effect of hydrothermal aging on the properties and PNA performance of Pd-zeolites. Then, we show how different experimental and theoretical methodologies can be integrated to gain mechanistic insights into the nature of Pd active sites, the NO x storage/release chemistry, as well as the interactions between Pd and typical components/poisons in engine exhausts. This review also gathers several novel designs of PNA integration into modern exhaust after-treatment systems for practical application. At the end, we discuss the major challenges, as well as important implications, for the further development and real application of Pd-zeolite-based PNA in cold-start NO x mitigation.
Keyphrases
  • climate change
  • nucleic acid
  • deep learning
  • heavy metals
  • air pollution