期刊
ACS CATALYSIS
卷 11, 期 22, 页码 13891-13901出版社
AMER CHEMICAL SOC
DOI: 10.1021/acscatal.1c03214
关键词
chabazite zeolite; cold-start DeNO(x); phosphorus; catalyst deactivation; poisoning mechanisms
资金
- National Natural Science Foundation of China [21976058, 21806039]
- Natural Science Foundation of Guangdong Province [2018A030313302]
- Science and Technology Program of Guangzhou [202102080490]
- Pearl River Talent Recruitment Program of Guangdong Province [2019QN01L170]
- In-novation & Entrepreneurship Talent Prog r a m of Shaoguan City
This study demonstrates that phosphorus (P) originating from lubricant oil additives or biofuels can lead to severe deactivation of Pd-SSZ-13 zeolites in automotive exhaust after-treatment systems. The loss of isolated Pd sites, specifically [Pd(OH)]+ and Pd2+, due to P-poisoning was found to be the primary reason for deactivation. In situ studies suggest that [Pd(OH)]+ is more susceptible to P-poisoning than Pd2+, leading to migration of [Pd(OH)]+ to the zeolite surface and subsequent formation of inactive metaphosphate and bulk PdOx species.
Phosphorus (P) originating from lubricant oil additives or biofuels is an emerging chemical poison in catalytic systems for automotive exhaust after-treatment. Here, we demonstrate that P-poisoning led to severe deactivation of small-pore Pd-SSZ-13 zeolites (with CHA framework) as passive NOx adsorbers (PNA) and CO oxidation catalysts for cold-start exhaust purification applications. Deactivation mechanisms of P-poisoning were unraveled by comparatively examining the P-free and P-loaded Pd-SSZ-13 zeolites using transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), nuclear magnetic resonance (NMR), temperature-programmed reduction by hydrogen (H-2-TPR), CO pulse adsorption, temperature-programmed desorption using NH3 as a probe molecule (NH3-TPD), ultraviolet/visible light (UV/vis) spectroscopy, and in situ diffuse relectance infrared Fourier transform spectroscopy (DRIFTS). The loss of isolated Pd sites-namely, [Pd(OH)]+ and Pd-2. (located in the eight- and six-membered rings of CHA framework, respectively)-was revealed to be largely responsible for the deactivation of Pd-SSZ-13 in passive NOx adsorption and catalytic CO oxidation. In situ DRIFTS studies using NO or CO as a probe molecule suggest that [Pd(OH)](+) was more susceptible to P-poisoning than Pd2+. Specifically, P-poisoning led to a migration of [Pd(OH)](+) from cationic exchange sites to the zeolite surface, forming inactive metaphosphate (i.e., [Pd(OH)]+PO3-) and bulk PdOx species at high temperatures. In contrast, P-poisoning of Pd2+ sites proceeded via a sequential transformation to [Pd(OH)](+) first, and then to [Pd(OH)]+PO3- and bulk PdOx. This study provides a comprehensive mechanistic understanding on the deactivation of Pd-SSZ-13 by P-poisoning, and may guide the design of high-performance, phosphorus-resistant Pd-zeolite catalysts for cold-start exhaust after-treatment.
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