Influence of Na, P and (Na + P) poisoning on a model copper-ferrierite NH3-SCR catalyst

Tarot, Marie-Laure; Iojoiu, Eduard Emil; Lauga, Vincent; Duprez, Daniel; Courtois, Xavier; Can, Fabien

doi:10.1016/j.apcatb.2019.03.044

Cited by 44 publications

(25 citation statements)

References 36 publications

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“…All of the catalysts show adsorption bands at 1916, 1908, and 1891 cm −1 , which can be attributed to NO adsorbed on Cu 2+ sites. 23,25,48,61 The amount of Cu 2+ ions follows the order Cu-F > Cu-0.3P-R3 > Cu-0.3P-R2 > Cu-0.3P-R1 > Cu-0.3P, which is consistent with the EPR result. This illustrates that the NO adsorption ability of Cu-SSZ-13 is reduced after phosphorus impregnation and then recovered by washing with hot water.…”

Section: Resultssupporting

confidence: 88%

“…Recently, a growing number of studies have focused on the deactivation mechanism of Cu-zeolite catalysts by phosphorus poisoning. ,,− Regrettably, to the best of our knowledge, there is no report on the regeneration of phosphorus-poisoned SCR catalysts in the open literature. If phosphorus-poisoned catalysts can be regenerated, the service life of Cu-SSZ-13 catalysts can be greatly improved.…”

Section: Introductionmentioning

confidence: 99%

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Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH₃-SCR of NO_x: The Deactivation and Promotion Mechanism of Phosphorus

et al. 2021

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Despite the successful commercialization of Cu-SSZ-13 catalysts as efficient ammonia-selective catalytic reduction (NH3-SCR) catalysts in diesel vehicles for NO x elimination, their sensitivity toward phosphorus poisoning is one of the primary challenges to practical applications. In this study, an efficient method was used to regenerate a phosphorus-poisoned Cu-SSZ-13 catalyst by washing with hot water. The mechanism of deactivation and regeneration of the Cu-SSZ-13 catalyst was deeply investigated by a series of careful characterizations of fresh, poisoned, and regenerated catalysts. After regeneration, the recovery of the decreased accessibility and porosity, deactivated Brønsted acid sites, and Cu2+ ions resulted in the restoration of the decreased activity and hydrothermal stability of the poisoned Cu-SSZ-13. At a low phosphorus loading (0.2 mmol/gcatal, 0.54 wt %), the promotion effect of phosphorus on the SCR performance was observed after regeneration, which was attributed to the decrease in the content of CuO species and recovery of the acid sites and active Cu2+ ions after regeneration. Additionally, the combination of washing with hot water and hydrothermal aging results in good recovery of the SCR performance of the phosphorus-poisoned catalyst. This work focuses on the regeneration of a phosphorus-poisoned Cu-SSZ-13 catalyst, which provides an efficient method to prolong the lifespan of the Cu-SSZ-13 catalyst in practical applications.

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Section: Resultssupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH₃-SCR of NO_x: The Deactivation and Promotion Mechanism of Phosphorus

et al. 2021

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“…Depending on the reaction conditions, Pd in zeolites could interconvert between highly dispersed and aggregated states, , which can be distinguished by in situ DRIFTS using different molecular probes (e.g., NO, CO, NH 3 , etc.). Here, we first used NO as a probe molecule, which could form stable nitrosyl adducts upon interaction with metal ions, to interrogate the state of Pd sites in SSZ-13 before and after P-poisoning. , Figure a presents the DRIFT spectra in the range of 1800–2000 cm –1 for the Pd-SSZ-13 catalysts during NO adsorption at 100 °C. An intense band at 1865 cm –1 and a feeble shoulder at 1811 (1817) cm –1 were observed, and it can be attributed to nitrosyl complexes adhering on two types of cationic Pd sites, i.e., Pd 2+ in 6MR and [Pd(OH)] + in 8MR (denoted as [Pd(OH)] + @8MR), respectively. ,,,,, After P-poisoning, band intensities related to NO species at [Pd(OH)] + @8MR decreased dramatically, while the IR band for NO at isolated Pd 2+ was preserved without a significant change in intensity.…”

Section: Resultsmentioning

confidence: 99%

Unravelling Phosphorus-Induced Deactivation of Pd-SSZ-13 for Passive NO_x Adsorption and CO Oxidation

et al. 2021

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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 NO x 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 (H2-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 Pd2+ (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 NO x 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 PdO x 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 PdO x . 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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“…Nitrogen oxides (NO and NO 2 ), released from stationary and mobile source exhaust, have generated a series of serious environmental issues, such as photochemical smog, acid rain, greenhouse effects, and ozone depletion. − Selective catalytic reduction with NH 3 (NH 3 -SCR) is currently regarded to be one of the most effective strategies to reduce NO x emissions. , Meanwhile, V 2 O 5 –MoO 3 (WO 3 )/TiO 2 has been the extensively employed and currently commercial NH 3 -SCR catalyst. , However, several disadvantages are still present in this system, which considerably limit its further utilization in practical applications, for instance, the toxicity of vanadium species, the high operation temperature, the low specific surface area of TiO 2 , and so forth. − Furthermore, the temperature of emitted NO x from stationary coal-fired plants and boilers is generally lower than 250 °C, yet the V 2 O 5 –WO 3 (MoO 3 )/TiO 2 catalyst is not effective for the abatement of exhaust smoke NO x at the so-low temperature region. Therefore, it is necessary and imperative to develop environmentally friendly NH 3 -SCR catalysts with excellent low-temperature activity for the conversion of NO x .…”

Section: Introductionmentioning

confidence: 99%

Mechanochemical Synthesis of Highly Porous CeMnO_x Catalyst for the Removal of NO_x

Cheng

Tan

Ren

et al. 2019

Ind. Eng. Chem. Res.

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Tailoring the pore structure is a straightforward and effective strategy to regulate the catalytic activity of catalysts in heterogeneous catalysis reactions but remain a challenge. Herein, we present a low-cost, facile, and large-scale mechanochemical nanocasting strategy between cerium salt and manganese salt that enables solvent-free and rapid synthesis of porous CeMnO x oxide with a high specific surface area, rich chemisorbed oxygen species, Mn4+, and acidity, as well as improved reducibility. Moreover, this kind of catalyst shows exceptionally high low-temperature activity for the selective catalytic reduction of NO x with ammonia (NH3-SCR). It achieves almost 100% NO x conversion at 150 °C, which is much lower than that of its bulk CeMnO x counterpart constructed by the sol–gel method. It is expected that this technology may open up new opportunities for fabricating a number of advanced porous materials with exceptional catalytic activity for the environmental catalysis field.

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Influence of Na, P and (Na + P) poisoning on a model copper-ferrierite NH3-SCR catalyst

Cited by 44 publications

References 36 publications

Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH₃-SCR of NO_x: The Deactivation and Promotion Mechanism of Phosphorus

Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH₃-SCR of NO_x: The Deactivation and Promotion Mechanism of Phosphorus

Unravelling Phosphorus-Induced Deactivation of Pd-SSZ-13 for Passive NO_x Adsorption and CO Oxidation

Mechanochemical Synthesis of Highly Porous CeMnO_x Catalyst for the Removal of NO_x

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Influence of Na, P and (Na + P) poisoning on a model copper-ferrierite NH3-SCR catalyst

Cited by 44 publications

References 36 publications

Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH3-SCR of NOx: The Deactivation and Promotion Mechanism of Phosphorus

Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH3-SCR of NOx: The Deactivation and Promotion Mechanism of Phosphorus

Unravelling Phosphorus-Induced Deactivation of Pd-SSZ-13 for Passive NOx Adsorption and CO Oxidation

Mechanochemical Synthesis of Highly Porous CeMnOx Catalyst for the Removal of NOx

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Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH₃-SCR of NO_x: The Deactivation and Promotion Mechanism of Phosphorus

Efficient Strategy to Regenerate Phosphorus-Poisoned Cu-SSZ-13 Catalysts for the NH₃-SCR of NO_x: The Deactivation and Promotion Mechanism of Phosphorus

Unravelling Phosphorus-Induced Deactivation of Pd-SSZ-13 for Passive NO_x Adsorption and CO Oxidation

Mechanochemical Synthesis of Highly Porous CeMnO_x Catalyst for the Removal of NO_x