NOx Removal by Selective Catalytic Reduction with Ammonia over a Hydrotalcite-Derived NiFe Mixed Oxide

Wang, Ruonan; Wu, Xu; Zou, Chunlei; Li, Xiaojian; Du, Yali

doi:10.3390/catal8090384

Cited by 39 publications

(17 citation statements)

References 44 publications

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“…As can be observed, the isotherm of Fe 85 Ce 10 W 5 -CP-CA(NA1.0) can be recognized as a type IV N2 adsorption/desorption isotherm according to the International Union of Pure and Applied Chemistry (IUPAC) classification, and it presents mainly meso-pores (2-50 nm), however, the hysteresis loops of Fe85Ce10W5-CP-CA(NA1.0) and Fe85Ce10W5-CP-CA are the H2 and H1 type [32,34], respectively. This demonstrates that the removal of nitrate promotes the formation of meso-pores in magnetic, and the Fe85Ce10W5-CP-CA catalyst shows uniform and regular meso-pores, which was confirmed by the results of the pore diameter distribution in Figure 5B [35]. Interesting, the Brunauer-Emmett and Teller (BET) surface area of Fe 85 Ce 10 W 5 -CP-CA was 90.85 m 2 /g, a little smaller than that of Fe 85 Ce 10 W 5 -CP-CA(NA 1.0 ) (93.13 m 2 /g), as shown in Table 2.…”

Section: N 2 Adsorption-desorptionsupporting

confidence: 69%

The Role of Nitrate on the Sol-Gel Spread Self-Combustion Process and Its Effect on the NH3-SCR Activity of Magnetic Iron-Based Catalyst

et al. 2020

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Sol-gel spread self-combustion is the burning of the complexing agent in dried gel and the oxidant. Meanwhile, high temperature takes place during the combustion process, which is harmful to the pore structure of the catalyst. The nitrate from metal nitrate precursors as an oxidant could participate in the spread of the self-combustion process. Therefore, the influence of nitrate from metal nitrate on the spread self-combustion of an iron–cerium–tungsten citric acid gel and its catalytic performance of NOx reduction were investigated by removing nitrate via the dissolution of washing co-precipitation with citric acid and re-introducing nitric acid into the former solution. It was found that the removal of nitrate contributes to enhancing the NH3–SCR activity of the magnetic mixed oxide catalyst. The NOx reduction efficiency was close to 100% for Fe85Ce10W5–CP–CA at 250 °C while the highest was only 80% for the others. The results of thermal analysis demonstrate that the spread self-combustion process of citric acid dried gel is enhanced by re-introducing nitric acid into the citric acid dissolved solution when compared with the removal of nitrate. In addition, the removal of nitrate helps in the formation of γ-Fe2O3 crystallite in the catalyst, refining the particle size of the catalyst and increasing its pore volume. The removal of nitrate also contributes to the formation of Lewis acid sites and Brønsted acid sites on the surface of the catalyst compared with the re-introduction of nitric acid. The in situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) demonstrates that both Eley–Rideal (E–R) and Langmuir–Hinshelwood (L–H) mechanisms exist over Fe85Ce10W5–CP–CA at 250 °C with E–R as its main mechanism.

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Section: N 2 Adsorption-desorptionsupporting

confidence: 69%

The Role of Nitrate on the Sol-Gel Spread Self-Combustion Process and Its Effect on the NH3-SCR Activity of Magnetic Iron-Based Catalyst

et al. 2020

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“…Just as the catalytic results presented, the Ni 3 Mn 1 Fe 1 ‐600 catalyst showed the most satisfactory DeNO x results. It can be seen from Figure S2 that the DeNO x efficiency of NiMnFe−T catalysts was better at low temperature range than NiFe‐LDO catalyst of our previously reported, which should be ascribed to Mn species redox behavior . Furthermore, the effect of GHSV on the DeNO x performance of Ni 3 Mn 1 Fe 1 ‐600 catalyst was also investigated Figure S3, ESI†).…”

Section: Resultsmentioning

confidence: 73%

“…Besides, it was also discovered that the strong interaction between the Ni and Mn species in the NiMn bi‐metal oxides could lead to great catalytic activities of NO x removal . Apart from that, our preliminary research found that NiFe mixed oxide afforded superior SO 2 resistance and catalytic stability in the application of NH 3 ‐SCR due to the creation of redox cycle resulting from the electron transfer between Ni and Fe, whereas the low‐temperature DeNO x activity was not very satisfactory . Thus, introducing Mn species into the NiFe system might be promising to improve NH 3 ‐SCR activity in the low temperature zone.…”

Section: Introductionmentioning

confidence: 89%

NH₃‐SCR Performance Enhancement of LDHs‐Based NiMnFe‐Mixed Oxides by Two‐Phase Coexistence and Cooperation

Liu

Zou

et al. 2019

ChemistrySelect

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Mixed oxides with NiMnFe‐LDHs as precursors were synthesized and evaluated as catalysts in selective catalytic reduction of NO with NH3 (NH3‐SCR). Appropriate calcination temperature was identified to achieve optimal catalyst. The results pronouncedly affirmed that the catalytic performances of the as‐acquired catalysts were vulnerable to calcination temperature, where Ni3Mn1Fe1‐600 presented preferable DeNOx activity with above 90% NO conversion and 98% N2 selectivity in the range of 150‐360 °C. Multiple characterizations exhibited that the outstanding DeNOx activity was determined by the coexistence as well as cooperation of NiFe2O4 spinel and Ni6MnO8 phase, which could contribute more surface active sites, and synergetic effect arising from the electron transfer between Ni, Mn ions and Ni, Fe ions. Furthermore, a more rapid redox cycle and optimal DeNOx performance were resultantly accomplished.

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“…In the automotive industry, hydrocarbons are initially preferred as reductors as they are present in the exhaust gas, but not many catalysts are active for the reaction and most of them have problems related to the hydrothermal stability of the materials [7]. Ammonia is the other alternative selected by the industry and a high efficiency [8,9] can be obtained when ammonia or its precursor (urea) are used for the NO x -SCR.…”

Section: Introductionmentioning

confidence: 99%

The Influence of the Support on the Activity of Mn–Fe Catalysts Used for the Selective Catalytic Reduction of NOx with Ammonia

2020

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Mono and bimetallic Mn–Fe catalysts supported on different materials were prepared and their catalytic performance in the NH3–SCR of NOx was investigated. It was shown that Mn and Fe have a synergic effect that enhances the activity at low temperature. Nevertheless, the activity of the bimetallic catalysts depends very much on the support selected. The influence of the support on the catalyst activity has been studied using materials with different textural and acid–base properties. Microporous (BEA-zeolite), mesoporous (SBA15 and MCM41) and bulk (metallic oxides) materials with different acidity have been used as supports for the Mn–Fe catalysts. It has been shown that the activity depends on the acidity of the support and on the surface area. Acid sites are necessary for ammonia adsorption and high surface area produces a better dispersion of the active sites resulting in improved redox properties. The best results have been obtained with the catalysts supported on alumina and on beta zeolite. The first one is the most active at low temperatures but it presents some reversible deactivation in the presence of water. The Mn–Fe catalyst supported on beta zeolite is the most active at temperatures higher than 350 °C, without any deactivation in the presence of water and with a 100% selectivity towards nitrogen.

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NOx Removal by Selective Catalytic Reduction with Ammonia over a Hydrotalcite-Derived NiFe Mixed Oxide

Cited by 39 publications

References 44 publications

The Role of Nitrate on the Sol-Gel Spread Self-Combustion Process and Its Effect on the NH3-SCR Activity of Magnetic Iron-Based Catalyst

The Role of Nitrate on the Sol-Gel Spread Self-Combustion Process and Its Effect on the NH3-SCR Activity of Magnetic Iron-Based Catalyst

NH₃‐SCR Performance Enhancement of LDHs‐Based NiMnFe‐Mixed Oxides by Two‐Phase Coexistence and Cooperation

The Influence of the Support on the Activity of Mn–Fe Catalysts Used for the Selective Catalytic Reduction of NOx with Ammonia

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NOx Removal by Selective Catalytic Reduction with Ammonia over a Hydrotalcite-Derived NiFe Mixed Oxide

Cited by 39 publications

References 44 publications

The Role of Nitrate on the Sol-Gel Spread Self-Combustion Process and Its Effect on the NH3-SCR Activity of Magnetic Iron-Based Catalyst

The Role of Nitrate on the Sol-Gel Spread Self-Combustion Process and Its Effect on the NH3-SCR Activity of Magnetic Iron-Based Catalyst

NH3‐SCR Performance Enhancement of LDHs‐Based NiMnFe‐Mixed Oxides by Two‐Phase Coexistence and Cooperation

The Influence of the Support on the Activity of Mn–Fe Catalysts Used for the Selective Catalytic Reduction of NOx with Ammonia

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NH₃‐SCR Performance Enhancement of LDHs‐Based NiMnFe‐Mixed Oxides by Two‐Phase Coexistence and Cooperation