Vanadium contamination of FCC catalyst: Understanding the destruction and passivation mechanisms

Ubong J. Etim; Peng Bai; Rooh Ullah; Fazle Subhan; Zifeng Yan

doi:10.1016/j.apcata.2018.02.011

Vanadium contamination of FCC catalyst: Understanding the destruction and passivation mechanisms

Ubong J. Etim, Peng Bai^*, Rooh Ullah, Fazle Subhan, Zifeng Yan

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Vanadium scavenging material comprising magnesium and yttrium oxides (Mg-Y-oxide) was prepared and evaluated for vanadium capture under simulated FCC regeneration conditions for typical FCC process. Vanadium trapping ability was measured using BET, XRD, FTIR, EDX coupled SEM and MAT. The results show that physiochemical properties, vanadium trapping and catalyst protection increase with amount of the trap material. SEM-EDX results confirm migration of vanadium as indicated by its presence in the passivator particle. Vanadium migrates within the catalyst particles by both inter and intra particles mechanisms. The XRD data further reveal high vanadium selectivity towards yttrium when passivator is incorporated after impregnation of vanadium, with the formation of crystalline yttrium vanadate (YVO₄). Catalytic evaluation indicates improved activities of catalysts containing passivator which correlate with physiochemical parameters. In the passivation mechanism, mobile vanadic acid preferentially reacts more with Y₂O₃ in mixed metal oxide due to its higher activity (active sites), forming YVO₄. These results therefore reveal that the passivator protects the catalyst by formation of immobile vanadate with mobile vanadic acid, thereby reducing hydrolysis of the catalyst framework and thus preserving important properties of the catalyst.

Original language	English
Pages (from-to)	108-117
Number of pages	10
Journal	Applied Catalysis A: General
Volume	555
DOIs	https://doi.org/10.1016/j.apcata.2018.02.011
State	Published - 5 Apr 2018
Externally published	Yes

Keywords

Deactivation
FCC catalyst
Mechanism
Passivation
Vanadium

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10.1016/j.apcata.2018.02.011

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@article{79e3899732bf456094a00e381a68618f,

title = "Vanadium contamination of FCC catalyst: Understanding the destruction and passivation mechanisms",

abstract = "Vanadium scavenging material comprising magnesium and yttrium oxides (Mg-Y-oxide) was prepared and evaluated for vanadium capture under simulated FCC regeneration conditions for typical FCC process. Vanadium trapping ability was measured using BET, XRD, FTIR, EDX coupled SEM and MAT. The results show that physiochemical properties, vanadium trapping and catalyst protection increase with amount of the trap material. SEM-EDX results confirm migration of vanadium as indicated by its presence in the passivator particle. Vanadium migrates within the catalyst particles by both inter and intra particles mechanisms. The XRD data further reveal high vanadium selectivity towards yttrium when passivator is incorporated after impregnation of vanadium, with the formation of crystalline yttrium vanadate (YVO4). Catalytic evaluation indicates improved activities of catalysts containing passivator which correlate with physiochemical parameters. In the passivation mechanism, mobile vanadic acid preferentially reacts more with Y2O3 in mixed metal oxide due to its higher activity (active sites), forming YVO4. These results therefore reveal that the passivator protects the catalyst by formation of immobile vanadate with mobile vanadic acid, thereby reducing hydrolysis of the catalyst framework and thus preserving important properties of the catalyst.",

keywords = "Deactivation, FCC catalyst, Mechanism, Passivation, Vanadium",

author = "Etim, {Ubong J.} and Peng Bai and Rooh Ullah and Fazle Subhan and Zifeng Yan",

note = "Publisher Copyright: {\textcopyright} 2018 Elsevier B.V.",

year = "2018",

month = apr,

day = "5",

doi = "10.1016/j.apcata.2018.02.011",

language = "英语",

volume = "555",

pages = "108--117",

journal = "Applied Catalysis A: General",

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T1 - Vanadium contamination of FCC catalyst

T2 - Understanding the destruction and passivation mechanisms

AU - Etim, Ubong J.

AU - Bai, Peng

AU - Ullah, Rooh

AU - Subhan, Fazle

AU - Yan, Zifeng

PY - 2018/4/5

Y1 - 2018/4/5

N2 - Vanadium scavenging material comprising magnesium and yttrium oxides (Mg-Y-oxide) was prepared and evaluated for vanadium capture under simulated FCC regeneration conditions for typical FCC process. Vanadium trapping ability was measured using BET, XRD, FTIR, EDX coupled SEM and MAT. The results show that physiochemical properties, vanadium trapping and catalyst protection increase with amount of the trap material. SEM-EDX results confirm migration of vanadium as indicated by its presence in the passivator particle. Vanadium migrates within the catalyst particles by both inter and intra particles mechanisms. The XRD data further reveal high vanadium selectivity towards yttrium when passivator is incorporated after impregnation of vanadium, with the formation of crystalline yttrium vanadate (YVO4). Catalytic evaluation indicates improved activities of catalysts containing passivator which correlate with physiochemical parameters. In the passivation mechanism, mobile vanadic acid preferentially reacts more with Y2O3 in mixed metal oxide due to its higher activity (active sites), forming YVO4. These results therefore reveal that the passivator protects the catalyst by formation of immobile vanadate with mobile vanadic acid, thereby reducing hydrolysis of the catalyst framework and thus preserving important properties of the catalyst.

AB - Vanadium scavenging material comprising magnesium and yttrium oxides (Mg-Y-oxide) was prepared and evaluated for vanadium capture under simulated FCC regeneration conditions for typical FCC process. Vanadium trapping ability was measured using BET, XRD, FTIR, EDX coupled SEM and MAT. The results show that physiochemical properties, vanadium trapping and catalyst protection increase with amount of the trap material. SEM-EDX results confirm migration of vanadium as indicated by its presence in the passivator particle. Vanadium migrates within the catalyst particles by both inter and intra particles mechanisms. The XRD data further reveal high vanadium selectivity towards yttrium when passivator is incorporated after impregnation of vanadium, with the formation of crystalline yttrium vanadate (YVO4). Catalytic evaluation indicates improved activities of catalysts containing passivator which correlate with physiochemical parameters. In the passivation mechanism, mobile vanadic acid preferentially reacts more with Y2O3 in mixed metal oxide due to its higher activity (active sites), forming YVO4. These results therefore reveal that the passivator protects the catalyst by formation of immobile vanadate with mobile vanadic acid, thereby reducing hydrolysis of the catalyst framework and thus preserving important properties of the catalyst.

KW - Deactivation

KW - FCC catalyst

KW - Mechanism

KW - Passivation

KW - Vanadium

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DO - 10.1016/j.apcata.2018.02.011

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VL - 555

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JO - Applied Catalysis A: General

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ER -

Vanadium contamination of FCC catalyst: Understanding the destruction and passivation mechanisms

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Keywords

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