Enhanced Coke Gasification Activity of the Mn1.5Cr1.5O4 Spinel Catalyst during Coking in Ethylene–Steam Mixtures

Bukhovko, Maxim P.; Liu, Yang; Nezam, Iman; Li, Liwei; Malek, Andrzej; Davis, Robert J.; Agrawal, Pradeep; Jones, Christopher W.

doi:10.1021/acs.energyfuels.1c00036

Cited by 5 publications

(7 citation statements)

References 53 publications

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“…An Ar + ion laser (λ = 488 nm) was used to collect first-order Raman spectra, with a laser source intensity of 5 mW for 2 s. The sample was placed onto a glass slide to analyze at least three different coked spots. The collected Raman spectra were deconvoluted using constrained peak fitting settings in OriginPro software. , …”

Section: Experimental Methodssupporting

confidence: 90%

“…All of the thermal pretreatments and coking tests were conducted in a customized thermogravimetric analyzer system (TGA, NETZSCH STA449F3) (Supporting Information (SI) Figure S1), as reported and validated in our previous work. ,− Prior to the first coking cycle, the Mn-plated/anodized Incoloy 800H sample (hereafter, Mn-Inc.) was placed inside an alumina crucible and thermally pretreated under a H 2 –H 2 O atmosphere. The TGA system was evacuated and purged with nitrogen three times, and the Mn-Inc. sample was then heated inside the TGA under nitrogen (130 mL/min) up to 825 °C at 10 °C/min.…”

Section: Experimental Methodsmentioning

confidence: 99%

“…The collected Raman spectra were deconvoluted using constrained peak fitting settings in OriginPro software. 34,35 ■ RESULTS AND DISCUSSION Initial Characterization of Mn-Plated/Anodized incoloy 800H…”

Section: Characterizationmentioning

confidence: 99%

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Anticoking Performance of Electrodeposited Mn/MnO Surface Coating on Fe–Ni–Cr Alloy during Steam Cracking

Bukhovko

Liu

et al. 2021

ACS Eng. Au

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Manganese electrodeposition and anodization are performed on an Fe−Ni−Cr alloy (Incoloy 800H) to form an Mn/MnO surface coating after thermal pretreatment. The Mn/ MnO-coated alloy is coked under simulated steam cracking conditions in ethylene-steam, and its anticoking performance is compared with pretreated, uncoated alloys. The mass of deposited coke during repeated coking cycles is measured by thermogravimetric analysis (TGA) and also determined from the measured CO/CO 2 concentrations during decoking with air. Compared to the uncoated alloys that have Cr 2 O 3 -rich surfaces, the Mn/MnO-coated alloy shows 30−40% less deposited coke and a peak coke oxidation temperature reduced by about 100 °C. The Mn/MnO surface coating is hypothesized to reduce coke deposition by limiting the amount of Fe/Ni species on the surface and by catalyzing coke gasification/oxidation reactions via the formation of catalytically active Mn 3+ species.

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Section: Experimental Methodssupporting

confidence: 90%

Section: Experimental Methodsmentioning

confidence: 99%

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Anticoking Performance of Electrodeposited Mn/MnO Surface Coating on Fe–Ni–Cr Alloy during Steam Cracking

Bukhovko

Liu

et al. 2021

ACS Eng. Au

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“…For instance, the oxide layer of Al-Coated regenerated itself after each cracking cycle. On the other hand, the non-aluminum-containing alloys of 33/43 Cr–Ni, Cr–Mn-Coated, and 27/34 Cr–Ni showed some fluctuations in coke formation corresponding to cracking cycles, which might indicate deterioration and recovery of the oxide layer during cracking/decoking cycles . 33/43 Cr–Ni and Cr–Mn-Coated coupons showed some aging after the second and third cracking cycles, respectively, which demonstrates that the negative effect of aging was superior to the positive effect of oxide layer recovery.…”

Section: Resultsmentioning

confidence: 98%

“…To reduce coke formation in reactor furnaces, researchers have examined numerous methodologies, mostly categorized into three groups: three-dimensional (3D) reactor technology, ,,− surface modification, − and feed additives. ,− Surface technologies, the focus of this work, aim to mitigate or eliminate catalytic coke formation by covering up the surface catalytic sites (nickel and iron). In fact, at the beginning of the reaction, highly active catalytic sites on the surface of the metals are in direct contact with the carbon-rich atmosphere.…”

Section: Introductionmentioning

confidence: 99%

Carburization of High-Temperature Alloys during Steam Cracking: The Impact of Alloy Composition and Temperature

Shirazi

Ghanbari

Vermeire

et al. 2023

Ind. Eng. Chem. Res.

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Prior studies found that the carburization tendency is negligible for technically developed materials at temperatures below 900 °C, especially for Al-containing alloys compared to non-Al-containing alloys applied in steam cracking reactors. However, it is unclear whether this benefit remains at higher temperatures. This work compared coke deposition tendencies of recently developed alloys to each other and to a conventional material when cracking ethane at a higher temperature (950 °C) than previously reported. Under the studied experimental conditions, coking rates vary in the range of 1.22 × 10 −6 to 20.5 × 10 −6 kg/(m 2 • s) for Al-containing alloys, while for non-Al-containing alloys, coke deposition rates fall in a range of 4.95 × 10 −6 to 33 × 10 −6 kg/ (m 2 •s). In general, aluminum-containing alloys showed less coke formation and improved stability against aging after five cracking cycles compared to the non-aluminum-containing materials. The results also showed that substantially less, if any, carburization could be detected in developed alloys even at high temperatures, in contrast to the results from a reference conventional alloy of 27/ 34 Cr−Ni. At higher temperatures, the protective oxide surface layer of the Al-containing alloys remained noticeably durable and integrated with negligible spallation compared to the ones of non-Al-containing alloys. In fact, the 27/34 Cr−Ni alloy showed the highest coking rate and carburization, implying the most vulnerable oxide surface layer relative to the other alloys. However, energydispersive X-ray (EDX) results showed no signs of carburization or deterioration of the surface of 27/34 Cr−Ni after experiments at 880 °C, indicating that both the temperature and matrix composition can play significant roles in determining the suitability of an alloy for application in steam crackers.

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Steam reforming kinetics of olefins and aromatics over Mn-Cr-O spinel oxides

Liu

Bukhovko

Malek

et al. 2021

Journal of Catalysis

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Enhanced Coke Gasification Activity of the Mn_1.5Cr_1.5O₄ Spinel Catalyst during Coking in Ethylene–Steam Mixtures

Cited by 5 publications

References 53 publications

Anticoking Performance of Electrodeposited Mn/MnO Surface Coating on Fe–Ni–Cr Alloy during Steam Cracking

Anticoking Performance of Electrodeposited Mn/MnO Surface Coating on Fe–Ni–Cr Alloy during Steam Cracking

Carburization of High-Temperature Alloys during Steam Cracking: The Impact of Alloy Composition and Temperature

Steam reforming kinetics of olefins and aromatics over Mn-Cr-O spinel oxides

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