Investigation of Ni/SiO2 catalysts prepared at different conditions for hydrogen production from ethanol steam reforming

Wu, Chunfei; Dupont, Valerie; Nahil, Mohamad A.; Dou, Binlin; Chen, Haisheng; Williams, Paul T.

doi:10.1016/j.joei.2016.01.002

Cited by 32 publications

(22 citation statements)

References 36 publications

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“…Two‐stage fixed‐bed reactor has been adopted to perform ethanol reforming test. The reactor setup is shown in Figure , which is similar to our previous work . The ethanol and water mixture with S/C molar ratio of 3 was preheated to 250°C in the first reactor, which was inoculated in first reactor by a syringe pump.…”

Section: Experimental and Methodsmentioning

confidence: 88%

“…In a study of Kim et al, 30% Ni/SBA‐15 catalyst, S/C ratio of 1.5, and 550°C to 800°C temperature range have been employed for ethanol steam reforming, and the corresponding hydrogen yield could reach about 70% at 700°C. Wu et al obtained a maximum hydrogen yield of 72.0% at 20% Ni/SiO 2 catalyst, S/C ratio of 4, and reforming temperature of 600°C from ethanol steam reforming. These revealed that the performance of the synthesized Ni/CaO catalysts is analogous with other ethanol steam reforming catalysts.…”

Section: Resultsmentioning

confidence: 99%

“…Among these methods, catalytic ethanol steam reforming is promising because ethanol is low volatile and nontoxic, and is easy to handle and transport. In addition, it has a high content of hydrogen, and it can be stored easily …”

Section: Introductionmentioning

confidence: 99%

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Ethanol steam reforming on Ni/CaO catalysts for coproduction of hydrogen and carbon nanotubes

et al. 2019

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Summary Catalytic steam reforming of ethanol is considered as a promising technology for producing H2 in the modern world. In this study, using a fixed‐bed reactor, steam reforming of ethanol was performed for production of carbon nanotubes (CNTs) and H2 simultaneously at 600°C on Ni/CaO catalysts. Commercial CaO and a synthetic CaO prepared using sol‐gel were scrutinized for ethanol's catalytic steam reforming. Analysis results of N2 isothermal adsorption indicate that the CaO synthesized by sol‐gel has more pore volume and surface area in comparison with the commercial CaO. When Ni was loaded, the Ni/CaO catalyst shows an encouraging catalytic property for H2 production, and an increase in Ni loading could improve H2 production. The Ni/CaO catalyst with sol‐gel CaO support has presented a higher hydrogen production and better catalytic stability than the catalysts with the commercial CaO support at low Ni loading. The highest hydrogen yield is 76.8% at Ni loading content of 10% for the Ni/sol‐gel CaO catalyst with WHSV of 3.32/h and S/C ratio of 3. The carbon formed after steam reforming primarily consists of filamentous carbons and amorphous carbons, and CNTs are the predominant type of carbon deposition. The deposited extent of carbon on the used Ni/CaO catalyst lessen upon more Ni loading, and the elongated CNTs are desired to be formed at the surface of the Ni/sol‐gel CaO catalyst. Thus, an efficient process and improved economic value is associated with prompt hydrogen production and CNTs from ethanol steam reforming.

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Section: Experimental and Methodsmentioning

confidence: 88%

Section: Resultsmentioning

confidence: 99%

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Ethanol steam reforming on Ni/CaO catalysts for coproduction of hydrogen and carbon nanotubes

et al. 2019

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“…It is well known that most of the catalyst deactivation of ESR is attributed to the active metal sintering and the deposition of various type of carbon on the surface of the catalyst [41,42]. How to solve these problems is the main challenge in this field.…”

Section: Discussionmentioning

confidence: 99%

Improved H2 Production by Ethanol Steam Reforming over Sc2O3-Doped Co-ZnO Catalysts

et al. 2017

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H 2 production by catalytically ethanol steam reforming (ESR) is an effective and prospective method for the application of fuel cells. However, the catalysts' desirable activity and stability remains an unprecedented challenge. Herein, a type of Sc 2 O 3 -doped Co-ZnO catalyst was developed by a co-precipitation method. The so-constructed Co 2 Zn 1 Sc 0.3 catalyst exhibited a superb catalytic performance compared with Co-ZnO, giving a STY(H 2 ) as high as 1.099 mol·h −1 ·g -cat −1 (data taken 100 h after the reaction started). In comparison, the pristine Co-ZnO catalyst only afforded a STY(H 2 ) of 0.684 mol·h −1 ·g -cat −1 under identical reaction conditions. Characterization results revealed that the Sc 2 O 3 dopant strengthened the electronic interaction between Co species and ZnO, which was in favour of elevating the reduction temperature of Co oxides and boosting the dispersion of the Co n+ (n = 1 or 2). The introduction of Sc 2 O 3 induced the formation of O 2− and OH − . All of these effects effectively inhibited the sintering of active Co species and markedly improved the activity and operating stability of the catalyst.

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“…Apart from the nature and composition of the mixed oxides, the different preparation methods of these mixed oxides have been studied to achieve high hydrogen yields , , , , , , . The sol‐gel method can produce a mesoporous structure of the catalysts , , , , , , which can improve the mass transfer efficiency and diminish the deactivation rate . For a zeolite as the support, the sol‐gel incipient wetness impregnation (SIWI) method produces a hierarchical structure, improving the catalyst stability .…”

Section: Effects Of the Supportmentioning

confidence: 99%

Effect of Supports and Promoters on the Performance of Ni‐Based Catalysts in Ethanol Steam Reforming

et al. 2020

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Ethanol steam reforming (ESR) is one of the potential processes to convert ethanol into valuable products. Hydrogen produced from ESR is considered as green energy for the future and can be an excellent alternative to fossil fuels with the aim of mitigating the greenhouse gas effect. The ESR process has been well studied, using transition metals as catalysts coupled with both acidic and basic oxides as supports. Among various reported transition metals, Ni is an inexpensive material with activity comparable to that of noble metals, showing promising ethanol conversion and hydrogen yields. Additionally, different promoters and supports were utilized to enhance the hydrogen yield and the catalyst stability. This review summarizes and discusses the influences of the supports and promoters of Ni‐based catalysts on the ESR process.

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Investigation of Ni/SiO2 catalysts prepared at different conditions for hydrogen production from ethanol steam reforming

Cited by 32 publications

References 36 publications

Ethanol steam reforming on Ni/CaO catalysts for coproduction of hydrogen and carbon nanotubes

Ethanol steam reforming on Ni/CaO catalysts for coproduction of hydrogen and carbon nanotubes

Improved H2 Production by Ethanol Steam Reforming over Sc2O3-Doped Co-ZnO Catalysts

Effect of Supports and Promoters on the Performance of Ni‐Based Catalysts in Ethanol Steam Reforming

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