An overview of the methanol reforming process: Comparison of fuels, catalysts, reformers, and systems

Herdem, Münür Sacit; Sinaki, Maryam Younessi; Farhad, Siamak; Hamdullahpur, Feridun

doi:10.1002/er.4440

Cited by 89 publications

(35 citation statements)

References 149 publications

(212 reference statements)

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“…[ 1–5 ] Currently, Hydrogen is mainly extracted from the reforming of traditional hydrocarbons such as diesel, methane and methanol, and the coal gasification process. [ 6–9 ] However, among those processes, massive environment‐unfriendly by‐products (e.g., CO, CO 2 ) are usually generated together with hydrogen production. Electrochemical hydrogen evolution reaction (HER) has been attracted more and more attention recently since it is considered as one of the greenest technologies to produce hydrogen.…”

Section: Introductionmentioning

confidence: 99%

Synergistically Tuning Electronic Structure of Porous β‐Mo₂C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity

Chen

Geng

et al. 2020

Adv Funct Materials

161

120

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The development of novel non-noble electrocatalysts with controlled structure and surface composition is critical for efficient electrochemical hydrogen evolution reaction (HER). Herein, the rational design of porous molybdenum carbide (β-Mo 2 C) spheres with different surface engineered structures (Co doping, Mo vacancies generation, and coexistence of Co doping and Mo vacancies) is performed to enhance the HER performance over the β-Mo 2 C-based catalyst surface. Density functional theory calculations and experimental results reveal that the synergistic effect of Co doping with Mo vacancies increases the electron density around the Fermi-level and modulates the d band center of β-Mo 2 C so that the strength of the MoH bond is reasonably optimized, thus leading to an enhanced HER kinetics. As expected, the optimized Co 50 -Mo 2 C-12 with porous structure displays a low overpotential (η 10 = 125 mV), low-onset overpotential (η onset = 27 mV), and high exchange current density (j 0 = 0.178 mA cm −2 ). Furthermore, this strategy is also successfully extended to develop other effective metal (e.g., Fe and Ni) doped β-Mo 2 C electrocatalyst, indicating that it is a universal strategy for the rational design of highly efficient metal carbide-based HER catalysts and beyond.

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Section: Introductionmentioning

confidence: 99%

Synergistically Tuning Electronic Structure of Porous β‐Mo₂C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity

Chen

Geng

et al. 2020

Adv Funct Materials

161

120

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“…Fuel cell is an attractive environmentally friendly energy conversion technology, but its application is very limited due to the difficulties associated with the transportation and storage of hydrogen [1][2][3]. A promising route for the broad adoption of fuel cells is through the so-called onboard fuel cell technology where H 2 is obtained via real-time steam reforming of hydrocarbon, such as methanol, which is liquid at room temperature and normal pressure [3,4].…”

Section: Introductionmentioning

confidence: 99%

“…Cu is the most commonly used commercial catalyst for the methanol steam reforming (MSR), CH 3 OH + H 2 O CO 2 + 3H 2 . However, Cu-catalyst suffers from some serious drawbacks such as pyrophoricity and catalyst sintering [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Density Functional Theory Based Micro- and Macro-Kinetic Studies of Ni-Catalyzed Methanol Steam Reforming

Lin

2020

Catalysts

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The intrinsic mechanism of Ni-catalyzed methanol steam reforming (MSR) is examined by considering 54 elementary reaction steps involved in MSR over Ni(111). Density functional theory computations and transition state theory analyses are performed on the elementary reaction network. A microkinetic model is constructed by combining the quantum chemical results with a continuous stirring tank reactor model. MSR rates deduced from the microkinetic model agree with the available experimental data. The microkinetic model is used to identify the main reaction pathway, the rate determining step, and the coverages of surface species. An analytical expression of MSR rate is derived based on the dominant reaction pathway and the coverages of surface species. The analytical rate equation is easy to use and should be very helpful for the design and optimization of the operating conditions of MSR.

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“…A comprehensive review of the hydrogen production methods, including the environmental and economic impacts, is discussed in Acar and Dincer . More specially, a review on hydrogen production from methanol reforming can be found in Herdem et al…”

Section: Introductionmentioning

confidence: 99%

“…A comprehensive review of the hydrogen production methods, including the environmental and economic impacts, is discussed in Acar and Dincer. 1 More specially, a review on hydrogen production from methanol reforming can be found in Herdem et al 2 The reaction between Al and H 2 O is slow at low temperatures due to the coherent alumina (Al 2 O 3 ) passivation layer around the Al core that prevents its oxidation. Water must hydrate the Al 2 O 3 layer in order to break the Al─O bonds.…”

Section: Introductionmentioning

confidence: 99%

Tunable kinetics of nanoaluminum and microaluminum powders reacting with water to produce hydrogen

et al. 2019

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Summary This paper reports on the kinetics and reaction processes of 40‐nm and 1‐μm aluminum powders with water to produce hydrogen at atmospheric pressure. This reaction produces aluminum hydroxide with irregular morphologies as by‐products. It was found that the nucleation and growth of the aluminum hydroxides affect the kinetics of the reaction and thus the hydrogen production. The heat release in isothermal microcalorimetry and hydrogen production in a nonisothermal batch reactor were used to determine the rate‐determining steps of the reaction mechanism and the corresponding activation energies. Model and model‐free methods have been implemented to describe the reaction sequence between aluminum particle and water while the phase of newly produced aluminum hydroxide in the system plays an important role. The reaction of nanoaluminum particles and water, being more sensitive to temperature, goes to completion to produce bayerite, Al (OH)3 at 30°C, and boehmite, AlOOH at 50°C, whereas the microaluminum particles do not react completely and produce only bayerite at 30°C and also low‐amount boehmite at 50°C. Nevertheless, these processes exhibit two distinct and sequential stages: a kinetically controlled stage with the apparent activation energy (Ea) of 100 to 110 kJ/mol, where nucleation and growth are limited by the chemical reactions on the surface of aluminum, and a diffusion controlled stage with Ea of 44 kJ/mol for the 40‐nm Al/water reaction and 86 kJ/mol for the 1‐μm Al/water reaction, where growth is limited by the mass diffusion through the aluminum hydroxide by‐products. The separation of these two stages is more obvious under isothermal conditions. For nonisothermal conditions, two stages are overlapped, and the one with a lower Ea dominates.

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An overview of the methanol reforming process: Comparison of fuels, catalysts, reformers, and systems

Cited by 89 publications

References 149 publications

Synergistically Tuning Electronic Structure of Porous β‐Mo₂C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity

Synergistically Tuning Electronic Structure of Porous β‐Mo₂C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity

Density Functional Theory Based Micro- and Macro-Kinetic Studies of Ni-Catalyzed Methanol Steam Reforming

Tunable kinetics of nanoaluminum and microaluminum powders reacting with water to produce hydrogen

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An overview of the methanol reforming process: Comparison of fuels, catalysts, reformers, and systems

Cited by 89 publications

References 149 publications

Synergistically Tuning Electronic Structure of Porous β‐Mo2C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity

Synergistically Tuning Electronic Structure of Porous β‐Mo2C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity

Density Functional Theory Based Micro- and Macro-Kinetic Studies of Ni-Catalyzed Methanol Steam Reforming

Tunable kinetics of nanoaluminum and microaluminum powders reacting with water to produce hydrogen

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Synergistically Tuning Electronic Structure of Porous β‐Mo₂C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity

Synergistically Tuning Electronic Structure of Porous β‐Mo₂C Spheres by Co Doping and Mo‐Vacancies Defect Engineering for Optimizing Hydrogen Evolution Reaction Activity