A Comparative Study on the Performance of Direct Carbon Solid Oxide Fuel Cells Powered with Different Rank Coals

Liu, Guoyang; Zhang, Yating; Zhou, Anning; Wang, Junzhe; Cai, Jiangtao; Dang, Yongqiang

doi:10.1021/acs.energyfuels.1c00051

Cited by 5 publications

(2 citation statements)

References 46 publications

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“…Different carbon materials have been used as the fuel in MC-DCFCs [49,52,54,[127][128][129][130][131] and SO-DCFCs [132][133][134][135][136][137]. Generally, a high surface area and a small particle size of carbon fuel can improve its electrochemical reactivity by increasing the interaction between the carbon particles and the anode catalyst.…”

Section: Effect Of the Type Of Carbonmentioning

confidence: 99%

Molten Metals and Molten Carbonates in Solid Oxide Direct Carbon Fuel Cell Anode Chamber: Liquid Metal Anode and Hybrid Direct Carbon Fuel Cells

Antolini¹

2023

Catalysts

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To enhance the contact between the electrolyte (source of O2−) and the carbon fuel in solid oxide–direct carbon fuel cells (SO-DCFCs), molten metals and molten salts were used in the anode chamber. Oxygen ions can dissolve and be transported in the molten medium to the anode three-phase boundary to reach and oxidize the carbon particles. To improve the sluggish kinetics of the electrochemical oxidation of carbon, the same molten media can act as redox mediators. Moreover, using a liquid metal/salt anode, tolerant to fuel impurities, the negative effect of carbon contaminants on cell performance is mitigated. In this work, an overview of SO-DCFCs with liquid metals, liquid carbonates, and mixed liquid metals/liquid carbonates in the anode chamber is presented and their performance was compared to that of conventional SO-DCFCs.

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Section: Effect Of the Type Of Carbonmentioning

confidence: 99%

Molten Metals and Molten Carbonates in Solid Oxide Direct Carbon Fuel Cell Anode Chamber: Liquid Metal Anode and Hybrid Direct Carbon Fuel Cells

Antolini¹

2023

Catalysts

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“…Common parameters that are used to differentiate the FC include the operating conditions, the structure of the FC, and the type of electrolyte. Depending on the polymer electrolyte used, FC can be categorized into (1) alkaline fuel cells (AFCs) (alkaline solutions as an electrolyte); (2) phosphoric acid fuel cells (PAFCs) (acidic solution); (3) molten carbonate fuel cells (MCFCs) (salt electrolyte of molten carbonate); (4) solid oxide fuel cells (SOFCs) (conducting electrolyte of ceramic ions); and (5) PEMFCs (water-based acidic polymer electrolyte). − AFC using potassium hydroxide (KOH) as an electrolyte suffers from durability issues. It is very sensitive to pollutants and normally requires oxygen of high purity.…”

Section: Introductionmentioning

confidence: 99%

A Critical Review of the Advancement Approach and Strategy in SPEEK-Based Polymer Electrolyte Membrane for Hydrogen Fuel Cell Application

Kamal,

Jaafar,

Khan

et al. 2024

Energy Fuels

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Due to rising energy demand and global warming, the world is shifting from nonrenewable energy to renewable sources, such as fuel cells (FCs), due to their high energy conversion efficiency and environmental friendliness. A proton exchange membrane fuel cell (PEMFC) is an environmentally friendly and efficient FC. It converts the chemical energy stored in hydrogen fuel into electrical energy. A polymer electrolyte membrane (PEM) is a core element of the membrane electrode assembly (MEA). It transfers a proton from the anode to cathode, restricts electron flow across the membrane surface, and prevents reactant mixing. Sulfonated poly(ether ether ketone) (SPEEK)-based membranes are effective PEMs as compared to commonly used Nafion membranes due to their excellent chemical, thermal, and mechanical stability as well as cost-effectiveness. However, it suffers from poor proton conductivity. Normally, the proton conductivity of SPEEK can be improved by enhancing the degree of sulfonation (DS) and temperature and reducing the relative humidity (RH). However, the high DS of SPEEK and temperature with low RH tend to reduce the mechanical strength of PEM, which consequently sacrifices the membrane's lifetime. Therefore, the design of efficient SPEEK PEMs requires further modifications to improve the proton conductivity and strength, which can simultaneously enhance single-cell performance and durability. Therefore, this article reviews the advancements and various strategies to achieve high-performance and long-lived SPEEK-based PEMs. First, the tuning of SPEEK was performed by varying the DS of SPEEK. Second, the progress of modifying SPEEK with inorganic nano additives and metal−organic frameworks (MOFs) was also discussed comprehensively. The review also summarizes the influence of electrically and magnetically aligned nanoparticles on FC performance and membrane durability. Thus, the present review paper can be used as a reference for controlling different parameters to develop both efficient and durable SPEEK-based PEMs that can potentially compete with Nafion-based membranes for FC applications.

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A comprehensive review of solid oxide fuel cells operating on various promising alternative fuels

Guo

Xia

et al. 2022

Energy Conversion and Management

173

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A Comparative Study on the Performance of Direct Carbon Solid Oxide Fuel Cells Powered with Different Rank Coals

Cited by 5 publications

References 46 publications

Molten Metals and Molten Carbonates in Solid Oxide Direct Carbon Fuel Cell Anode Chamber: Liquid Metal Anode and Hybrid Direct Carbon Fuel Cells

Molten Metals and Molten Carbonates in Solid Oxide Direct Carbon Fuel Cell Anode Chamber: Liquid Metal Anode and Hybrid Direct Carbon Fuel Cells

A Critical Review of the Advancement Approach and Strategy in SPEEK-Based Polymer Electrolyte Membrane for Hydrogen Fuel Cell Application

A comprehensive review of solid oxide fuel cells operating on various promising alternative fuels

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