Electrospun CNF Supported Ceramics as Electrochemical Catalysts for Water Splitting and Fuel Cell: A Review

Verma, Sahil; Sinha-Ray, Sumit

doi:10.3390/polym12010238

Cited by 42 publications

(11 citation statements)

References 122 publications

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“…Accordingly, timely and comprehensive reviews about meaningful works in this area is of significant necessity, providing a useful guide to the following research. Although a limited number of reviews are accessible on the recent development of self-supported electrocatalysts for water electrolysis, [44,[50][51][52][53][54] most of them overviewed from the perspectives of various TM-based compounds, [50,51] or geometric constructions, [44] or synthetic methods, [52,53] or selection of supported substrates. [54] Most importantly, an overall systematic and comprehensive review that is dedicated to reveal promising self-supported electrocatalysts for practical water electrolysis is still lacking.…”

Section: Introductionmentioning

confidence: 99%

Self‐Supported Electrocatalysts for Practical Water Electrolysis

Yang

Drieß

Menezes

2021

Advanced Energy Materials

213

146

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Over the years, significant advances have been made to boost the efficiency of water splitting by carefully designing economic electrocatalysts with augmented conductivity, more accessible active sites, and high intrinsic activity in laboratory test conditions. However, it remains a challenge to develop earth‐abundant catalysts that can satisfy the demands of practical water electrolysis, that is, outstanding all‐pH electrolyte capacity, direct seawater splitting ability, exceptional performance for overall water splitting, superior large‐current‐density activity, and robust long‐term durability. In this context, considering the features of increased active species loading, rapid charge, and mass transfer, a strong affinity between catalytic components and substrates, easily‐controlled wettability, as well as, enhanced bifunctional performance, the self‐supported electrocatalysts are presently projected to be the most suitable contenders for practical massive scale hydrogen generation. In this review, a comprehensive introduction to the design and fabrication of self‐supported electrocatalysts with an emphasis on the design of deposited nanostructured catalysts, the selection of self‐supported substrates, and various fabrication methods are provided. Thereafter, the recent development of promising self‐supported electrocatalysts for practical applications is reviewed from the aforementioned aspects. Finally, a brief conclusion is delivered and the challenges and perspectives relating to promotion of self‐supported electrocatalysts for sustainable large‐scale production of hydrogen are discussed.

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Section: Introductionmentioning

confidence: 99%

Self‐Supported Electrocatalysts for Practical Water Electrolysis

Yang

Drieß

Menezes

2021

Advanced Energy Materials

213

146

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“…Electrospinning is one of the widely accepted fabrication methodof developing nanofibers with good performance for various applications like catalysis, [65] drug delivery, [66] energy storage, [67] etc. Yang et al developed MXene/polyurethane mat through electrospinning.…”

Section: Mxene Based Sensorsmentioning

confidence: 99%

MXene Based Sensing Materials: Current Status and Future Perspectives

Sivasankarapillai¹,

Sharma²,

Hwa³

et al. 2022

ES Energy Environ.

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MXenes are a family of two-dimensional multifunctional materials in a rapid development phase since their discovery in 2011. MXenes possess excellent features like high conductivity and surface area, improved mechanical properties, hydrophilicity, and ability to tune the surface properties with modifying functional groups. These features make MXenes suitable candidates for a wide range of applications, including biomedical and energy storage. This review is focused on various types of MXenes which are recently reported for sensor applications. The current scenario regarding fabrication and properties of MXenes are initially described, followed by a discussion of their applications as piezoresistive and biochemical sensors. This involves mechanical strain detection and detection of biomolecules, biomarkers, and drug molecules relevant to biomedical applications. Finally, the future perspectives are briefly discussed, which will help the researchers identify the limitations for the current scenario and develop new strategies that focus on developing novel, efficient and sensitive MXene based sensors.

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“…These can prepare rapid ion diffusion channels, which is advantageous when attempting to obtain high Li + storage capacity [35]. A variety of NPCs have been investigated, such as carbon nanofibers [80,81] carbon nanocages [82,83], nitrogen- Although the production and application of carbon materials from overall biomass were extensively reviewed [3,73,74], very little attention has been paid to value-added carbons derived from fish industry waste, which are only briefly described. In the authors' opinion, the very significant and recent advances in fish waste-derived materials deserve to be reviewed, owing to their strategic importance for the sustainability of energy storage devices.…”

Section: Applications In Lithium-ion Batteries (Libs)mentioning

confidence: 99%

“…These can prepare rapid ion diffusion channels, which is advantageous when attempting to obtain high Li + storage capacity [35]. A variety of NPCs have been investigated, such as carbon nanofibers [80,81] carbon nanocages [82,83], nitrogen-enriched nanocarbons [84,85], etc. Their porous structures can reduce the diffusion length of Li-ions, while their high specific surface area offers abundant active sites for Li + storage reactions [86].…”

Section: Applications In Lithium-ion Batteries (Libs)mentioning

confidence: 99%

Sustainable Materials from Fish Industry Waste for Electrochemical Energy Systems

2021

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Fish industry waste is attracting growing interest for the production of environmentally friendly materials for several different applications, due to the potential for reduced environmental impact and increased socioeconomic benefits. Recently, the application of fish industry waste for the synthesis of value-added materials and energy storage systems represents a feasible route to strengthen the overall sustainability of energy storage product lines. This review focused on an in-depth outlook on the advances in fish byproduct-derived materials for energy storage devices, including lithium-ion batteries (LIBs), sodium-ion (NIBs) batteries, lithium-sulfur batteries (LSBs), supercapacitors and protein batteries. For each of these, the latest applications were presented together with approaches to improve the electrochemical performance of the obtained materials. By analyzing the recent literature on this topic, this review aimed to contribute to further advances in the sustainability of energy storage devices.

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Electrospun CNF Supported Ceramics as Electrochemical Catalysts for Water Splitting and Fuel Cell: A Review

Cited by 42 publications

References 122 publications

Self‐Supported Electrocatalysts for Practical Water Electrolysis

Self‐Supported Electrocatalysts for Practical Water Electrolysis

MXene Based Sensing Materials: Current Status and Future Perspectives

Sustainable Materials from Fish Industry Waste for Electrochemical Energy Systems

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