Comprehensive Insights and Advancements in Gel Catalysts for Electrochemical Energy Conversion

Bari, Gazi A. K. M. Rafiqul; Jeong, Jae-Ho

doi:10.3390/gels10010063

Cited by 4 publications

(2 citation statements)

References 172 publications

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“…Aerogel formation involves the replacement of liquid with gas without collapsing the polymer networks. This process occurs in two distinct steps: gel formation and subsequent drying (Figure 3) [42]. The drying phase presents a significant challenge, as the surface tension of the solvent within the gel can promote the destruction of the gel structure during solvent evaporation.…”

Section: Conductive Gel Materials Formation Classifications and Fabri...mentioning

confidence: 99%

Conductive Gels for Energy Storage, Conversion, and Generation: Materials Design Strategies, Properties, and Applications

Bari,

Jeong,

Barai

2024

Materials

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Gel-based materials have garnered significant interest in recent years, primarily due to their remarkable structural flexibility, ease of modulation, and cost-effective synthesis methodologies. Specifically, polymer-based conductive gels, characterized by their unique conjugated structures incorporating both localized sigma and pi bonds, have emerged as materials of choice for a wide range of applications. These gels demonstrate an exceptional integration of solid and liquid phases within a three-dimensional matrix, further enhanced by the incorporation of conductive nanofillers. This unique composition endows them with a versatility that finds application across a diverse array of fields, including wearable energy devices, health monitoring systems, robotics, and devices designed for interactive human-body integration. The multifunctional nature of gel materials is evidenced by their inherent stretchability, self-healing capabilities, and conductivity (both ionic and electrical), alongside their multidimensional properties. However, the integration of these multidimensional properties into a single gel material, tailored to meet specific mechanical and chemical requirements across various applications, presents a significant challenge. This review aims to shed light on the current advancements in gel materials, with a particular focus on their application in various devices. Additionally, it critically assesses the limitations inherent in current material design strategies and proposes potential avenues for future research, particularly in the realm of conductive gels for energy applications.

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Section: Conductive Gel Materials Formation Classifications and Fabri...mentioning

confidence: 99%

Conductive Gels for Energy Storage, Conversion, and Generation: Materials Design Strategies, Properties, and Applications

Bari,

Jeong,

Barai

2024

Materials

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“…Additionally, morphology engineering plays a pivotal role, ensuring high mass transport and maximizing the exposed surface area of the catalyst. To enhance the light-harvesting capacity within the visible region, molecular-level engineering of the materials is conducted through strain engineering, defect engineering, metal decoration, and innovative heterojunction formation [21,22]. These approaches mechanistically improve charge separation while simultaneously adjusting the band structure of the catalyst, thus enhancing its overall performance.…”

Section: Introductionmentioning

confidence: 99%

Materials Design and Development of Photocatalytic NOx Removal Technology

Bari,

Islam,

Jeong

2024

Metals

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Nitrogen oxide (NOx) pollutants have a significant impact on both the environment and human health. Photocatalytic NOx removal offers a sustainable and eco-friendly approach to combatting these pollutants by harnessing renewable solar energy. Photocatalysis demonstrates remarkable efficiency in removing NOx at sub-scale levels of parts per billion (ppb). The effectiveness of these catalysts depends on various factors, including solar light utilization efficiency, charge separation performance, reactive species adsorption, and catalytic reaction pathway selectivity. Moreover, achieving high stability and efficient photocatalytic activity necessitates a multifaceted materials design strategy. This strategy encompasses techniques such as ion doping, defects engineering, morphology control, heterojunction construction, and metal decoration on metal- or metal oxide-based photocatalysts. To optimize photocatalytic processes, adjustments to band structures, optimization of surface physiochemical states, and implementation of built-in electric field approaches are imperative. By addressing these challenges, researchers aim to develop efficient and stable photocatalysts, thus contributing to the advancement of environmentally friendly NOx removal technologies. This review highlights recent advancements in photocatalytic NOx removal, with a focus on materials design strategies, intrinsic properties, fundamental developmental aspects, and performance validation. This review also presents research gaps, emphasizing the need to understand the comprehensive mechanistic photocatalytic process, favored conditions for generating desired reactive species, the role of water concentration, temperature effects, inhibiting strategies for photocatalyst-deactivating species, and the formation of toxic NO2.

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Comprehensive Insight and Advancements in Material Design for Electrocatalytic Ammonia Production Technologies: An Alternative Clean Energy

Rafiqul Bari,

Jeong

2024

International Journal of Energy Research

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Ammonia (NH3) stands out as a promising green energy carrier in the context of the world’s future energy demands. The current ammonia production heavily relies on the energy‐intensive Haber–Bosch (H–B) process, contributing significantly to worldwide energy consumption (1–2%) and escalating carbon dioxide emissions by 1.5%. In light of the environmental and economic concerns associated with the H–B process, alternative electrochemical reduction methods for nitrogen and its derivatives have emerged as viable paths toward green energy production. While substantial research progress has been made in recent years, the transition from laboratory‐scale investigations to industrial or commercial applications has been hindered by low efficiency and selectivity in electrocatalytic systems. Establishing a cohesive strategy to advance electrocatalysts for nitrogen and its derivatives electroreduction is crucial. This study delves into a fundamental understanding of materials engineering and the modulation of electrocatalysts for ammonia production. Drawing on insights from various foundational research efforts, the aim is to provide guidance for future research directions based on fundamental principles. This exploration seeks to propel the development of electrocatalysts, addressing the current challenges and steering research toward efficient and selective electrochemical reduction processes for sustainable ammonia production.

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Comprehensive Insights and Advancements in Gel Catalysts for Electrochemical Energy Conversion

Cited by 4 publications

References 172 publications

Conductive Gels for Energy Storage, Conversion, and Generation: Materials Design Strategies, Properties, and Applications

Conductive Gels for Energy Storage, Conversion, and Generation: Materials Design Strategies, Properties, and Applications

Materials Design and Development of Photocatalytic NOx Removal Technology

Comprehensive Insight and Advancements in Material Design for Electrocatalytic Ammonia Production Technologies: An Alternative Clean Energy

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