Two‐Dimensional Conducting Polymers: Synthesis and Charge Transport

Barpuzary, Dipankar; Kim, Kyoungwook; Park, Moon Jeong

doi:10.1002/polb.24777

Cited by 10 publications

(2 citation statements)

References 25 publications

(53 reference statements)

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“…Self-supporting 2D CPs are essential for electronic and electrochemical applications. 37 Their planar configuration not only enhances the charge transport efficiency but also allows the integration of CPs into flexible and wearable devices due to their lightweight and thin characteristics. Moreover, the presence of interconnected pores spanning the 2D structures enables efficient diffusion of molecules and ions.…”

Section: Fabrication Of Self-supporting 2d Cps: Non-porous and Porous...mentioning

confidence: 99%

“…Furthermore, we investigate methods to achieve highly crystalline 2D-like CPs with porous morphologies and to produce self-supporting films. Promising future avenues, such as ice-assisted methods [34][35][36] and interfacial polymerization, [37][38][39][40] are extensively discussed. We also show some successful applications of these 2D-like porous CPs in practical devices.…”

Section: Introductionmentioning

confidence: 99%

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Porous pathways: Exploring the future of conducting polymers

Ham,

Sim,

Choi

et al. 2024

Bulletin Korean Chem Soc

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Conducting polymers (CPs) possess the intrinsic attractive properties of conventional polymers, coupled with unique electronic characteristics reminiscent of metals or semiconductors. Nanostructured CPs have recently gained significant interest for their distinct advantages over bulk counterparts. They demonstrate potential applications in energy storage devices, sensors, and catalysts, attributed to their large surface areas and shortened charge transport paths. A crucial structural aspect in this context includes introducing porous morphologies into CPs, and enhancing their functionality through interconnected channels. In this review, various synthetic methods of nanostructured CPs are introduced, emphasizing two‐dimensional (2D) configurations. The primary objective is to achieve high‐performance devices with highly organized stacking of conjugated backbones. Particular attention is placed on integrating 2D structures and porous morphologies into CPs through ice‐assisted methods and interfacial synthesis. The review also highlights successful applications of porous 2D CPs in practical devices and explores insights into future developments in the porous CPs field.

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Section: Fabrication Of Self-supporting 2d Cps: Non-porous and Porous...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Porous pathways: Exploring the future of conducting polymers

Ham,

Sim,

Choi

et al. 2024

Bulletin Korean Chem Soc

Self Cite

View full text Add to dashboard Cite

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Advancing the utilization of 2D materials for electrocatalytic seawater splitting

Ligani Fereja,

Mehmood,

et al. 2024

InfoMat

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Applying catalysts for electrochemical energy conversion holds great promise for developing clean and sustainable energy sources. One of the main advantages of electrocatalysis is its ability to reduce conversion energy loss significantly. However, the wide application of electrocatalysts in these conversion processes has been hindered by poor catalytic performance and limited resources of catalyst materials. To overcome these challenges, researchers have turned to two‐dimensional (2D) materials, which possess large specific surface areas and can easily be engineered to have desirable electronic structures, making them promising candidates for high‐performance electrocatalysis in various reactions. This comprehensive review focuses on engineering novel 2D material‐based electrocatalysts and their application to seawater splitting. The review briefly introduces the mechanism of seawater splitting and the primary challenges of 2D materials. Then, we highlight the unique advantages and regulating strategies for seawater electrolysis based on recent advancements. We also review various 2D catalyst families for direct seawater splitting and delve into the physicochemical properties of these catalysts to provide valuable insights. Finally, we outline the vital future challenges and discuss the perspectives on seawater electrolysis. This review provides valuable insights for the rational design and development of cutting‐edge 2D material electrocatalysts for seawater‐electrolysis applications.image

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