{"title":"Integration of smart electronics and energy systems","authors":"Sunkook Kim, Jung Ho Kim","doi":"10.1002/eom2.12404","DOIUrl":null,"url":null,"abstract":"<p>The special issue on “Integration of Smart Electronics and Energy Systems” aims to delve into the intricate interplay between these two domains, specifically emphasizing environmental sustainability and materials innovation. This issue seeks to showcase cutting-edge advancements, multifaceted challenges, and emerging opportunities in achieving efficient and sustainable energy systems through the seamless integration of smart electronics. The environmental aspect of this research encompasses efforts to minimize energy consumption, reduce greenhouse gas emissions, and mitigate the environmental impact associated with electronics manufacturing and disposal. Contributions are sought in areas such as renewable energy integration, energy-efficient technologies, and strategies for reducing carbon footprints. Moreover, these studies delve into the environmental considerations involved in the design, deployment, and operation of smart electronics and energy systems, intending to ensure long-term sustainability and the preservation of valuable resources. Simultaneously, the materials dimension occupies a pivotal role in this integration, expanding the horizons of research and innovation. Recent research seeks advances in developing and utilizing innovative materials for smart electronics and energy systems. This includes investigations into new materials with enhanced electrical, thermal, and mechanical properties alongside materials facilitating efficient energy harvesting, storage, and conversion mechanisms. Contributions spanning the domains of nanomaterials, organic electronics, flexible and stretchable materials, and novel composites used in energy devices and smart electronics are highly encouraged. Notably, this special issue accentuates studies demonstrating how material breakthroughs and advancements precipitate the integration of electronics and energy systems, thereby fostering improvements in performance, reliability, and longevity.</p><p>Recent research endeavors have made remarkable strides in materials science and technology, effectuating advancements across multifarious spheres. Topological catalysts based on semimetals have evinced remarkable catalytic performance in diverse electrochemical reactions, with a special focus on the hydrogen evolution reaction. Noteworthy progress has been achieved in all-solid-state batteries by advancing the forefront of high-energy-density anode materials, effectively rendering them highly suitable for employment in electric vehicles and energy storage systems. The remarkable potential of eco-friendly triboelectric nanogenerators lies in harnessing renewable kinetic energy through the ingenious deployment of nature-derived biomaterials. Pioneering research has been undertaken to mitigate the toxicity associated with lead in metal halide perovskite solar cells by exploring lead-free compositions and innovative recycling strategies. Prominent research thrusts have also been dedicated to developing optimized sensors, enabling real-time monitoring of diverse environmental factors within ecosystems. Additionally, the domain of bioelectronics has emerged as a pioneering domain, offering patient-friendly healthcare solutions with custom designs and eco-friendly approaches. These advancements collectively contribute to the realization of sustainable and innovative materials and technologies, thereby effectively addressing global challenges and fostering heightened environmental consciousness across an array of scientific disciplines. By highlighting the dimensions of environmental sustainability and materials innovation, we seek to make a valuable contribution toward the broader goal of forging a greener and more efficient future through the cohesive integration of smart electronics and energy systems.</p><p>In summary, we have observed remarkable accomplishments in integrating smart electronics and energy systems to achieve efficient and sustainable solutions. As guest editors, our objective is for this special issue to provide readers with a comprehensive understanding of the intricate mechanisms underlying this integration. A key emphasis is placed on minimizing energy consumption by adopting energy-efficient technologies and strategies. Additionally, exploring innovative materials plays a crucial role in enhancing the performance and reliability of smart electronics and energy systems.</p><p>The special issue, including five original articles and seven review articles, delving into the use of renewable energy sources and implementing carbon footprint reduction measures to ensure a sustainable future. Finally, the guest editors—Professor Jung Ho Kim at University of Wollongong and Professor Sunkook Kim at Sungkyunkwan University—express their sincere gratitude to all the contributing authors, reviewers, and the <b>EcoMat</b> editorial team—Dr. Wai-Sum Lo as Managing Editor and Professor Zijian Zheng as Editor-in-Chief at the Hong Kong Polytechnic University—for their valuable contributions and support in bringing this special issue to fruition.</p><p>The authors declare no conflict of interest.</p>","PeriodicalId":93174,"journal":{"name":"EcoMat","volume":"5 9","pages":""},"PeriodicalIF":10.7000,"publicationDate":"2023-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/eom2.12404","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"EcoMat","FirstCategoryId":"1085","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/eom2.12404","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"CHEMISTRY, PHYSICAL","Score":null,"Total":0}
引用次数: 0
Abstract
The special issue on “Integration of Smart Electronics and Energy Systems” aims to delve into the intricate interplay between these two domains, specifically emphasizing environmental sustainability and materials innovation. This issue seeks to showcase cutting-edge advancements, multifaceted challenges, and emerging opportunities in achieving efficient and sustainable energy systems through the seamless integration of smart electronics. The environmental aspect of this research encompasses efforts to minimize energy consumption, reduce greenhouse gas emissions, and mitigate the environmental impact associated with electronics manufacturing and disposal. Contributions are sought in areas such as renewable energy integration, energy-efficient technologies, and strategies for reducing carbon footprints. Moreover, these studies delve into the environmental considerations involved in the design, deployment, and operation of smart electronics and energy systems, intending to ensure long-term sustainability and the preservation of valuable resources. Simultaneously, the materials dimension occupies a pivotal role in this integration, expanding the horizons of research and innovation. Recent research seeks advances in developing and utilizing innovative materials for smart electronics and energy systems. This includes investigations into new materials with enhanced electrical, thermal, and mechanical properties alongside materials facilitating efficient energy harvesting, storage, and conversion mechanisms. Contributions spanning the domains of nanomaterials, organic electronics, flexible and stretchable materials, and novel composites used in energy devices and smart electronics are highly encouraged. Notably, this special issue accentuates studies demonstrating how material breakthroughs and advancements precipitate the integration of electronics and energy systems, thereby fostering improvements in performance, reliability, and longevity.
Recent research endeavors have made remarkable strides in materials science and technology, effectuating advancements across multifarious spheres. Topological catalysts based on semimetals have evinced remarkable catalytic performance in diverse electrochemical reactions, with a special focus on the hydrogen evolution reaction. Noteworthy progress has been achieved in all-solid-state batteries by advancing the forefront of high-energy-density anode materials, effectively rendering them highly suitable for employment in electric vehicles and energy storage systems. The remarkable potential of eco-friendly triboelectric nanogenerators lies in harnessing renewable kinetic energy through the ingenious deployment of nature-derived biomaterials. Pioneering research has been undertaken to mitigate the toxicity associated with lead in metal halide perovskite solar cells by exploring lead-free compositions and innovative recycling strategies. Prominent research thrusts have also been dedicated to developing optimized sensors, enabling real-time monitoring of diverse environmental factors within ecosystems. Additionally, the domain of bioelectronics has emerged as a pioneering domain, offering patient-friendly healthcare solutions with custom designs and eco-friendly approaches. These advancements collectively contribute to the realization of sustainable and innovative materials and technologies, thereby effectively addressing global challenges and fostering heightened environmental consciousness across an array of scientific disciplines. By highlighting the dimensions of environmental sustainability and materials innovation, we seek to make a valuable contribution toward the broader goal of forging a greener and more efficient future through the cohesive integration of smart electronics and energy systems.
In summary, we have observed remarkable accomplishments in integrating smart electronics and energy systems to achieve efficient and sustainable solutions. As guest editors, our objective is for this special issue to provide readers with a comprehensive understanding of the intricate mechanisms underlying this integration. A key emphasis is placed on minimizing energy consumption by adopting energy-efficient technologies and strategies. Additionally, exploring innovative materials plays a crucial role in enhancing the performance and reliability of smart electronics and energy systems.
The special issue, including five original articles and seven review articles, delving into the use of renewable energy sources and implementing carbon footprint reduction measures to ensure a sustainable future. Finally, the guest editors—Professor Jung Ho Kim at University of Wollongong and Professor Sunkook Kim at Sungkyunkwan University—express their sincere gratitude to all the contributing authors, reviewers, and the EcoMat editorial team—Dr. Wai-Sum Lo as Managing Editor and Professor Zijian Zheng as Editor-in-Chief at the Hong Kong Polytechnic University—for their valuable contributions and support in bringing this special issue to fruition.
“智能电子与能源系统的集成”特刊旨在深入研究这两个领域之间错综复杂的相互作用,特别强调环境可持续性和材料创新。本期旨在展示通过智能电子产品的无缝集成实现高效和可持续能源系统的前沿进展、多方面的挑战和新兴机遇。本研究的环境方面包括努力减少能源消耗,减少温室气体排放,以及减轻与电子产品制造和处置相关的环境影响。寻求在可再生能源整合、节能技术和减少碳足迹战略等领域作出贡献。此外,这些研究深入研究了智能电子和能源系统的设计、部署和运行中涉及的环境因素,旨在确保长期可持续性和宝贵资源的保护。同时,材料维度在这种整合中起着关键作用,扩大了研究和创新的视野。最近的研究寻求在开发和利用智能电子和能源系统的创新材料方面取得进展。这包括研究具有增强的电学、热学和机械性能的新材料,以及促进高效能量收集、存储和转换机制的材料。高度鼓励在纳米材料,有机电子,柔性和可拉伸材料以及用于能源设备和智能电子的新型复合材料领域做出贡献。值得注意的是,本期特刊着重介绍了材料的突破和进步如何促进电子和能源系统的集成,从而促进性能、可靠性和寿命的提高。近年来的研究工作在材料科学和技术方面取得了显著的进展,在各个领域都取得了进步。基于半金属的拓扑催化剂在多种电化学反应中表现出显著的催化性能,特别是在析氢反应中。通过推进高能量密度负极材料的前沿,全固态电池取得了显著进展,有效地使其非常适合用于电动汽车和储能系统。生态友好型摩擦电纳米发电机的巨大潜力在于,它通过巧妙地利用源自自然的生物材料来利用可再生动能。通过探索无铅成分和创新的回收策略,开展了开创性的研究,以减轻金属卤化物钙钛矿太阳能电池中铅的毒性。突出的研究重点还致力于开发优化的传感器,以便实时监测生态系统内的各种环境因素。此外,生物电子学领域已成为一个开创性的领域,提供具有定制设计和环保方法的患者友好型医疗保健解决方案。这些进步共同有助于实现可持续和创新的材料和技术,从而有效地应对全球挑战,并在一系列科学学科中培养更高的环境意识。通过强调环境可持续性和材料创新的维度,我们寻求通过智能电子和能源系统的内聚集成,为打造更绿色、更高效的未来这一更广泛的目标做出有价值的贡献。总之,我们在整合智能电子和能源系统以实现高效和可持续解决方案方面取得了显著成就。作为客座编辑,我们的目标是在本期特刊中为读者提供对这种集成背后复杂机制的全面理解。重点是通过采用节能技术和战略尽量减少能源消耗。此外,探索创新材料在提高智能电子和能源系统的性能和可靠性方面起着至关重要的作用。本期特刊包括5篇原创文章和7篇评论文章,深入探讨了可再生能源的使用和实施减少碳足迹的措施,以确保可持续的未来。最后,我们的客座编辑——伍伦贡大学的Jung Ho Kim教授和成均馆大学的Sunkook Kim教授——向所有的撰稿人、审稿人和EcoMat编辑团队表示衷心的感谢。 香港理工大学行政总编辑罗伟心及总编辑郑子健教授,感谢他们为本期特刊作出宝贵贡献及支持。作者声明无利益冲突。