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Sonoelectrochemistry for energy and environmental applications.
Ultrasonics Sonochemistry ( IF 8.7 ) Pub Date : 2020-01-20 , DOI: 10.1016/j.ultsonch.2020.104960 Jayaraman Theerthagiri 1 , Jagannathan Madhavan 2 , Seung Jun Lee 1 , Myong Yong Choi 1 , Muthupandian Ashokkumar 3 , Bruno G Pollet 4
Ultrasonics Sonochemistry ( IF 8.7 ) Pub Date : 2020-01-20 , DOI: 10.1016/j.ultsonch.2020.104960 Jayaraman Theerthagiri 1 , Jagannathan Madhavan 2 , Seung Jun Lee 1 , Myong Yong Choi 1 , Muthupandian Ashokkumar 3 , Bruno G Pollet 4
Affiliation
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Sonoelectrochemistry is the study of the effects and applications of ultrasonic waves on electrochemical processes. The integration of ultrasound and electrochemistry offers many advantages: fast reaction rates, enhanced surface activation, and increased mass transport at an electrode. Significant progress has been made in advancing basic and applied aspects of sonoelectrochemical techniques, which are herein reviewed by addressing the development and applications of sonoelectrochemical processes in energy and environmental areas. This review examines the experimental procedures that are used in various sonoelectrochemical techniques generally used for the synthesis of energy related materials (e.g., fuel cell electrocatalysts and materials for hydrogen production) and for the degradation of various organic compounds/pollutants. The challenges that remain for the sonoelectrochemical production of energy materials, the degradation of organic pollutants, and their associated reaction pathway mechanism(s) are also discussed. This review also highlights the significant improvements made to date. The provided information in this review may be helpful to scientists working in the research areas of environmental remediation, energy exploitation and exploration, as well as synthetic process-oriented research.
中文翻译:
用于能源和环境应用的声电化学。
声电化学是超声波对电化学过程的影响和应用的研究。超声和电化学的集成提供了许多优势:快速的反应速度,增强的表面活化和增加的电极质量传输。在推进声电化学技术的基本和应用方面已经取得了重大进展,本文通过解决声电化学方法在能源和环境领域的发展和应用来对其进行综述。这篇综述检查了在各种声电化学技术中使用的实验程序,这些技术通常用于合成与能源相关的材料(例如,燃料电池电催化剂和用于制氢的材料)以及各种有机化合物/污染物的降解。还讨论了能量材料的声电化学生产,有机污染物的降解及其相关的反应途径机理所面临的挑战。这篇评论还强调了迄今为止取得的重大改进。本文中提供的信息可能对从事环境修复,能源开发和勘探以及以合成过程为导向的研究领域的科学家有所帮助。
更新日期:2020-01-21
中文翻译:
用于能源和环境应用的声电化学。
声电化学是超声波对电化学过程的影响和应用的研究。超声和电化学的集成提供了许多优势:快速的反应速度,增强的表面活化和增加的电极质量传输。在推进声电化学技术的基本和应用方面已经取得了重大进展,本文通过解决声电化学方法在能源和环境领域的发展和应用来对其进行综述。这篇综述检查了在各种声电化学技术中使用的实验程序,这些技术通常用于合成与能源相关的材料(例如,燃料电池电催化剂和用于制氢的材料)以及各种有机化合物/污染物的降解。还讨论了能量材料的声电化学生产,有机污染物的降解及其相关的反应途径机理所面临的挑战。这篇评论还强调了迄今为止取得的重大改进。本文中提供的信息可能对从事环境修复,能源开发和勘探以及以合成过程为导向的研究领域的科学家有所帮助。
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