Oct 27 2022米拉·佩雷拉(Mila Perera)审查
一种称为GraphDiyne(GDY)的合成碳结晶材料已从绘图板发展到目前的地位,作为推动下一个电池技术飞跃的潜在关键因素,这是因为锂在1990年代初期没有铅超过铅和重金属以来就没有看到。
Zicheng Zuo教授是中国科学院的GraphDiyne原始团队的成员,化学研究所,已发表了一份有关GDY开发的评论论文及其用作储能和转换的接口组成部分。欧洲杯线上买球
Due to the inherent characteristics of GDY, some new phenomena and properties have been discovered in a wide range of research fields。GDY has made substantial breakthroughs in fundamental and applied science, formed innovative scientific concepts and made great achievements。
Zicheng Zuo,中国科学院教授兼成员兼成员欧洲杯线上买球
The study was reported in theNano Research Energy日记10月25日th,2022。
Among the achievements of GDYs, the authors concentrated mainly on the 2-D crystal’s potential as it pertains to energy conversion and storage.
In the global fight to decrease carbon emissions, the scientific community has been driven to determine methods of achieving the maximum results from renewable energy sources.
Zuo explained that improved energy storage is a primary part of this. Considerable enhancements in mass energy storage will help optimize the efficient yield of wind and solar. The hourly output of each differs considerably based on weather and time of day.
GraphDiyne是一种无限扩展的结晶晶格,可以容纳充电,几乎没有电阻,从而使其成为下一代高科技电池的理想电池阳极,可以使大规模的可再生能源储备可行,并且可以使用电动汽车,并且可以使用电动汽车,并且可以使用很多更广泛的市场。
Research strongly indicates that the graphdiyne interface has strong potential for mass-market applications of high-energy density batteries and water splitting, which are important fields for creating a sustainable society。We firmly believe that these materials will bring transformative progress for energy storage and conversion in five to ten years。
Zicheng Zuo,中国科学院教授兼成员兼成员欧洲杯线上买球
Zuo的团队分析了GraphDiyne的潜力,即几个电池组成部分之间的接口。其中包括镁,钾,钠和锂,所有这些都被广泛研究以用于未来的储能。
在各种实验中使用不同的储能使用的发现表明,GraphDiyne似乎是高效的电力导体。这使电流能够沿着最小电阻的路径通过。
Also, graphdiyne held up as stable over time, making it a suitable subject of study for real-world energy storage applications in the future.
Stability and controllability are two unprecedented advantages of a graphdiyne interface, and it has the potential to revolutionize the interfacial stability and functions in real scenarios。
Zicheng Zuo,中国科学院教授兼成员兼成员欧洲杯线上买球
由于GraphDiyne被称为在准确控制的实验室环境中生长的结晶晶格,因此必须发现更快的生产方式,以使其对于公共基础设施规模和商业工业应用程序可行。赵表示,他和他的合作者将继续研究GraphDiyne的储能潜力。
赵说:“In the future, we will scale up the research and build large-scale prototype devices to show the advantages of the graphdiyne interface in advancing the energy density and lifespan of batteries。”
期刊参考
Gao, X.,等。(2022) Advanced electrochemical energy storage and conversion on graphdiyne interface.Nano Research Energy。doi.org/10.26599/nre.2022.9120036。
资源:http://www.tup.tsinghua.edu.cn/en/index.html