Manifestations of carbon capture-storage and ambivalence of quantum-dot & organic solar cells: An indispensable abridged review

International Journal of Solar Thermal Vacuum Engineering Pub Date : 2020-10-10 DOI:10.37934/stve.2.1.4058

S. Memon, G. Nemera, T. I. Nwokeji

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引用次数: 4

Abstract

This study bestows an essential abridged review of the manifestations of carbon capture & storage (CCS) systems and the ambivalence of quantum-dot & organic photovoltaic (PV) solar cells. This research implicates that CCS system is evolving in capturing emissions from coal-fired electrical power stations to further mitigate climate change. Different manifestations are discussed for capturing and storing the with repercussions on operating costs, toxicity and energy efficiency. Chemical Looping Combustion appears to be the more energy efficient than Oxy-fuel CFBC and Ionic Liquids, and less expensive than Calcium Looping and Amine Scrubbing. Calcium Looping (Cal) and Ionic Liquids are also less toxic than Amine Scrubbing. Direct air technology is also very compelling at capturing emissions but highly expensive. Nevertheless, further research is still required for all CCS systems to be able to implement them widely in existing/new electrical power stations. Waste heat energy recovery systems can be used in conjunction with capture systems for further reduction of emissions. The ambivalence of quantum dot and organic solar cells are briefly reviewed. It implicates that composite film with enhanced quantum dot effects will make the film highly transparent and options of tunability of its color spectrum make the quantum dot solar cells highly attractive to a wide variety of applications. Organic solar cells are carbon-rich polymers and can be designed to improve a precise function of the cell, such as sensitivity to a certain type of light. OPV cells can only be considered as half-competent to crystalline silicon and have smaller beneficial lifespans, but could be less costly to produce in high volumes. Current research issues are substitution/compromises between electrical power conversion efficiency and average visible light transmittance. However, improving average light-transmittance decreases electrical power conversion efficiency and vice versa.

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量子点与有机太阳能电池的碳捕获-储存表现与矛盾:不可或缺的综述

本研究对碳捕获与储存(CCS)系统的表现以及量子点与有机光伏(PV)太阳能电池的矛盾心理进行了必要的简要回顾。该研究表明，CCS系统在捕获燃煤电厂排放以进一步减缓气候变化方面正在不断发展。讨论了捕获和储存对运行成本、毒性和能源效率的影响的不同表现。化学循环燃烧似乎比氧燃料CFBC和离子液体更节能，比钙循环和胺洗涤更便宜。钙环(Cal)和离子液体的毒性也比胺洗涤小。直接空气技术在捕获排放物方面也非常有吸引力，但价格非常昂贵。然而，要使所有CCS系统能够在现有/新的发电站中广泛实施，还需要进一步的研究。废热能源回收系统可以与捕获系统结合使用，以进一步减少排放。简要评述了量子点与有机太阳能电池的矛盾。这意味着具有增强量子点效应的复合薄膜将使薄膜具有高透明度，其光谱的可调性使量子点太阳能电池具有广泛的应用前景。有机太阳能电池是富含碳的聚合物，可以设计成提高电池的精确功能，比如对特定类型光的灵敏度。OPV电池只能被认为是晶体硅的一半竞争力，而且有益寿命更短，但大批量生产的成本可能更低。当前的研究问题是电能转换效率与平均可见光透过率之间的替代/折衷。然而，提高平均透光率会降低电能转换效率，反之亦然。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Journal of Solar Thermal Vacuum Engineering

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