2020
DOI: 10.4236/oalib.1106178
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Electrochemical Engineering in the Core of the Dye-Sensitized Solar Cells (DSSCs)

Abstract: Dye-sensitized solar cells (DSSCs) are classed in the category of thin-film solar cells, which have been under thorough investigation during the last thirty years thanks to their low price, easy fabrication procedure, low toxicity and ease of generation. Even now, there are great efforts to substitute the present DSSC materials because of their elevated price, less abundance, and long-term stability. The performance of present DSSCs attains 12%, employing Ru(II) dyes via regulating material and structural feat… Show more

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Cited by 7 publications
(7 citation statements)
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“…In recent years, DSSCs have emerged as potential competitors to Si-based SCs due to their easy and solution-based fabrication process and their cost efficiency. The history of DSSCs began in 1960 when it was discovered that illuminated organic dyes could be used as an electrochemical system to generate electricity. , In 1972, scientists successfully developed the chlorophyll-sensitized zinc oxide (ZnO) electrode for electricity generation by injecting excited dye molecules into a semiconducting material. , DSSCs have recently emerged as a promising technology due to their potential for achieving high PCE combined with low production costs and a straightforward fabrication process . Additionally, DSSCs are compatible with flexible and wearable substrates, making them highly versatile in various applications.…”
Section: Photovoltaic Energy Harvesting: Solar Cellmentioning
confidence: 99%
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“…In recent years, DSSCs have emerged as potential competitors to Si-based SCs due to their easy and solution-based fabrication process and their cost efficiency. The history of DSSCs began in 1960 when it was discovered that illuminated organic dyes could be used as an electrochemical system to generate electricity. , In 1972, scientists successfully developed the chlorophyll-sensitized zinc oxide (ZnO) electrode for electricity generation by injecting excited dye molecules into a semiconducting material. , DSSCs have recently emerged as a promising technology due to their potential for achieving high PCE combined with low production costs and a straightforward fabrication process . Additionally, DSSCs are compatible with flexible and wearable substrates, making them highly versatile in various applications.…”
Section: Photovoltaic Energy Harvesting: Solar Cellmentioning
confidence: 99%
“…The history of DSSCs began in 1960 when it was discovered that illuminated organic dyes could be used as an electrochemical system to generate electricity. 166 , 167 In 1972, scientists successfully developed the chlorophyll-sensitized zinc oxide (ZnO) electrode for electricity generation by injecting excited dye molecules into a semiconducting material. 166 , 168 DSSCs have recently emerged as a promising technology due to their potential for achieving high PCE combined with low production costs and a straightforward fabrication process.…”
Section: Photovoltaic Energy Harvesting: Solar Cellmentioning
confidence: 99%
“…Instead, sensitized wide band gap semiconductors derived from metal oxides such as TiO 2 , ZnO, niobium oxide, carbon materials, bilayer-assembled, and their composites have been used as a major photoelectrode in DSSCs, as shown in Figure 4 [38,39]. So, the next section discussed the basic structure of DSSCs, which is composed of different layers as compared to conventional solar cells based on silicon, such as photoanode/photoelectrode/working electrode (WE), counterelectrode (CE), electrolyte, and sensitizer (both synthetic/complex and natural dyes) [35,38,40,41].…”
Section: Basic Elements Of Dsscsmentioning
confidence: 99%
“…These ameliorations imply that process periods and so energy consumption could be greatly decreased for a given operation [139][140][141]. In addition, alternative energy sources (e.g., microwave and light energy [17]) that can be selected to wanted process chemistries, may conduct to less energy waste than is frequently faced with traditional thermal energy sources Ghernaout, et al [142]; Ghernaout, et al [143]; Ghernaout and Elboughdiri [144].…”
Section: Applying Process Intensification (Pi) For Environmentmentioning
confidence: 99%