Advanced Research Trends in Dye-sensitized Solar Cells

Overview

Journal J Mater Chem A Mater

Date 2021 May 17

PMID 33996094

Citations 39

Authors

Mikko Kokkonen

Parisa Talebi

Jin Zhou

Somayyeh Asgari

Sohail Ahmed Soomro

Farid Elsehrawy

Janne Halme

Shahzada Ahmad

Anders Hagfeldt

Syed Ghufran Hashmi

Affiliations

Soon will be listed here.

Abstract

Dye-sensitized solar cells (DSSCs) are an efficient photovoltaic technology for powering electronic applications such as wireless sensors with indoor light. Their low cost and abundant materials, as well as their capability to be manufactured as thin and light-weight flexible solar modules highlight their potential for economic indoor photovoltaics. However, their fabrication methods must be scaled to industrial manufacturing with high photovoltaic efficiency and performance stability under typical indoor conditions. This paper reviews the recent progress in DSSC research towards this goal through the development of new device structures, alternative redox shuttles, solid-state hole conductors, TiO photoelectrodes, catalyst materials, and sealing techniques. We discuss how each functional component of a DSSC has been improved with these new materials and fabrication techniques. In addition, we propose a scalable cell fabrication process that integrates these developments to a new monolithic cell design based on several features including inkjet and screen printing of the dye, a solid state hole conductor, PEDOT contact, compact TiO, mesoporous TiO, carbon nanotubes counter electrode, epoxy encapsulation layers and silver conductors. Finally, we discuss the need to design new stability testing protocols to assess the probable deployment of DSSCs in portable electronics and internet-of-things devices.

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