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Innovative Energy & Research | ISSN: 2576-1463 | Volume 7

Renewable Energy and Resources

Energy Materials and Fuel Cell Research

2

nd

International Conference on

&

August 27-28, 2018 | Boston, USA

Highly efficient nano composite electrolyte for quasi-solid-state dye-sensitized solar cells under room

light conditions

Shanmuganathan Venkatesan, Chiao-wei Li, I-Ping Liu

and

Yuh-Lang Lee

National Cheng Kung University, Taiwan

Statement of the problem:

Dye-sensitized solar cells (DSSCs) are a promising technology owing to their high-power conversion

efficiencies (PCEs) under room light conditions and low manufacturing cost with respect to conventional silicon solar cells.

Nowadays, the internet of things (IoT) is attracting worldwide technological interest because it delineates associations between

various small devices. However, the problems related to power these devices have become significant. Among the several

power supply systems, indoor DSSCs will be the most promising for a continuous power supply to IoT devices. In the literature,

only a few studies have been reported about the performance of liquid-state DSSCs using iodide electrolytes under room-light

conditions. Since relatively few electrons are excited, the recombination of the excited electrons with electrolytes strongly

affects the open circuit voltage (Voc) of the DSSCs. In addition, because of the notable decrease in excited holes, less iodide

will be required to minimize the holes. These two effects significantly decrease the performance of DSSCs under room light

illumination.

Methodology:

To solve these problems, in this study, new nanocomposite electrolytes (NCEs) were prepared by mixing various

metal oxides nanofillers (NFs) and cobalt poly (vinylidene fluoride-co-hexafluoropropylene) polymer gel electrolytes (PGEs).

These NCEs were utilized to fabricate the quasi-solid-state DSSCs (QS-DSSCs). The performance of QS-DSSCs using MK-2

dye under 200 lux was studied and compared.

Findings:

The PCE (20.11%) of the QS-DSSCs using 4 wt% ZnO NFs was higher than those of the liquid version (18.91%) and

other DSSCs. This was mainly due to the decrease in the capacitance and increase in the recombination resistance of the QS-

DSSCs using ZnO NFs that contributed to the high Voc of the related DSSC. This cell showed stable, long-term PCE at room

temperature (~1000 h).

Conclusion:

The ZnO/PVDF-HFP NCEs were proven to be efficient and stable for preparing high-performance indoor QS-

DSSCs.

Biography

S Venkatesan received his PhD degree (2009) in chemistry from National Chung Hsing University, Taichung, Taiwan. He has expertise in preparation, character-

ization, and utilization of polymer-supported catalysts for efficient and selective organic functional group transformations in the presence of oxygen. He has been

utilized these catalysts for the preparation of various chemically modified electrodes for electrochemical sensor and battery applications. In recent years, he has

been focused on the fabrication of outdoor and indoor dye-sensitized laboratory and sub-module quasi-solid state dye-sensitized solar cells (DSSCs). He has

successfully assembled these cells after his systematic research in iodide and cobalt-based liquid, polymer, polymer gel electrolytes with and without nanofillers

such as nanosized metal oxides, metal carbides, and graphene oxide sponge. In further, he prepared printable electrolytes for DSSCs by altering the viscosity of

the polymer electrolytes. These printable electrolytes are beneficial for the role-role-printing process and mass production of DSSCs.

venkatkandan@yahoo.com

Shanmuganathan Venkatesan et al., Innov Ener Res 2018, Volume 7

DOI: 10.4172/2576-1463-C2-006