A dye – sensitized solar cell module with enhanced charge collection efficiency

Intense research in the field of dye-sensitized solar cells (DSCs) brought them to a level of delivering ~13% efficiency (η) using mesoporous TiO2 particles, inorganic dyes, and redox electrolyte. High η and IPCEs are so far reported in devices of rather smaller area (≤ 0.2 cm2), a size that put lim...

Full description

Saved in:
Bibliographic Details
Main Author: Azhar, Fakharuddin
Format: Thesis
Language:English
Published: 2015
Subjects:
Online Access:http://umpir.ump.edu.my/id/eprint/10989/1/A%20dye%20%E2%80%93%20sensitized%20solar%20cell%20module%20with%20enhanced%20charge%20collection%20efficiency.pdf
Tags: Add Tag
No Tags, Be the first to tag this record!
id my-ump-ir.10989
record_format uketd_dc
spelling my-ump-ir.109892023-01-26T02:52:04Z A dye – sensitized solar cell module with enhanced charge collection efficiency 2015-02 Azhar, Fakharuddin TK Electrical engineering. Electronics Nuclear engineering Intense research in the field of dye-sensitized solar cells (DSCs) brought them to a level of delivering ~13% efficiency (η) using mesoporous TiO2 particles, inorganic dyes, and redox electrolyte. High η and IPCEs are so far reported in devices of rather smaller area (≤ 0.2 cm2), a size that put limitations on the scalability of the device. On the other hand, large area modules (DSMs) are developed by up scaling the DSCs to give either added voltages (series connection), such as S –type, W–type and Z–type, or currents (parallel connection) with appreciable output voltage (~8 V) and current (~2 – 3 A), respectively, in separate devices of active areas in the 20 – 1000 cm2 range. The highest achieved in DSMs is ~ 8.2%, ~36% smaller than their laboratory scale devices. We note that such designs are invariably built in the form of interconnected TiO2 strips (≥ 3 cm2) and the photocurrent density (JSC) in these designs is merely 30 – 50 % then that of single cells. We have investigated the effects of DSC photoelectrode area upon its  and identified that, within the limits of our study, threshold area is the key in achieving the JSC and clearly not the expanded photoelectrode area as adopted conventionally in a DSM fabrication. Upon increasing the photoelectrode area, the  decreased biexponentially, the main contributor to which was the JSC. The upshots of the electrochemical studies revealed that the electrons from an area above a threshold are never collected due to a competition between electron lifetime (τn) and transit time (τd). We suggest that if larger electrodes are fabricated, then electrons from smaller spatial domains contribute to the short circuit current density. The diffusion length (Ln) in DSCs, which is defined as the distance travelled by electrons before recombining with the hole species in electrolyte, L= (Dnn)1/2, where Dn is the electron diffusivity, considered only film thickness so far. Our findings reveal that area of the electrode is also to be considered when the L is defined. Based on the insights, we fabricated alternative designs to build DSMs with increased charge collection (c). In our specially designed experiments, we altered the photoelectrode design by splitting the electrode into multiple fractions to restrict the electron diffusion pathways. We observed a correlation between the device physical dimensions and its charge collection efficiency via current-voltage and impedance spectroscopy measurements. Our electrode designs showed >50 % increased JSC due to shorter τd, higher recombination resistance and 20 – 50% higher c compared to the conventional ones despite their similar active volume (~3.36 × 10-4 cm3). If high efficiency DSCs is targeted using commercial TiO2 paste on account of its high specific surface area, results from our studies would be helpful in designing new device structures to build high efficiency DSMs 2015-02 Thesis http://umpir.ump.edu.my/id/eprint/10989/ http://umpir.ump.edu.my/id/eprint/10989/1/A%20dye%20%E2%80%93%20sensitized%20solar%20cell%20module%20with%20enhanced%20charge%20collection%20efficiency.pdf pdf en public phd doctoral Universiti Malaysia Pahang Faculty Of Industrial Science and Technology
institution Universiti Malaysia Pahang Al-Sultan Abdullah
collection UMPSA Institutional Repository
language English
topic TK Electrical engineering
Electronics Nuclear engineering
spellingShingle TK Electrical engineering
Electronics Nuclear engineering
Azhar, Fakharuddin
A dye – sensitized solar cell module with enhanced charge collection efficiency
description Intense research in the field of dye-sensitized solar cells (DSCs) brought them to a level of delivering ~13% efficiency (η) using mesoporous TiO2 particles, inorganic dyes, and redox electrolyte. High η and IPCEs are so far reported in devices of rather smaller area (≤ 0.2 cm2), a size that put limitations on the scalability of the device. On the other hand, large area modules (DSMs) are developed by up scaling the DSCs to give either added voltages (series connection), such as S –type, W–type and Z–type, or currents (parallel connection) with appreciable output voltage (~8 V) and current (~2 – 3 A), respectively, in separate devices of active areas in the 20 – 1000 cm2 range. The highest achieved in DSMs is ~ 8.2%, ~36% smaller than their laboratory scale devices. We note that such designs are invariably built in the form of interconnected TiO2 strips (≥ 3 cm2) and the photocurrent density (JSC) in these designs is merely 30 – 50 % then that of single cells. We have investigated the effects of DSC photoelectrode area upon its  and identified that, within the limits of our study, threshold area is the key in achieving the JSC and clearly not the expanded photoelectrode area as adopted conventionally in a DSM fabrication. Upon increasing the photoelectrode area, the  decreased biexponentially, the main contributor to which was the JSC. The upshots of the electrochemical studies revealed that the electrons from an area above a threshold are never collected due to a competition between electron lifetime (τn) and transit time (τd). We suggest that if larger electrodes are fabricated, then electrons from smaller spatial domains contribute to the short circuit current density. The diffusion length (Ln) in DSCs, which is defined as the distance travelled by electrons before recombining with the hole species in electrolyte, L= (Dnn)1/2, where Dn is the electron diffusivity, considered only film thickness so far. Our findings reveal that area of the electrode is also to be considered when the L is defined. Based on the insights, we fabricated alternative designs to build DSMs with increased charge collection (c). In our specially designed experiments, we altered the photoelectrode design by splitting the electrode into multiple fractions to restrict the electron diffusion pathways. We observed a correlation between the device physical dimensions and its charge collection efficiency via current-voltage and impedance spectroscopy measurements. Our electrode designs showed >50 % increased JSC due to shorter τd, higher recombination resistance and 20 – 50% higher c compared to the conventional ones despite their similar active volume (~3.36 × 10-4 cm3). If high efficiency DSCs is targeted using commercial TiO2 paste on account of its high specific surface area, results from our studies would be helpful in designing new device structures to build high efficiency DSMs
format Thesis
qualification_name Doctor of Philosophy (PhD.)
qualification_level Doctorate
author Azhar, Fakharuddin
author_facet Azhar, Fakharuddin
author_sort Azhar, Fakharuddin
title A dye – sensitized solar cell module with enhanced charge collection efficiency
title_short A dye – sensitized solar cell module with enhanced charge collection efficiency
title_full A dye – sensitized solar cell module with enhanced charge collection efficiency
title_fullStr A dye – sensitized solar cell module with enhanced charge collection efficiency
title_full_unstemmed A dye – sensitized solar cell module with enhanced charge collection efficiency
title_sort dye – sensitized solar cell module with enhanced charge collection efficiency
granting_institution Universiti Malaysia Pahang
granting_department Faculty Of Industrial Science and Technology
publishDate 2015
url http://umpir.ump.edu.my/id/eprint/10989/1/A%20dye%20%E2%80%93%20sensitized%20solar%20cell%20module%20with%20enhanced%20charge%20collection%20efficiency.pdf
_version_ 1783731937135820800