Kompozit Formda Monodispers Gözenekli Mikrokürelerin Sentezi Ve Boya Duyarlı Güneş Hücrelerinde Kullanımı
Date
2018-09Author
Gökçeli, Sercan
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In this thesis, the conversion efficiency of dye sensitized solar cells were investigated. A
multi-stage hydrolysis-condensation method was developed for synthesizing metal oxides and
their composites in the form of monodisperse-porous microspheres. Afterwards, these
microspheres were integrated into dye sensitized solar cells one by one as an electron transfer
medium for comparing the energy conversion efficiency.
Monodispers, porous silicon dioxide (SiO2), titanium dioxide (TiO2) and cerium dioxide
(CeO2) microspheres and their composites in the form of titanium dioxide doped silicon
dioxide (TiO2@SiO2), cerium dioxide doped silicon dioxide (CeO2@SiO2), and cerium
dioxide doped titanium dioxide (CeO2@TiO2) microspheres were prepared with different
doping ratios. Synthesized microparticles were applied on a glass electrode working as an
anode. By this way, a layer of semiconductor was formed on the glass substrate as an electron
transfer region. Furthermore, synthesized TiO2 and CeO2 microspheres were seperately added onto TiO2 nanospheres and also used in solar cells as semiconductor layer. Ruthenium based
N-719 dye and iodide/triiodide (I-
3 / I-) redox couple were used as the electron source for
current generation and electrolite respectively, in the dye sensitized solar cell.
According to the results of performance measurements of dye sensitized solar cells, energy
conversion efficiencies were measured as 1.06, 0.025, 0.023 and 0.043 for TiO2 , CeO2,
single and double doped TiO2@SiO2 microspheres, respectively. The energy conversion
efficiencies of 0.015, 0.064 and 0.031 were obtained with CeO2@SiO2 microspheres for lower
to higher amount of doping. The values of the same parameter were also determined as 0.017,
0.2 and 0.01 for CeO2@TiO2 microspheres prepared with dopings with lower to higher
amount.
In addition, as a second set, TiO2 and CeO2 microspheres were seperately added onto TiO2
nanospheres with different weight ratios and the mixtures were applied to dye sensitized solar
cells as semiconductor layers and their energy conversion efficiencies were compared. The
energy conversion efficiencies were determined as 0.044, 0.019, 0.150, 0.610 and 0,60 with
the mixtures containing (w/w) %1, %5, %10, %20 and %50 percent of TiO2 microspheres
respectively. On the other hand, the energy conversion efficiencies were determined as 0.130,
0.10, 0.017, 0.005 and 0.037 with the mixtures containing (w/w) %1, %5, %10, %20 and %50
percent of CeO2 microspheres respectively.
5 μm sized-porous CeO2 and TiO2 and SiO2 composites prepared with different doping ratios
were first used in dye sensitized solar cells as semi-conducting layer. Besides, the use of
powder mixtures containing both TiO2/CeO2 microspheres and TiO2 nanospheres was the
another contribution of this study into the literature, in dye sensitized solar cells.