The document discusses improving light trapping in perovskite solar cells by developing a nano-structured transparent contact. The goal is to enhance the quantum efficiency, short-circuit current, and open-circuit voltage of perovskite solar cells to increase overall efficiency. A methodology is proposed that involves simulating flat and nano-cone structured perovskite solar cells and modifying the nano-cone structure parameters to optimize light trapping. Simulation results show reduced power losses and reflections with the nano-cone structures compared to flat structures, demonstrating enhanced light trapping. Future work could involve developing lead-free perovskites and texturing multiple layers.
Improving Perovskite Solar Cell Efficiency via Nano-Structured Transparent Contact
1. “Improvement of Light-Trapping in Perovskite
Solar Cell by Developing Nano-Structured
Transparent Contact.”
1
Final Defense
on
2. Group #61
Under the supervision of
Mohammad Ismail Hossain
Assistant professor, Faculty of Engineering
American International University - Bangladesh 2
Names ID
Islam, Rakibul 13-23758-1
Palash, Fazlul Karim 13-23775-1
Shamsuddin, MD. 13-23833-1
Sarker, Chinmoy 13-23797-1
3. Contents
Introduction
Goals and Potential Benefits
Methodology for Achieving Goal
Theoretical Background
Optical Model
Simulation Results
Conclusion and Future Development
References
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4. Introduction
Photovoltaics is the direct conversion of light into electricity.
Some materials exhibit a property known as the photoelectric effect that causes
to absorb photons of light and release electrons.
These free electrons are captured, an electric current results that can be used as
electricity
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6. Goals and Potential Benefits
Goals Potential Benefits
• The main goal of this thesis is to
enhance the light trapping limit of
Perovskite solar cell by developing its
nano structure transparent contact.
• In addition, we will try to enhance the
quantum efficiency (QE), short-circuit
current (Isc), and open circuit-voltage
(Voc) of the Perovskite solar cell that
contributes to calculate the overall cell
efficiency.
• Low manufacturing cost (cost is 1/3 to
1/5 of the silicon based solar cell),
high energy conversion efficiency,
high thermal stability, utilizes the
advantage of the wide band gap semi-
conductor can operate in harsh
environment.
• Higher photon absorption power in
shorter wavelength and very lower in
longer wave length.
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7. Methodology for Achieving Goal
Flat structure perovskite
solar cell
Nano-cone (nano-wire)
textured perovskite solar cell
(opening angle 128 degree
and texture height 60 nm)
Simulation and results
Modified nano-cone (nano-
wire) textured perovskite
solar cell (opening angle 40
degree and texture height 340
nm)
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8. Theoretical Background
Perovskite Solar Cells:
A perovskite solar cell (PSC) is a type of solar cell which includes
a perovskite structured compound, most commonly a hybrid organic-
inorganic lead or tin halide-based material, as the light-harvesting active layer.
For more than 7 years it has been under extensive research. It specially
attractive for Building Integrated Photovoltaic (BIPV).
PSCs is third generation solar cells which is based on Nano PV technology.
The PSCs are made up of five components:
Conductive mechanical support
Semiconductor film
Perovskites
Redox couple electrolyte and
Counter electrode 8
9. Perovskite Material:
Perovskite is one kind of mineral that
was named after Lev Perovski. He was
the founder of Russian geographical
society. This perovskite mineral first
discovered in the Ural Mountains.
Basic Structure:
Naturally occurring Perovskite
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Theoretical Background
10. Advantages & Limitations of Perovskite
Solar Cell
Advantages:
Low cost
Easy to handle
Flexible
More efficient in absorbing light
Easy to setup
Limitations:
Lead based Perovskite solar cells have
some effect on environment
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11. Optical Model
The TiO2 , MA(CH3NH3PbI3 ), P3 HT layers act as p-i-n layer and these
thicknesses are 40 nm, 360 nm, 10 nm. The Ag metal works as back reflector
and its thickness is 200 nm.
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12. Optical Model
The average power loss profiles of the cell ,
Q(X,Y,Z) =
1
2
𝑐𝜖0 𝑛𝛼 𝐸(𝑋, 𝑌, 𝑍) 2
The short circuit current ,
𝐼𝑆𝐶 =
𝑞
ℎ𝑐 𝜆 𝑚𝑖𝑛
𝜆 𝑚𝑎𝑥
𝜆 𝑄𝐸 𝜆 𝑆 𝜆 𝑑𝜆
The overall quantum efficiency ,
𝑄𝐸 =
1
𝑃 𝑂𝑝𝑡
𝑄 𝑥, 𝑦, 𝑧 𝑑𝑥 𝑑𝑦 𝑑𝑧
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13. Simulation and Result
Figure 1: Losses Vs wavelength graph of flat
structure at period 500 nm.
Figure 2: Reflection Vs wavelength graph of flat
structure at period 500 nm.
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14. Simulation and Result
(a) (b) (c)
Figure 3: Power loss profile in flat structure at
wavelength (a) 380 nm, (b) 550 nm and (c) 700
nm of 500 nm period
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15. Simulation and Result
Figure 4: Losses Vs wavelength graph of nano
cone structure at period 500 nm
Figure 5: Reflection Vs wavelength graph of
nano cone structure at period 500 nm.
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16. Simulation and Result
(a) (b) (c)
Figure 6: Power loss in nano cone structure
at wavelength (a) 380 nm, (b) 550 nm and
(c) 700 nm of 500 nm period 16
17. Simulation and Result
Figure 7: Losses Vs wavelength graph of nano
cone structure at period 500 nm and the
conduction angle and texture height are respect to
400 and 340 nm.
Figure 8: Reflection Vs wavelength graph of nano
cone structure at period 500 nm and the
conduction angle and texture height are respect to
400 and 340 nm. 17
18. Simulation and Result
(a) (b) (c)
Figure 9: Power loss profile in nano cone
structure at wavelength (a) 380 nm, (b) 550 nm
and (c) 700 nm of 500 nm period at opening
angle 400 and texture height 340 nm.
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19. Simulation and Result
Figure 10: Quantum efficiencies comparison
graph at period 500 nm of flat structure, nano
cone structure and modified nano cone
structure. 19
20. Conclusion and Future Development
Conclusion:
In our thesis we developed the light trapping in perovskite solar cell by
texturing FTCO.
Future Development:
Lead free Perovskite solar cell
Textured structure will be developed in different layers
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21. References
1. Susannah Lee,“Harvesting Solar Energy Using Inexpensive and Benign Materials,” Susannah Lee,2012. [Online].
Available:http://link.springer.com/referenceworkentry/10.1007/978-1-4419-7991-9_32. Accessed: Nov. 24, 2016.
2. Kojima, et al. “T. Organometal halide perovskites as visible-light sensitizers for photovoltaic cells,” J. Am. Chem.
Soc. 131, 6050–6051 (2009).
3. Kojima, et al. (May 6, 2009), “Organometal Halide Perovskites as Visible-Light Sensitizers for Photovoltaic
Cells,” Journal of the American Chemical Society. 131 (17): 60506051.
4. “Posts - EPFL Perovskite solar cell 21% efficiency entry in NREL efficiency chart,” 2015. [Online]. Available:
http://www.dyesol.com/posts/cat/corporatenews/post/EPFL_Perovskite_solar_cell_21_percent_efficiency_entry_in_N
REL_efficiency_chart/?___SID=U. Accessed: Nov. 24, 2016.
5. Ossila, “Perovskites and Perovskite solar cells: An introduction,” Ossila, 2015. [Online]. Available:
https://www.ossila.com/pages/perovskites-and-perovskite-solar-cells-an-introduction.Accessed: Nov. 24, 2016.
6. R.Dewan, , I. Vasilev And D. Knipp, “Optics in thin-film silicon solar cells with periodic surface texture,” 12th
Euregional Workshop on Novel Concepts for Future Thin-Film Silicon Solar Cells (Tu Delft, The Netherlands, 2010).
7. Burschka, et al. (July 10, 2013), “Sequential deposition as a route to high-performance perovskite-sensitized solar
cells,” Nature. 499 (7458): 316–319.
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