Show/Hide Menu
Hide/Show Apps
Logout
Türkçe
Türkçe
Search
Search
Login
Login
OpenMETU
OpenMETU
About
About
Open Science Policy
Open Science Policy
Open Access Guideline
Open Access Guideline
Postgraduate Thesis Guideline
Postgraduate Thesis Guideline
Communities & Collections
Communities & Collections
Help
Help
Frequently Asked Questions
Frequently Asked Questions
Guides
Guides
Thesis submission
Thesis submission
MS without thesis term project submission
MS without thesis term project submission
Publication submission with DOI
Publication submission with DOI
Publication submission
Publication submission
Supporting Information
Supporting Information
General Information
General Information
Copyright, Embargo and License
Copyright, Embargo and License
Contact us
Contact us
Angle-independent diffractive optical elements for efficient solar energy conversion
Date
2020-01-01
Author
Yolalmaz, Alim
Yüce, Emre
Metadata
Show full item record
This work is licensed under a
Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License
.
Item Usage Stats
247
views
0
downloads
Cite This
© 2020 SPIE.Conversion of solar energy into electricity is crucial to meet our ever-growing energy needs. The broadband spectrum of the sunlight limits the conversion efficiency of the single- and multi-junction based solar cells. Moreover, the angle of incident radiation dramatically decreases the amount of converted energy. In fact, diffractive optical elements (DOE) designed for spectrally splitting solar light are optimized for normal incidence, and their performance drastically decreases under angled-illumination. Unfortunately, once the number of design parameters two of whose are the number of wavelengths and number of incident angles increases, computational expense for DOEs design rises. Here, we design DOEs which concentrate and split the broadband radiation under angled-illumination. In our design, we take thin, transparent and cost-effective materials into account, and we manage to disperse broadband radiation 400 nm - 1100 nm into two separate bands which are the visible band 400 nm - 700 nm and the short-IR band 701 nm - 1100 nm. Here we optimize the DOEs for angled-illumination using computationally cost-effective approaches. We observe that spectral splitting of the broadband light is less sensitive to variation of incident angle of solar radiation once DOE optimization performed for the area which is half of the output plane. As a result, 8% and 18% excess solar energy conversion can be achieved within the visible band and the short-IR band, respectively. What's interesting is that less than 0.6% deviation in output intensity can be observed when a single DOE is illuminated at angle spans from 0 to 80 degrees.
Subject Keywords
Diffractive optical elements
,
Diffraction
,
Optical design
,
Solar energy
URI
https://hdl.handle.net/11511/57140
DOI
https://doi.org/10.1117/12.2554878
Collections
Department of Physics, Conference / Seminar
Suggestions
OpenMETU
Core
Enhancing Performance of Solar Cells via Wavefront Shaping
Atila, Sena; Yüce, Emre; Department of Micro and Nanotechnology (2022-8-25)
Solar energy has a great potential to provide for our energy demand. However, due to the broadband nature of the Sun, solar cells encounter efficiency losses. For singlejunction GaAs solar cells, the efficiency is measured as 27.6% at most [1]. Previously, the broadband light is experimentally split and concentrated to chosen positions on the CCD camera as three sub-bands to utilize the full spectrum of the Sun, and a particular type of diffractive optical element (SpliCon) is obtained [2]. In this thesis,...
Designs of diffractive optical elements for solar energy harvesting
Yolalmaz, Alim; Yüce, Emre (2019-08-01)
© 2019 IEEE.Solar energy has been chosen as 'the source of energy' given its effectiveness and promises that push researchers forward for developing enhanced solar panels. Diffractive optical elements promise efficient spatial and spectral control of the sunlight that can fulfill the need for increased conversion efficiency. Here, we present designs of diffractive optical elements that can spectrally split broadband sunlight as well as serving as a solar concentrator. We show that a single wavelength can be...
Surface texturing study with aluminum induced texturing method on soda-lime glass substrates for thin film solar cells
Ünal, Mustafa; Turan, Raşit; Ünalan, Hüsnü Emrah; Department of Micro and Nanotechnology (2017)
It is essential to employ an effective light trapping scheme to decrease the cost of produced solar electricity further in thin film solar cell technologies. There are several methods that can be used for light trapping and aluminum induced texturing (AIT) is one of them. The aim of this thesis study is to obtain highly effective light trapping interface via texturing of glass surface by AIT process. The resultant texture is affected by several parameters such as Al thickness, annealing time and temperature...
Analytical Modelling, Simulation and Comparative Study of Multi-Junction Solar Cells Efficiency
Hadjdida, Abdelkader; Bourahla, Mohamed; Ertan, Hulusi Bülent; Bekhti, Mohamed (2018-12-01)
Currently, solar energy is promising the primary source of renewable energy that has a great potential to generate power for an extremely low operating cost when compared to already existing power generation technologies. Increasing the efficiency of solar cells is a major goal and the prominent factor in photovoltaic system research. Current triple junction solar cells reach 30% and the next generation will bring 35% in 5 years to peak at 40%. These cells are used in space environment and in terrestrial sy...
Light trapping micro and nanostructures fabricated by top down approaches for solar cell applications
Altınoluk, Hayriye Serra; Turan, Raşit; Akın, Tayfun; Department of Micro and Nanotechnology (2016)
For an ultimate victory of solar energy over polluting fossil fuels, we need to decrease the cost of electricity generated from the sun. The technology based on photovoltaic (PV) solar cell is offering the most promising alternative in this energy conversion. However, this can be possible only if we can reduce the cost of solar cell fabrication and/or increase the conversion efficiency. In order to increase the performance/cost ratio of solar cells, new approaches reducing optical and electrical losses are ...
Citation Formats
IEEE
ACM
APA
CHICAGO
MLA
BibTeX
A. Yolalmaz and E. Yüce, “Angle-independent diffractive optical elements for efficient solar energy conversion,” 2020, vol. 11366, Accessed: 00, 2020. [Online]. Available: https://hdl.handle.net/11511/57140.