has been cited by the following article(s):
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[1]
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Comparing a covalently linked BODIPY–pyrene system versus the corresponding physical mixture as chromophores in luminescent solar concentrators
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Sustainable Energy & …,
2024 |
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[2]
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Quantum dots-based solar cells: futuristic green technology to accomplish the energy crisis
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Quantum Dots,
2023 |
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[3]
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A review on quantum dot sensitized solar cells: Past, present and future towards carrier multiplication with a possibility for higher efficiency
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2020 |
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[4]
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Biosynthesis of cadmium selenide quantum dots by Providencia vermicola
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2019 |
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[5]
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Advantages of Polymer Electrolytes Towards Dye‐sensitized Solar Cells
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2018 |
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[6]
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An organic-inorganic hybrid photoelectrochemical storage cell for improved solar energy storage
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Electrochimica Acta,
2017 |
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[7]
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Macroporous Fluorine Doped Tin Oxide Photoelectrodes for Solar Water Splitting
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2016 |
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[8]
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Ordered transparent conductive oxides (TCOs) for applications to photoelectrochemistry
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2016 |
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[9]
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Molten salt assisted self-assembly (MASA): synthesis, characterization and solar cell performances of mesoporous silica-CdSe and titania-CdSe thin films
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2015 |
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[10]
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Synthesis of CuInS2 nanocrystals and Quantum dots apply to Solar Cell
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Master's Thesis,
2014 |
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[11]
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Entwicklung von neuartigen Photokatalysatoren zur Wasserspaltung
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Dissertationen,
2013 |
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[12]
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Quantum dot-sensitized solar cells—perspective and recent developments: A review of Cd chalcogenide quantum dots as sensitizers
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Renewable and Sustainable Energy Reviews,
2013 |
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[13]
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1, 4-Hydroquinone is a Hydrogen Reservoir for Fuel Cells and Recyclable via Photocatalytic Water Splitting
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Open Journal of Physical Chemistry,
2013 |
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[14]
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Solar Water Splitting by Semiconductor Nanocomposites and Hydrogen Storage with Quinoid Systems
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Open Journal of Physical Chemistry,
2012 |
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[1]
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Comparing a covalently linked BODIPY–pyrene system versus the corresponding physical mixture as chromophores in luminescent solar concentrators
Sustainable Energy & Fuels,
2024
DOI:10.1039/D4SE00329B
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[2]
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Biosynthesis of cadmium selenide quantum dots by Providencia vermicola
African Journal of Microbiology Research,
2019
DOI:10.5897/AJMR2018.9010
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[3]
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Rational Design of Solar Cells for Efficient Solar Energy Conversion
2018
DOI:10.1002/9781119437499.ch5
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[4]
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An organic-inorganic hybrid photoelectrochemical storage cell for improved solar energy storage
Electrochimica Acta,
2017
DOI:10.1016/j.electacta.2017.11.087
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[5]
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1,4-Hydroquinone is a Hydrogen Reservoir for Fuel Cells and Recyclable via Photocatalytic Water Splitting
Open Journal of Physical Chemistry,
2013
DOI:10.4236/ojpc.2013.32012
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[6]
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Quantum dot-sensitized solar cells—perspective and recent developments: A review of Cd chalcogenide quantum dots as sensitizers
Renewable and Sustainable Energy Reviews,
2013
DOI:10.1016/j.rser.2013.01.030
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[7]
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Solar Water Splitting by Semiconductor Nanocomposites and Hydrogen Storage with Quinoid Systems
Open Journal of Physical Chemistry,
2012
DOI:10.4236/ojpc.2012.24027
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