Based on Graphene Electrodes PbSe / CdSe Core-Shell Quantum Dots Battery

Peng Wang; Tong Yu Wang; He Lin Wang; Tie Qiang Zhang

doi:10.4028/www.scientific.net/AMM.737.88

Paper Titles

Research on the Correlation between Biodiesel's Composition and Physical & Chemical Properties
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Theory of Solar Hot Water System Construction Application Engineering Evaluation Field Test Method - The Amount of Solar Irradiance Intercept Method
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Wind Power Prediction Model Based on Wavelet Neural Network under Missing Data
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A Analysis on the Importance of Lithium Battery Cooling for Pure Electric Vehicles
p.83

Based on Graphene Electrodes PbSe / CdSe Core-Shell Quantum Dots Battery
p.88

Hydrothermal Upgrading of Bitumen with Glucose as Hydrogen Donor
p.92

Optimization of Catholyte in Hydrogen Redox Fuel Cell
p.97

Potential Energy Curves and Spectroscopic Properties of C^-₂ Studied by Configuration Interaction Method
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Reduced Thermal Conductivity in ZrNiSn-Based Heusler Alloys
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 737Based on Graphene Electrodes PbSe / CdSe...

Based on Graphene Electrodes PbSe / CdSe Core-Shell Quantum Dots Battery

Abstract:

what the cheaper and easier to get is graphene to replace high cost, limited sources of material and high temperature difference between the ITO (indium tin oxide) electrode material as a quantum dot solar cells is the focus of this study. This study used a chemical vapor deposition (CVD) production of graphene electrode explore the relationship between the transmittance and the graphene sheet resistance graphene layers; then make a graphene material as an electrode of the solar cell devices of different size and detecting its performance, the conclusion that the material is graphene electrode PbSe / CdSe quantum dot battery, which can effectively improve the conversion rate of the quantum dot solar cells (up to 3.6%), and stability, but also can greatly reduce the cost;

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Periodical:

Applied Mechanics and Materials (Volume 737)

Pages:

88-91

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.737.88

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Online since:

March 2015

Authors:

Peng Wang*, Tong Yu Wang, He Lin Wang, Tie Qiang Zhang

Keywords:

Chemical Vapor Deposition (CVD), Graphene

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* - Corresponding Author

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