Enhancing plasmonic photovoltaic using embedded metal nanoparticles /
Marina Medhat Rassmi Melek
Enhancing plasmonic photovoltaic using embedded metal nanoparticles / تحسين الخلايا الضوئيه البلازمونيه عن طريق دمجها بجسيمات معدنيه نانومتريه Marina Medhat Rassmi Melek ; Supervised Alaa K. Abdelmageed , Ezzeldin A. Soliman , Yasser M. Elbatawy - Cairo : Marina Medhat Rassmi Melek , 2017 - 72 P. : charts , facsimiles ; 30cm
Thesis (M.Sc.) - Cairo University - Faculty of Engineering - Department of Mathematics and Physics
Plasmonic Photovoltaic is apromising way to enhance the thin lm photovoltaic(PV) eciency. Gear shape nanoparticles are introduced to enhance the PV eciency via increasing the power absorbed by the PV semiconductor in the visible and near infrared ranges. The modes of the gear nanoparticles are investigated. A parametric study is performed that demonstrates how the design parameters of the proposed nanoparticles can be engineered for best power absorption within Si. A Figure of Merit (FoM) is dened that consider all objectives. An optimization process is carried out and the optimum gears dimensions, penetration depth, and periodicity are obtained for the maximum FoM. Then, a model for PIN-PV with embedded gear nanoparticles is presented for 1D and 2D structures. The enhancement of the embedded gear nanoparticles on the J-V characteristics of the PV is studied, and J-V characteristics corresponding to maximum FoM is presented
Metal Nanoparticles Photovoltaic Plasmonic
Enhancing plasmonic photovoltaic using embedded metal nanoparticles / تحسين الخلايا الضوئيه البلازمونيه عن طريق دمجها بجسيمات معدنيه نانومتريه Marina Medhat Rassmi Melek ; Supervised Alaa K. Abdelmageed , Ezzeldin A. Soliman , Yasser M. Elbatawy - Cairo : Marina Medhat Rassmi Melek , 2017 - 72 P. : charts , facsimiles ; 30cm
Thesis (M.Sc.) - Cairo University - Faculty of Engineering - Department of Mathematics and Physics
Plasmonic Photovoltaic is apromising way to enhance the thin lm photovoltaic(PV) eciency. Gear shape nanoparticles are introduced to enhance the PV eciency via increasing the power absorbed by the PV semiconductor in the visible and near infrared ranges. The modes of the gear nanoparticles are investigated. A parametric study is performed that demonstrates how the design parameters of the proposed nanoparticles can be engineered for best power absorption within Si. A Figure of Merit (FoM) is dened that consider all objectives. An optimization process is carried out and the optimum gears dimensions, penetration depth, and periodicity are obtained for the maximum FoM. Then, a model for PIN-PV with embedded gear nanoparticles is presented for 1D and 2D structures. The enhancement of the embedded gear nanoparticles on the J-V characteristics of the PV is studied, and J-V characteristics corresponding to maximum FoM is presented
Metal Nanoparticles Photovoltaic Plasmonic