000 02329cam a2200349 a 4500
003 EG-GiCUC
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008 180530s2017 ua dh f m 000 0 eng d
040 _aEG-GiCUC
_beng
_cEG-GiCUC
041 0 _aeng
049 _aDeposite
097 _aM.Sc
099 _aCai01.13.10.M.Sc.2017.Ma.E
100 0 _aMarina Medhat Rassmi Melek
245 1 0 _aEnhancing plasmonic photovoltaic using embedded metal nanoparticles /
_cMarina Medhat Rassmi Melek ; Supervised Alaa K. Abdelmageed , Ezzeldin A. Soliman , Yasser M. Elbatawy
246 1 5 _aتحسين الخلايا الضوئيه البلازمونيه عن طريق دمجها بجسيمات معدنيه نانومتريه
260 _aCairo :
_bMarina Medhat Rassmi Melek ,
_c2017
300 _a72 P. :
_bcharts , facsimiles ;
_c30cm
502 _aThesis (M.Sc.) - Cairo University - Faculty of Engineering - Department of Mathematics and Physics
520 _aPlasmonic Photovoltaic is apromising way to enhance the thin {uFB01}lm photovoltaic(PV) e{uFB03}ciency. Gear shape nanoparticles are introduced to enhance the PV e{uFB03}ciency 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 de{uFB01}ned that consider all objectives. An optimization process is carried out and the optimum gear{u2019}s 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
530 _aIssued also as CD
653 4 _aMetal Nanoparticles
653 4 _aPhotovoltaic
653 4 _aPlasmonic
700 0 _aAlaa K. Abdelmageed ,
_eSupervisor
700 0 _aEzzeldin A. Soliman ,
_eSupervisor
700 0 _aYasser M. Elbatawy ,
_eSupervisor
856 _uhttp://172.23.153.220/th.pdf
905 _aNazla
_eRevisor
905 _aShimaa
_eCataloger
942 _2ddc
_cTH
999 _c66381
_d66381