Three Dimensional Solar Cells Based on Optical Confinement Geometries (eBook)

Three dimensional (3D) optical geometries are becoming more common in the literature and lexicon of solar cells. Three Dimensional Solar Cells Based on Optical Confinement Geometries describes and reveals the basic operational nuances of 3D photovoltaics using three standard tools: Equivalent Circuit Models, Ray Tracing Optics in the Cavity, and Absorber Spectral Response. These tools aide in understanding experimental absorption profile and device parameters including Jsc, Voc, Fill Factor, and EQE. These methods also apply to individual optical confinement geometry device, integrated optical confinement geometry device, and hybrid optical confinement geometry device.
Additionally, this book discusses the importance of these methods in achieving the goal of high efficiency solar cells and suggests a possible application in large-scale photovoltaics business, like solar farms.

Yuan Li received his Ph.D in Physics at the Center for Nanotechnology and Molecular Materials at Wake Forest University under supervisor David Carroll. Yuan has been published in approximately 25 journals, has conducted 6 conference talks and presentations, and holds 4 patents that include an electroluminescence device based on pentacene for electron injection layer, a quartz boat with lid for thermal evaporation, a device for white light based on complex emission, and an apparatus for cleaning substrates. His Honors include the Chinese Government Award for Outstanding Self-Financed Students Abroad (2011), BOE Scholarship awarded by BOE Technology Group Co., and National Graduate Mathematical Contest in Modeling. 
Yuan Li, Wake Forest University, Winston-Salem, North Carolina, USA

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Three dimensional (3D) optical geometries are becoming more common in the literature and lexicon of solar cells. Three Dimensional Solar Cells Based on Optical Confinement Geometries describes and reveals the basic operational nuances of 3D photovoltaics using three standard tools: Equivalent Circuit Models, Ray Tracing Optics in the Cavity, and Absorber Spectral Response. These tools aide in understanding experimental absorption profile and device parameters including Jsc, Voc, Fill Factor, and EQE. These methods also apply to individual optical confinement geometry device, integrated optical confinement geometry device, and hybrid optical confinement geometry device. Additionally, this book discusses the importance of these methods in achieving the goal of high efficiency solar cells and suggests a possible application in large-scale photovoltaics business, like solar farms.