发布时间:2011-04-14
题 目:Integrated Nanophotonics for Next Generation Renewable Energy Applications
报告人:Prof. Yasha Yi(City University of New York and New York University)
时 间:4月18日(周一),上午10:00
地 点:物理馆512会议室
Abstract:
Integrated nanophotonics is an emerging field that can be utilized to mold the flow of light on a single chip. Recently, nanophotonics has found very interesting applications in telecommunications, next generation photovoltaics, biophotonics and medical imaging. After giving an introduction on the available renewable energy sources on earth, I will talk about next generation solar cells utilizing photonic crystals, and our recent research on optoelectronic properties of composite (structurally designed) materials at nm scale for the applications on energy related materials and devices. Utilizing current nanoelectronics technology, it is possible to study these novel energy related materials and devices in ways that were unimaginable a decade or two ago. In order to improve next generation thin film solar cell efficiency(2nd generation solar cell), we have developed a comprehensive light-trapping scheme that can tremendously enhance optical path length and make light almost completely absorbed at AM1.5 solar spectrum by using novel nano scale photonic materials structure. At the front side, the graded index structure is utilized to make the incident light to have minimum reflection and at the bottom side, textured photonic crystal makes incident light strongly bent and reflected almost parallel to the surface of the absorption layer, hence the optical path length can be enhanced more than two orders of magnitude longer than that obtained by conventional light trapping schemes. Furthermore, it provides extremely high reflectivity with large omnidirectional bandgap over several hundred nanometers in the solar spectrum range. As a result, the overall efficiency of the solar cell based on our photonic structure is improved significantly. Lastly, I will talk about many potential challenges and future work to be pursued in clean energy fields that require good control of photons and electrons at nanometer scale. This capability can efficiently convert sunlight energy to electricity and meet our demand for clean and renewable energy in the future.