首页> 外文会议>Nonimaging Optics and Efficient Illumination Systems II >Examination of Optimum Carrier Materials and Quantum Dots for a Quantum Dot Solar Concentrator using spectroscopic techniques

【24h】

Examination of Optimum Carrier Materials and Quantum Dots for a Quantum Dot Solar Concentrator using spectroscopic techniques

机译：使用光谱技术检查量子点太阳能聚光器的最佳载体材料和量子点

获取原文

获取原文并翻译 | 示例

页面导航

摘要
著录项
相似文献
相关主题

摘要

Spectroscopic measurements have been undertaken for a range of different quantum dot (QD) types and transparent host materials for use in a novel solar energy-concentrating device, a Quantum Dot Solar Concentrator (QDSC). A QDSC comprises QDs seeded in materials such as plastics and glasses that are suitable for incorporation into buildings where photovoltaic cells attached to the edges convert direct and diffuse solar energy into electricity for use in the building. High transparency in the matrix material and QDs with a large Stokes shift are essential for an efficient QDSC. An optimum matrix material for a QDSC has been determined based on absorption characteristics and an optimum commercially available QD type has been chosen using steady-state absorption, photoluminescence and photoluminescence excitation spectroscopy of QDs in solution and solid matrices.

机译：已经针对一系列不同的量子点（QD）类型和透明主体材料进行了光谱测量，这些材料用于一种新型的太阳能集中装置，即量子点太阳能集中器（QDSC）。 QDSC包含植入在塑料和玻璃等材料中的QD，这些QD适于掺入建筑物中，在建筑物中，附着在边缘的光伏电池将直接和扩散的太阳能转换成电能以供建筑物使用。基质材料和高斯托克斯位移QD的高透明度对于有效的QDSC至关重要。已基于吸收特性确定了用于QDSC的最佳基质材料，并使用溶液和固体基质中QD的稳态吸收，光致发光和光致发光激发光谱法选择了最佳的商用QD类型。

著录项

来源
《Nonimaging Optics and Efficient Illumination Systems II 》|2005年|P.59420V.1-59420V.8|共8页
会议地点 San DiegoCA(US)
作者
S.J. Gallagher; B.C. Rowan; J. Doran; B. Norton;
展开▼
作者单位

Focas Institute School of Physics Dublin Institute of Technology Kevin St Dublin 8 Irel;

展开▼
会议组织
原文格式 PDF
正文语种 eng
中图分类电气照明 ;
关键词
solar energy; photovoltaic; solar concentrator; quantum dot; photoluminescence;

机译：太阳能;光伏;太阳能聚光器;量子点;光致发光;

相似文献

外文文献
中文文献
专利

1. Quantum dot solar concentrator: Device optimisation using spectroscopic techniques [J] . S.J. Gallagher, B.C. Rowan, J. Doran, Solar Energy . 2007 ,第4期

机译：量子点太阳能集中器：使用光谱技术进行设备优化
2. Photoexcited carrier dynamics in colloidal quantum dot solar cells: insights into individual quantum dots, quantum dot solid films and devices [J] . Zhang Yaohong, Wu Guohua, Liu Feng, Chemical Society Reviews . 2020 ,第1期

机译：胶体量子点太阳能电池中的运动型载体动态：洞察单个量子点，量子点固体薄膜和装置
3. Improving the optical efficiency and concentration of a single-plate quantum dot solar concentrator using near infra-red emitting quantum dots [J] . M. Kennedy, S.J. McCormack, J. Doran, Solar Energy . 2009 ,第7期

机译：使用近红外发射量子点提高单板量子点太阳能集中器的光学效率和集中度
4. Examination of Optimum Carrier Materials and Quantum Dots for a Quantum Dot Solar Concentrator using spectroscopic techniques [C] . S.J. Gallagher, B.C. Rowan, J. Doran, Conference on Nonimaging Optics and Efficient Illumination Systems . 2005

机译：使用光谱技术检查量子点太阳能聚光器的最佳载体材料和量子点
5. (Indium,gallium)arsenide quantum dot materials for solar cell applications: Effect of strain-reducing and strain-compensated barriers on quantum dot structural and optical properties [D] . Pancholi, Anup 2008

机译：用于太阳能电池的（铟，镓）砷化物量子点材料：应变降低和应变补偿势垒对量子点结构和光学性质的影响
6. Influence of Quantum Dot Concentration on Carrier Transport in ZnO:TiO2 Nano-Hybrid Photoanodes for Quantum Dot-Sensitized Solar Cells [O] . Francis S. Maloney, Uma Poudyal, Weimin Chen, 2016

机译：量子点浓度对量子点敏感型太阳能电池用ZnO：TiO2纳米复合光阳极中载流子传输的影响
7. Influence of Quantum Dot Concentration on Carrier Transport in ZnO:TiO2 Nano-Hybrid Photoanodes for Quantum Dot-Sensitized Solar Cells [O] . Francis S. Maloney, Uma Poudyal, Weimin Chen, 2016

机译：量子点浓度对ZnO：TiO2纳米杂化光阳极对量子点敏化太阳能电池载流子迁移的影响

Examination of Optimum Carrier Materials and Quantum Dots for a Quantum Dot Solar Concentrator using spectroscopic techniques

摘要

著录项

相似文献

相关主题

期刊订阅