Light harvester band gap engineering in excitonic solar cells: A case study on semiconducting quantum dots sensitized rainbow solar cells

Isabella Concina; Gurpreet S. Selopal; Riccardo Milan; Giorgio Sberveglieri; Alberto Vomiero

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Light harvester band gap engineering in excitonic solar cells: A case study on semiconducting quantum dots sensitized rainbow solar cells

机译：激子太阳能电池的光收集器带隙工程：以半导体量子点敏化彩虹太阳能电池为例

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A systematic study on the fabrication of quantum dots sensitized solar cells (QDSSCs) exploiting hybrid networks of semiconducting light harvesters is presented, which shows how the engineering of band gaps of the device components by a very simple technique allows improving the solar energy conversion performances. Panchromatic devices are fabricated and tested, and correspondent functional parameters analyzed in order to highlight both advantages and drawbacks of the most common (CdS, CdSe, PbS) quantum dots applied for light collection in QDSSCs. Judicious engineering of the light harvester layer is demonstrated as a simple and powerful strategy for boosting device performances, through the management of light collection in a rather broad range of solar spectrum and photogenerated charges injection and collection.

机译：提出了利用半导体光收集器的混合网络制造量子点敏化太阳能电池（QDSSC）的系统研究，该研究显示了通过非常简单的技术对器件组件的带隙进行工程设计如何可以改善太阳能转换性能。全色器件经过制造和测试，并分析了相应的功能参数，以突出显示QDSSC中用于光收集的最常见的（CdS，CdSe，PbS）量子点的优缺点。通过管理相当广泛的太阳光谱范围内的光收集以及光生电荷的注入和收集，光收集器层的明智工程设计被证明是提高设备性能的简单而有效的策略。

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来源
《Pure and Applied Chemistry》 |2014年第5期|共10页
作者
Isabella Concina; Gurpreet S. Selopal; Riccardo Milan; Giorgio Sberveglieri; Alberto Vomiero;
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正文语种 eng
中图分类化学;
关键词
electrodes; energy conversion; semiconductors; NMS-IX;

机译：电极;能量转换;半导体;NMS-IX;

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1. Light harvester band gap engineering in excitonic solar cells: A case study on semiconducting quantum dots sensitized rainbow solar cells [J] . Isabella Concina, Gurpreet S. Selopal, Riccardo Milan, Pure and Applied Chemistry . 2014,第5期

机译：激子太阳能电池的光收集器带隙工程：以半导体量子点敏化彩虹太阳能电池为例
2. Combined post-modification of iodide ligands and wide band gap ZnS in quantum dot sensitized solar cells [J] . Guangda Niu, Nan Li, Liduo Wang Physical chemistry chemical physics: PCCP . 2014,第34期

机译：量子点敏化太阳能电池中碘配体和宽带隙ZnS的组合后修饰
3. Band Engineering in Core/Shell ZnTe/CdSe for Photovoltage and Efficiency Enhancement in Exciplex Quantum Dot Sensitized Solar Cells [J] . Jiao Shuang, Shen Qing, Mora-Sero Ivan, ACS nano . 2015,第1期

机译：核/壳ZnTe / CdSe中的能带工程可提高复杂量子点敏化太阳能电池的光电压和效率
4. ENGINEERING THE MICROSTRUCTURE AND CHEMISTRY OF BOTH QUANTUM DOTS AND PHOTOANODES IN QUANTUM-DOT SENSITIZED SOLAR CELLS FOR HIGH POWER CONVERSION EFFICIENCY [C] . Guozhong Cao, Ru Zhou, Lin Yang ACS National Meeting and Exhibition . 2014

机译：Quantum-Dot敏化太阳能电池中量子点和光阳极的微观结构和化学，高功率转换效率
5. Dye- and quantum dot-sensitized solar cells based on nanostructured wide-bandgap semiconductors via an integrated experimental and modeling study. [D] . Xin, Xukai. 2012

机译：通过综合实验和模型研究，基于纳米结构宽带隙半导体的染料和量子点敏化太阳能电池。
6. Improved performance and stability in quantum dot solar cells through band alignment engineering [O] . Chia-Hao M. Chuang, Patrick R. Brown, Vladimir Bulović, -1

机译：通过能带对齐工程提高了量子点太阳能电池的性能和稳定性
7. Light harvester band gap engineeringudin excitonic solar cells: A case study on semiconducting quantum dots sensitized rainbow solar cells [O] . Concina I., Selopal G. S., Milan R., 2014

机译：光收集器带隙工程 ud在激子太阳能电池中的应用：以半导体量子点敏化彩虹太阳能电池为例

Light harvester band gap engineering in excitonic solar cells: A case study on semiconducting quantum dots sensitized rainbow solar cells

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