Multi-Scale Particle-Based Simulation of Disordered/Ordered Interfaces for High Efficiency Solar Cells

高效太阳能电池无序/有序界面的多尺度粒子模拟

• 批准号: 0933838
• 负责人: Christiana Honsberg
• 金额: $ 31.6万
• 依托单位: Arizona State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-01 至 2012-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0933838&HistoricalAwards=false
• 关键词: Multi; Scale; Particle; Based; Simulation

This award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5).0933838HonsbergThe cost of solar cells must be reduced by a factor of two in order to achieve grid parity. There are a number of new technologies which can achieve this goal, including advanced silicon, thin film (CdTe or CIGS), organic solar cells, or, in the longer term, nanostructured photovoltaics. A commonality among these systems is the predominance of transport mechanisms across disordered/ordered interfaces that control the device performance. Existing modeling programs and approaches do not model such effects, requiring a particle-based approach such as Monte-Carlo modeling, which can accommodate hopping transport, recombination, and opto-electronic processes. In addition, the calculations are complicated by the long time scales required for photovoltaic applications, making a multiscale approach essential. The goal of this project is to develop a novel modeling approach to simulating and understanding materials and interfaces where ?hopping? transport controls the transport and recombination, and then experimentally verify and demonstrate the ability to match and predict behavior of novel solar cells. The research will optimize two specific experimental systems (a-Si/Si and organic/Si) and demonstrate the ability to achieve both transport and low recombination across such interfaces. Future goals are to use the tool for other solar cell approaches and materials.The proposal has several scientific novelties as its intellectual merits. One scientific advance is the development of a multi-scale particle-based, Monte Carlo approach suitable for modeling disordered/ordered material interfaces. The improved understanding of these interfaces will be used to develop a match between simulated and experimental minority carrier lifetime curves of a-S/Si and organic/Si interfaces, and then develop optimized solar cells based on these interfaces. In addition to new models, the final scientific advances are to identify approaches to controlling the interface and demonstration of improved solar cells using this understanding, and allowing development of novel solar cell structures. The project has substantial broader impacts. First, it addresses a limiting issue for a range of novel solar cell approaches, from existing commercial devices to novel nanostructured, organic or dye-sensitized devices, allowing new, higher efficiency and lower cost photovoltaic approaches. In addition, it will provide unique educational opportunities beyond the research training afforded to the graduate student involved with the project. The collaboration of different groups will be formalized through a class on photovoltaics, which combines the viewpoints and expertise of the different groups. The collaboration will result in a ?simplified? Monte Carlo simulator that allows visualization of the transport in such complex structures. It will be added to the existing photovoltaic educational website developed by the PIs, which attracts about 1,000 visits a day.

该奖项是根据2009年美国复苏和再投资法案（公法111-5）资助的。0933838 Honsberg太阳能电池的成本必须降低两倍，以实现电网平价。有许多新技术可以实现这一目标，包括先进的硅、薄膜（CdTe或CIGS）、有机太阳能电池，或者从长远来看，纳米结构的光致发光材料。这些系统之间的共性是控制器件性能的无序/有序界面之间的传输机制占主导地位。现有的建模程序和方法不对这样的效应建模，需要基于粒子的方法，例如蒙特-卡罗建模，其可以适应跳跃传输、复合和光电过程。此外，光伏应用所需的长时间尺度使计算变得复杂，这使得多尺度方法至关重要。这个项目的目标是开发一种新的建模方法来模拟和理解材料和界面在哪里？跳跃？输运控制输运和复合，然后通过实验验证和证明匹配和预测新型太阳能电池行为的能力。该研究将优化两个特定的实验系统（a-Si/Si和有机/Si），并展示在这些界面上实现传输和低复合的能力。未来的目标是将该工具用于其他太阳能电池方法和材料。一个科学进步是发展了一种基于多尺度粒子的蒙特卡罗方法，适用于对无序/有序材料界面进行建模。对这些界面的进一步理解将用于开发a-S/Si和有机/Si界面的模拟和实验少数载流子寿命曲线之间的匹配，然后开发基于这些界面的优化太阳能电池。除了新的模型，最终的科学进展是确定控制界面的方法，并使用这种理解来演示改进的太阳能电池，并允许开发新的太阳能电池结构。该项目具有广泛的影响。首先，它解决了一系列新型太阳能电池方法的限制性问题，从现有的商业设备到新型纳米结构的有机或染料敏化设备，允许新的，更高效率和更低成本的光伏方法。此外，它还将提供独特的教育机会，超越为参与该项目的研究生提供的研究培训。不同团体的合作将通过一个结合不同团体的观点和专门知识的摄影学课程正式化。合作将导致一个？简化？蒙特卡罗模拟器，允许可视化的运输在这样复杂的结构。该网站将加入到现有的光伏教育网站中，该网站由PI开发，每天吸引约1，000次访问。