Introduction to light trapping in solar cell and photodetector devices pdf
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- Nanophotonics silicon solar cells: status and future challenges
- Introduction to Light Trapping in Solar Cell and Photo-detector Devices
- Unified Electromagnetic-Electronic Design of Light Trapping Silicon Solar Cells
- Nanostructures for Light Trapping in Thin Film Solar Cells
Plasmonics can be used to improve absorption in optoelectronic devices and has been intensively studied for solar cells and photodetectors.
Light management plays an important role in high-performance solar cells. Nanostructures that could effectively trap light offer great potential in improving the conversion efficiency of solar cells with much reduced material usage. Developing low-cost and large-scale nanostructures integratable with solar cells, thus, promises new solutions for high efficiency and low-cost solar energy harvesting.
Nanophotonics silicon solar cells: status and future challenges
Thin film solar cells are one of the important candidates utilized to reduce the cost of photovoltaic production by minimizing the usage of active materials. Increasing the absorption of light that can be converted into electrical current in thin film solar cells is crucial for enhancing the overall efficiency and in reducing the cost. Therefore, light trapping strategies play a significant role in achieving this goal. The main objectives of light trapping techniques are to decrease incident light reflection, increase the light absorption, and modify the optical response of the device for use in different applications. Nanostructures utilize key sets of approaches to achieve these objectives, including gradual refractive index matching, and coupling incident light into guided modes and localized plasmon resonances, as well as surface plasmon polariton modes. In this review, we discuss some of the recent developments in the design and implementation of nanostructures for light trapping in solar cells.
This site contains links to the solar cell papers published by Prof. Alam's group. The papers have been organized in a way that makes self-study of these papers easier. A set of resources are available at the bottom of the page. For any questions or comments, please send a note to alam purdue. Computer Programs, Formula Sheet, and Quizzes. Computer Programs.
Dielectric metamaterials with high refractive indices may have an incredible capability to manipulate the phase, amplitude, and polarization of the incident light. Combining the high refractive index and the excellent electrical characteristics of the hybrid organic-inorganic perovskites HOIPs , for the first time we experimentally demonstrate that metamaterial made of HOIPs can trap visible light and realize effective photon-to-electron conversion. The optical absorption is significantly enhanced at the visible regime compared to that of the flat HOIP film, which originates from the excited Mie resonances and transverse cavity modes with inhibited interface reflection. Our data point to the potential application of HOIP metamaterials for high-efficiency light trapping and photon-to-electron conversion. Mie resonances in dielectric metamaterials yield strong electric and magnetic resonances and allow substantial control over the light scattering amplitude and phase [ 1 ], [ 2 ], [ 3 ]. Similar to that in the metallic building blocks in plasmonic metamaterials [ 4 ], [ 5 ], [ 6 ], [ 7 ], the scattering properties of the dielectric resonators can be manipulated by varying the size, geometry, orientation, and material parameters of the resonators [ 8 ].
Introduction to Light Trapping in Solar Cell and Photo-detector Devices
Metrics details. Light manipulation has drawn great attention in photodetectors towards the specific applications with broadband or spectra-selective enhancement in photo-responsivity or conversion efficiency. In this work, a broadband light regulation was realized in photodetectors with the improved spectra-selective photo-responsivity by the optimally fabricated dielectric microcavity arrays MCAs on the top of devices. Both experimental and theoretical results reveal that the light absorption enhancement in the cavities is responsible for the improved sensitivity in the detectors, which originated from the light confinement of the whispering-gallery-mode WGM resonances and the subsequent photon coupling into active layer through the leaky modes of resonances. In addition, the absorption enhancements in specific wavelength regions were controllably accomplished by manipulating the resonance properties through varying the effective optical length of the cavities. This work well demonstrated that the leaky modes of WGM resonant dielectric cavity arrays can effectively improve the light trapping and thus responsivity in broadband or selective spectra for photodetection and will enable future exploration of their applications in other photoelectric conversion devices. Photodetectors PDs are in great demand for enhancing responsivity, which is practically important to its commercial applications, such as optical communication, sensing, and imaging in our daily life.
Unified Electromagnetic-Electronic Design of Light Trapping Silicon Solar Cells
A solar cell , or photovoltaic cell , is an electrical device that converts the energy of light directly into electricity by the photovoltaic effect , which is a physical and chemical phenomenon. Individual solar cell devices are often the electrical building blocks of photovoltaic modules , known colloquially as solar panels. The common single junction silicon solar cell can produce a maximum open-circuit voltage of approximately 0. Solar cells are described as being photovoltaic , irrespective of whether the source is sunlight or an artificial light. In addition to producing energy, they can be used as a photodetector for example infrared detectors , detecting light or other electromagnetic radiation near the visible range, or measuring light intensity.
Nanostructures for Light Trapping in Thin Film Solar Cells
New Approaches to Light Trapping in Solar Cell Devices discusses in detail the use of photonic and plasmonic effects for light trapping in solar cells. It compares and contrasts texturing, the current method of light-trapping design in solar cells, with emerging approaches employing photonic and plasmonic phenomena. These new light trapping methods reduce the amount of absorber required in a solar cell, promising significant cost reduction and efficiency. This book highlights potential advantages of photonics and plasmonics and describes design optimization using computer modeling of these approaches. Its discussion of ultimate efficiency possibilities in solar cells is grounded in a review of the Shockley-Queisser analysis; this includes an in-depth examination of recent analyses building on that seminal work.
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