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Journal articles on the topic 'Silicon solar cells'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 August 2024

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1

Vlaskin, V. I. "Nanocrystalline silicon carbide films for solar cells." Semiconductor Physics Quantum Electronics and Optoelectronics 19, no. 3 (September 30, 2016): 273–78. http://dx.doi.org/10.15407/spqeo19.03.273.

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2

Wagner, P. "Silicon solar cells." Microelectronics Journal 19, no. 4 (July 1988): 37–50. http://dx.doi.org/10.1016/s0026-2692(88)80043-0.

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3

Wenham, S. R., and M. A. Green. "Silicon solar cells." Progress in Photovoltaics: Research and Applications 4, no. 1 (January 1996): 3–33. http://dx.doi.org/10.1002/(sici)1099-159x(199601/02)4:1<3::aid-pip117>3.0.co;2-s.

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4

Korkishko, R. M. "Analysis of features of recombination mechanisms in silicon solar cells." Semiconductor Physics Quantum Electronics and Optoelectronics 17, no. 1 (March 31, 2014): 14–20. http://dx.doi.org/10.15407/spqeo17.01.014.

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5

Tsakalakos, L., J. Balch, J. Fronheiser, B. A. Korevaar, O. Sulima, and J. Rand. "Silicon nanowire solar cells." Applied Physics Letters 91, no. 23 (December 3, 2007): 233117. http://dx.doi.org/10.1063/1.2821113.

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6

Hill, R. "Amorphous Silicon Solar Cells." Electronics and Power 32, no. 9 (1986): 680. http://dx.doi.org/10.1049/ep.1986.0402.

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7

Galloni, Roberto. "Amorphous silicon solar cells." Renewable Energy 8, no. 1-4 (May 1996): 400–404. http://dx.doi.org/10.1016/0960-1481(96)88886-0.

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8

Blakers, A. W., and T. Armour. "Flexible silicon solar cells." Solar Energy Materials and Solar Cells 93, no. 8 (August 2009): 1440–43. http://dx.doi.org/10.1016/j.solmat.2009.03.016.

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9

Won, Rachel. "Graphene–silicon solar cells." Nature Photonics 4, no. 7 (July 2010): 411. http://dx.doi.org/10.1038/nphoton.2010.140.

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10

Carlson, D. E. "Amorphous-silicon solar cells." IEEE Transactions on Electron Devices 36, no. 12 (1989): 2775–80. http://dx.doi.org/10.1109/16.40936.

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11

Van Overstraeten, Roger. "Crystalline silicon solar cells." Renewable Energy 5, no. 1-4 (August 1994): 103–6. http://dx.doi.org/10.1016/0960-1481(94)90359-x.

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12

Rath, J. K. "Nanocystalline silicon solar cells." Applied Physics A 96, no. 1 (December 23, 2008): 145–52. http://dx.doi.org/10.1007/s00339-008-5017-x.

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13

Fuhs, W. "Amorphous silicon solar cells." Solar & Wind Technology 4, no. 1 (January 1987): 7–15. http://dx.doi.org/10.1016/0741-983x(87)90003-8.

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14

Carlson, D. E. "Amorphous silicon solar cells." Solar Cells 20, no. 1 (February 1987): 75–76. http://dx.doi.org/10.1016/0379-6787(87)90023-8.

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15

Nie, Yuxuan, and Xintong Yu. "Structure affects perovskite/silicon solar cells." Highlights in Science, Engineering and Technology 13 (August 21, 2022): 68–74. http://dx.doi.org/10.54097/hset.v13i.1333.

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Contemporarily, the power conversion efficiency of monolithic perovskite/silicon series solar cells has been significantly improved. Starting with the structure of solar cells, this paper discusses the reasons for the power growth of perovskite/silicon series solar cells. Subsequently, the main advantages of perovskite/silicon series solar cells are summarized. Afterwards, the bottlenecks and limitations encountered in the current state-of-art scenarios of solar cells are evaluated detailly, and future prospects for the further exploration are demonstrated. By comparing perovskite/silicon cells with different structures and designs, the idea is proposed of breaking through higher power, and through the discussion of bottlenecks. The direction of progress of perovskite/silicon solar cells for a long time in the future is clarified accordingly. These results shed light on development of the Perovskite / silicon series solar cell.
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16

Wang, Jiaming. "Comparison of development prospects between silicon solar cells and perovskite solar cells." Highlights in Science, Engineering and Technology 27 (December 27, 2022): 512–18. http://dx.doi.org/10.54097/hset.v27i.3808.

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The development history, preparation process, structure and working principle of silicon solar cells and perovskite solar cells are introduced. The main parameters and production processes of the two kinds of solar cells are compared. The advantages and disadvantages of perovskite solar energy compared with existing solar cells in market application are analyzed and summarized, including good light absorption, high energy conversion efficiency and simple process flow, The problems of cost, size and stability of perovskite solar cells in market application are pointed out and the solutions are given. Perovskite solar cells have an excellent development prospect. Short circuit voltage, open circuit current and efficiency exceed those of silicon solar cells and are expected to gradually replace silicon solar cells in the market.
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17

Barnett, Allen M., Robert B. Hall, and James A. Rand. "Thin Polycrystalline Silicon Solar Cells." MRS Bulletin 18, no. 10 (October 1993): 33–37. http://dx.doi.org/10.1557/s0883769400038264.

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Solar cells formed with thin silicon active layers (<100 μm thick) offer advantages over thick ingot-based devices. The advantages come in two forms: the first is the potential for higher conversion efficiency than that of conventional thick devices, and the second is a reduction in material requirements. The use of thin polycrystalline silicon for solar cells offers the potential of capturing the high performance of crystalline silicon while achieving the potential low cost of thin films. Experimental and theoretical studies initially uncovered the issues of grain size and thickness as limiting factors. Subsequent work added the issue of back-surface passivation. This article addresses the conditions required for the successful development of polycrystalline silicon into a high efficiency, low-cost, terrestrial product.
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18

Huang, Yuan Ming, Qing Lan Ma, Ming Meng, and Bao Gai Zhai. "Porous Silicon Based Solar Cells." Materials Science Forum 663-665 (November 2010): 836–39. http://dx.doi.org/10.4028/www.scientific.net/msf.663-665.836.

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The primary aim of this communication is to introduce a novel approach of preparation of solar cell, viz. PS based solar cell, which is on the basis of the basic principle of the well established photovoltaic effect. We carefully investigate the current-voltage characteristics of the PS-based solar cell by virtue of performing the measurement of both current and voltage of PS-based solar cell under the condition of the sunlight irradiation and priori to sunlight irradiation in the purpose of observing clearly the photovoltaic effect possessed by the PS based solar cell. Judging by the results obtained in this paper, we can safely draw the conclusion that porous silicon is a good candidate material for the preparation of solar cell, that is to say that our study is giving high hope for the industrial production of high efficient PS-based thin film solar cells.
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19

Xue, Chun Rong, and Xia Yun Sun. "Design for Amorphous Silicon Solar Cells." Advanced Materials Research 750-752 (August 2013): 961–64. http://dx.doi.org/10.4028/www.scientific.net/amr.750-752.961.

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This document explains and demonstrates how to design efficient amorphous silicon solar cells. Some of the fundamental physical concepts required to interpret the scientific literature about amorphous silicon are introduced. The principal methods such as plasma deposition that are used to make amorphous siliconbased solar cells are investigated. On the basis, high-efficiency solar cells based on amorphous silicon technology are designed. Multi-junction amorphous silicon solar cells are discussed, how these are made and how their performance can be understood and optimized. To conclude this document, some of the directions that are important for future progress in the field are presented.
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20

Li, Jian Gong, Peng Wu, Peng Yu, and Shu Ai Li. "Ribbon Silicon Material for Solar Cells." Advanced Materials Research 531 (June 2012): 67–70. http://dx.doi.org/10.4028/www.scientific.net/amr.531.67.

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Solar cell is one of most important renewable energy. But now it is not be widely used because of its high cost compared with traditional resource. Ribbon silicon is one new low cost solar cell material avoiding ingot casting and slicing. It is a promising silicon wafer fabrication technology alternative to traditional ingot casting and slicing. Using ribbon silicon can make solar cell production cost greatly reduced. In this paper EFG, String Ribbon and a novel silicon wafer are discussed.
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21

Neuhaus, Dirk-Holger, and Adolf Münzer. "Industrial Silicon Wafer Solar Cells." Advances in OptoElectronics 2007 (April 13, 2007): 1–15. http://dx.doi.org/10.1155/2007/24521.

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In 2006, around 86% of all wafer-based silicon solar cells were produced using screen printing to form the silver front and aluminium rear contacts and chemical vapour deposition to grow silicon nitride as the antireflection coating onto the front surface. This paper reviews this dominant solar cell technology looking into state-of-the-art equipment and corresponding processes for each process step. The main efficiency losses of this type of solar cell are analyzed to demonstrate the future efficiency potential of this technology. In research and development, more various advanced solar cell concepts have demonstrated higher efficiencies. The question which arises is “why are new solar cell concepts not transferred into industrial production more frequently?”. We look into the requirements a new solar cell technology has to fulfill to have an advantage over the current approach. Finally, we give an overview of high-efficiency concepts which have already been transferred into industrial production.
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22

Cho, Eun-Chel, Sangwook Park, Xiaojing Hao, Dengyuan Song, Gavin Conibeer, Sang-Cheol Park, and Martin A. Green. "Silicon quantum dot/crystalline silicon solar cells." Nanotechnology 19, no. 24 (May 9, 2008): 245201. http://dx.doi.org/10.1088/0957-4484/19/24/245201.

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23

Zhang, Yunlong, Long Zhou, and Chunfu Zhang. "Research Progress of Semi-Transparent Perovskite and Four-Terminal Perovskite/Silicon Tandem Solar Cells." Energies 17, no. 8 (April 11, 2024): 1833. http://dx.doi.org/10.3390/en17081833.

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Perovskite/silicon tandem solar cells are of great interest due to their potential for breaking the Shockley-Queisser limit of single-junction silicon solar cells. Perovskite solar cells are widely used as the top subcells in perovskite/silicon tandem solar cells due to their high efficiency and lower fabrication cost. Herein, we review the semi-transparent perovskite solar cell in terms of the mechanisms of their translucent structure, transparent electrodes, charge transport layer, and component modification. In addition, recent progress in the research and development of 4T perovskite/silicon tandem solar cells is summarized, with emphasis on the influence of perovskite structure and silicon cells on the progress of tandem solar cells. Finally, we discuss the challenges associated with 4T perovskite/silicon tandem solar cells and suggest directions for the development of perovskite/silicon commercialization.
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24

Um, Han-Don, Kangmin Lee, Inchan Hwang, Jeonghwan Park, Deokjae Choi, Namwoo Kim, Hyungwoo Kim, and Kwanyong Seo. "Progress in silicon microwire solar cells." Journal of Materials Chemistry A 8, no. 11 (2020): 5395–420. http://dx.doi.org/10.1039/c9ta12792e.

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25

Beaucarne, Guy. "Silicon Thin-Film Solar Cells." Advances in OptoElectronics 2007 (December 17, 2007): 1–12. http://dx.doi.org/10.1155/2007/36970.

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We review the field of thin-film silicon solar cells with an active layer thickness of a few micrometers. These technologies can potentially lead to low cost through lower material costs than conventional modules, but do not suffer from some critical drawbacks of other thin-film technologies, such as limited supply of basic materials or toxicity of the components. Amorphous Si technology is the oldest and best established thin-film silicon technology. Amorphous silicon is deposited at low temperature with plasma-enhanced chemical vapor deposition (PECVD). In spite of the fundamental limitation of this material due to its disorder and metastability, the technology is now gaining industrial momentum thanks to the entry of equipment manufacturers with experience with large-area PECVD. Microcrystalline Si (also called nanocrystalline Si) is a material with crystallites in the nanometer range in an amorphous matrix, and which contains less defects than amorphous silicon. Its lower bandgap makes it particularly appropriate as active material for the bottom cell in tandem and triple junction devices. The combination of an amorphous silicon top cell and a microcrystalline bottom cell has yielded promising results, but much work is needed to implement it on large-area and to limit light-induced degradation. Finally thin-film polysilicon solar cells, with grain size in the micrometer range, has recently emerged as an alternative photovoltaic technology. The layers have a grain size ranging from 1 μm to several tens of microns, and are formed at a temperature ranging from 600 to more than 1000∘C. Solid Phase Crystallization has yielded the best results so far but there has recently been fast progress with seed layer approaches, particularly those using the aluminum-induced crystallization technique.
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26

Goswami, Romyani. "Three Generations of Solar Cells." Advanced Materials Research 1165 (July 23, 2021): 113–30. http://dx.doi.org/10.4028/www.scientific.net/amr.1165.113.

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In photovoltaic system the major challenge is the cost reduction of the solar cell module to compete with those of conventional energy sources. Evolution of solar photovoltaic comprises of several generations through the last sixty years. The first generation solar cells were based on single crystal silicon and bulk polycrystalline Si wafers. The single crystal silicon solar cell has high material cost and the fabrication also requires very high energy. The second generation solar cells were based on thin film fabrication technology. Due to low temperature manufacturing process and less material requirement, remarkable cost reduction was achieved in these solar cells. Among all the thin film technologies amorphous silicon thin film solar cell is in most advanced stage of development and is commercially available. However, an inherent problem of light induced degradation in amorphous silicon hinders the higher efficiency in this kind of cell. The third generation silicon solar cells are based on nano-crystalline and nano-porous materials. Hydrogenated nanocrystalline silicon (nc-Si:H) is becoming a promising material as an absorber layer of solar cell due to its high stability with high Voc. It is also suggested that the cause of high stability and less degradation of certain nc-Si:H films may be due to the improvement of medium range order (MRO) of the films. During the last ten years, organic, polymer, dye sensitized and perovskites materials are also attract much attention of the photovoltaic researchers as the low budget next generation PV material worldwide. Although most important challenge for those organic solar cells in practical applications is the stability issue. In this work nc-Si:H films are successfully deposited at a high deposition rate using a high pressure and a high power by Radio Frequency Plasma Enhanced Chemical Vapor Deposition (RF PECVD) technique. The transmission electron microscopy (TEM) studies show the formations of distinct nano-sized grains in the amorphous tissue with sharp crystalline orientations. Light induced degradation of photoconductivity of nc-Si:H materials have been studied. Single junction solar cells and solar module were successfully fabricated using nanocrystalline silicon as absorber layer. The optimum cell is 7.1 % efficient initially. Improvement in efficiency can be achieved by optimizing the doped layer/interface and using Ag back contact.
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27

Yang, Hong, He Wang, and Dingyue Cao. "Investigation of soldering for crystalline silicon solar cells." Soldering & Surface Mount Technology 28, no. 4 (September 5, 2016): 222–26. http://dx.doi.org/10.1108/ssmt-04-2015-0015.

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Purpose Tabbing and stringing are the critical process for crystalline silicon solar module production. Because of the mismatch of the thermal expansion coefficients between silicon and metal, phenomenon of cell bowing, microcracks formation or cell breakage emerge during the soldering process. The purpose of this paper is to investigate the effect of soldering on crystalline silicon solar cells and module, and reveal soldering law so as to decrease the breakage rates and improve reliability for crystalline silicon solar module. Design/methodology/approach A microscopic model of the soldering process is developed by the study of the crystalline silicon solar cell soldering process in this work. And the defects caused by soldering were analyzed systematically. Findings The defects caused by soldering are analyzed systematically. The optimal soldering conditions are derived for the crystalline silicon solar module. Originality/value The quality criterion of soldering for crystalline silicon solar module is built for the first time. The optimal soldering conditions are derived for the crystalline silicon solar module. This study provides insights into solder interconnection reliability in the photovoltaic (PV) industry.
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28

Albrasia, Enteisar, and Fathia Mohhammed Essa Albrasi. "Solar cells and their use." International Journal of Applied Science and Research 05, no. 05 (2022): 27–33. http://dx.doi.org/10.56293/ijasr.2022.5428.

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The sun's light is an unewable, renewable source of energy that is unaffected by environmental factors like noise and pollution. It is easily obtainable from the Earth's petroleum resources, natural gas, and other nonrenewable energy sources like coal. There were several stages of evolution in the composition of solar cells from one generation to the next. The silicon used in the early solar cells was largely produced as single crystals on silicon chips. Furthermore, advances in thin films the dye and organic solar cells improved the cell's efficiency. The inability to choose the best solar cell for a particular place is essentially what prevents advancement
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29

Kim, Sangmo, Van Quy Hoang, and Chung Wung Bark. "Silicon-Based Technologies for Flexible Photovoltaic (PV) Devices: From Basic Mechanism to Manufacturing Technologies." Nanomaterials 11, no. 11 (November 3, 2021): 2944. http://dx.doi.org/10.3390/nano11112944.

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Over the past few decades, silicon-based solar cells have been used in the photovoltaic (PV) industry because of the abundance of silicon material and the mature fabrication process. However, as more electrical devices with wearable and portable functions are required, silicon-based PV solar cells have been developed to create solar cells that are flexible, lightweight, and thin. Unlike flexible PV systems (inorganic and organic), the drawbacks of silicon-based solar cells are that they are difficult to fabricate as flexible solar cells. However, new technologies have emerged for flexible solar cells with silicon. In this paper, we describe the basic energy-conversion mechanism from light and introduce various silicon-based manufacturing technologies for flexible solar cells. In addition, for high energy-conversion efficiency, we deal with various technologies (process, structure, and materials).
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30

Ge, AnXu. "Design and process of perovskite/silicon tandem solar cells." Applied and Computational Engineering 24, no. 1 (November 7, 2023): 134–38. http://dx.doi.org/10.54254/2755-2721/24/20230693.

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At present, the solar cells that occupy most market are still silicon solar cells. However, the power conversion efficiencies (PCEs) of the devices made of silicon have achieved an extreme value. Therefore, a new type of solar cells to get higher power conversion efficiencies are in great need. Since the 21st century, perovskite/silicon tandem solar cells have gained great attention because of their potential to offer higher PCE compared with other traditional solar cells. This article elaborates the inevitability of the development of perovskite/silicon crystal tandem solar cells from the perspectives of development history, cell structure. This article also discusses the different materials of both perovskite top cell layers and silicon crystal bottom cell layers in this new type of solar cell, including methylammonium lead iodide, formamidinium lead iodide, cesium lead iodide, crystalline silicon, thin-film silicon and heterojunction with intrinsic thin layer. This article mainly presents the characteristics and advantages and disadvantages of different materials when they are used in this new type device.
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31

Watanabe, Hiroyuki. "Overview of Cast Multicrystalline Silicon Solar Cells." MRS Bulletin 18, no. 10 (October 1993): 29–32. http://dx.doi.org/10.1557/s0883769400038252.

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Worldwide environmental problems such as the greenhouse effect and acid rain have been caused by the human race's continuous reliance on the combustion of petroleum for fuel.Solar energy, which is clean and practically unlimited, is expected to be a desirable alternate energy source to conventional power supplies, and demand for the photovoltaic system has increased throughout the world, especially in Europe and the United States.Photovoltaic cells are probably the most effective method for capturing solar energy, since they are easy to use and are the most effective means of directly generating electricity.Many kinds of solar cells have been developed in past years, especially since the first oil crisis in 1973. Among them, solar cells from cast multicrystalline silicon (also refereed to as (cast) polycrystalline silicon or semicrystalline silicon) are considered to be one of the most promising types, capable of achieving both high efficiency and low cost.In 1975, Wacker proposed a new manufacturing method for silicon substrates, using the casting method. Since then, many organizations have been involved in the research and development of multicrystalline ingots and solar cells using multicrystalline silicon substrates.Multicrystalline silicon substrates contain many kinds of defects compared to single-crystal silicon substrates, so the efficiency of multicrystalline silicon solar cells has been inferior to that of single-crystal cells. Recent research on multicrystalline silicon solar cells has resulted in substantial improvements and in the demonstration of high-efficiency cells.
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32

JU, Minkyu, Seyoun KIM, Sangho KIM, Youngkuk KIM, Eun-Chel CHO, and Junsin YI. "High Efficiency Silicon Solar Cells." Physics and High Technology 28, no. 5 (May 31, 2019): 2–6. http://dx.doi.org/10.3938/phit.28.016.

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33

Martinelli, G. "Crystalline Silicon for Solar Cells." Solid State Phenomena 32-33 (December 1993): 21–26. http://dx.doi.org/10.4028/www.scientific.net/ssp.32-33.21.

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34

Möller, Hans Joachim. "Multicrystalline Silicon for Solar Cells." Solid State Phenomena 47-48 (July 1995): 127–42. http://dx.doi.org/10.4028/www.scientific.net/ssp.47-48.127.

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35

Kittler, Martin, and Wolfgang Koch. "Crystalline Silicon for Solar Cells." Solid State Phenomena 82-84 (November 2001): 695–700. http://dx.doi.org/10.4028/www.scientific.net/ssp.82-84.695.

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36

Kalejs, Juris P. "Silicon Ribbons for Solar Cells." Solid State Phenomena 95-96 (September 2003): 159–74. http://dx.doi.org/10.4028/www.scientific.net/ssp.95-96.159.

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37

Blakers, A. W., and M. A. Green. "20% efficiency silicon solar cells." Applied Physics Letters 48, no. 3 (January 20, 1986): 215–17. http://dx.doi.org/10.1063/1.96799.

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38

Zheng, Peiting, Fiacre Emile Rougieux, Xinyu Zhang, Julien Degoulange, Roland Einhaus, Pascal Rivat, and Daniel H. Macdonald. "21.1% UMG Silicon Solar Cells." IEEE Journal of Photovoltaics 7, no. 1 (January 2017): 58–61. http://dx.doi.org/10.1109/jphotov.2016.2616192.

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39

Bouazzi, A. S. "High-efficiency silicon solar cells." IEEE Potentials 19, no. 2 (2000): 16–18. http://dx.doi.org/10.1109/45.839640.

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40

Meier, D. L., R. H. Hopkins, and R. B. Campbell. "Dendritic web silicon solar cells." Journal of Propulsion and Power 4, no. 6 (November 1988): 586–90. http://dx.doi.org/10.2514/3.23104.

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41

Stelzner, Th, M. Pietsch, G. Andrä, F. Falk, E. Ose, and S. Christiansen. "Silicon nanowire-based solar cells." Nanotechnology 19, no. 29 (June 10, 2008): 295203. http://dx.doi.org/10.1088/0957-4484/19/29/295203.

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42

SCHWARTZ, R. J., and J. L. GRAY. "High Concentration Silicon Solar Cells." International Journal of Solar Energy 6, no. 6 (January 1988): 331–46. http://dx.doi.org/10.1080/01425918808914238.

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43

Munzer, K. A., K. T. Holdermann, R. E. Schlosser, and S. Sterk. "Thin monocrystalline silicon solar cells." IEEE Transactions on Electron Devices 46, no. 10 (1999): 2055–61. http://dx.doi.org/10.1109/16.791996.

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44

Willeke, G. P. "Thin crystalline silicon solar cells." Solar Energy Materials and Solar Cells 72, no. 1-4 (April 2002): 191–200. http://dx.doi.org/10.1016/s0927-0248(01)00164-7.

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45

Wang, A., J. Zhao, and M. A. Green. "24% efficient silicon solar cells." Applied Physics Letters 57, no. 6 (August 6, 1990): 602–4. http://dx.doi.org/10.1063/1.103610.

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46

Möller, H. J., C. Funke, M. Rinio, and S. Scholz. "Multicrystalline silicon for solar cells." Thin Solid Films 487, no. 1-2 (September 2005): 179–87. http://dx.doi.org/10.1016/j.tsf.2005.01.061.

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47

Blakers, Andrew, Ngwe Zin, Keith R. McIntosh, and Kean Fong. "High Efficiency Silicon Solar Cells." Energy Procedia 33 (2013): 1–10. http://dx.doi.org/10.1016/j.egypro.2013.05.033.

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48

Pudasaini, Pushpa Raj, and Arturo A. Ayon. "Nanostructured plasmonics silicon solar cells." Microelectronic Engineering 110 (October 2013): 126–31. http://dx.doi.org/10.1016/j.mee.2013.02.104.

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49

Jia-Yan, LI, CAI Min, WU Xiao-Wei, and TAN Yi. "Recycling Polycrystalline Silicon Solar Cells." Journal of Inorganic Materials 33, no. 9 (2018): 987. http://dx.doi.org/10.15541/jim20170547.

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50

Gharghi, Majid, Ehsanollah Fathi, Boubacar Kante, Siva Sivoththaman, and Xiang Zhang. "Heterojunction Silicon Microwire Solar Cells." Nano Letters 12, no. 12 (November 29, 2012): 6278–82. http://dx.doi.org/10.1021/nl3033813.

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