Thin‐film (25.5 μm) solar cells from layer transfer using porous silicon with 32.7 mA/cm<sup>2</sup> short‐circuit current density

Feldrapp, Karlheinz; Horbelt, Renate; Auer, R.; Brendel, Rolf

doi:10.1002/pip.465

Cited by 29 publications

(10 citation statements)

References 5 publications

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“…Fabrication of significantly thinner sheets of high quality Si with a thickness below 20 lm has been demonstrated by various techniques. [1][2][3] Throughout this work, we use a Si thickness of 20 lm as a case of study when exploring the light-trapping ability of the various structures. This is thinner than today's wafer-based solar cells by a factor of 10 and at the same time thicker than ordinary thinfilm solar cells by a factor of 10.…”

Section: Introductionmentioning

confidence: 99%

Comparison of periodic light-trapping structures in thin crystalline silicon solar cells

Gjessing

Sudbø

Marstein

2011

Journal of Applied Physics

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Material costs may be reduced and electrical properties improved by utilizing thinner solar cells. Light trapping makes it possible to reduce wafer thickness without compromising optical absorption in a silicon solar cell. In this work we present a comprehensive comparison of the light-trapping properties of various bi-periodic structures with a square lattice. The geometries that we have investigated are cylinders, cones, inverted pyramids, dimples (half-spheres), and three more advanced structures, which we have called the roof mosaic, rose, and zigzag structure. Through simulations performed with a 20 μm thick Si cell, we have optimized the geometry of each structure for light trapping, investigated the performance at oblique angles of incidence, and computed efficiencies for the different diffraction orders for the optimized structures. We find that the lattice periods that give optimal light trapping are comparable for all structures, but that the light-trapping ability varies considerably between the structures. A far-field analysis reveals that the superior light-trapping structures exhibit a lower symmetry in their diffraction patterns. The best result is obtained for the zigzag structure with a simulated photo-generated current Jph of 37.3 mA/cm2, a light-trapping efficiency comparable to that of Lambertian light-trapping.

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Section: Introductionmentioning

confidence: 99%

Comparison of periodic light-trapping structures in thin crystalline silicon solar cells

Gjessing

Sudbø

Marstein

2011

Journal of Applied Physics

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“…PV properties of various c‐Si solar cells as a function of c‐Si wafer/absorber thickness, w : a) V OC , b) J SC , c) FF, and d) efficiency. The difference in symbol types indicates the different approaches for preparing the thin c‐Si absorber and the cell architectures: standard slicing or thinning (SHJ cells [ 9,20,31,34,36–40,55–57 ] including heteroback contacts [ 30,32,33,55 ] and other types [ 6,8,9,11,18,58–62 ] ), epitaxially grown c‐Si films, [ 12–20,27 ] SOI, [ 24 ] exfoliated Si films, [ 19 ] and polycrystalline Si films. [ 25,26 ] The filled symbols represent data for cells which have been independently confirmed.…”

Section: Resultsmentioning

confidence: 99%

“…Experimentally, thin ( w < 100 μm) and very thin ( w < 70 μm) c‐Si cells have been investigated based on various technologies such as sliced/thinned free‐standing wafers, [ 6–11 ] epitaxially grown Si thin layers, [ 12–20 ] exfoliated Si films, [ 19,21 ] Si on insulator (SOI) wafers, [ 22–24 ] and polycrystalline Si thin films. [ 25,26 ] The first very thin c‐Si cell having η > 20% was demonstrated by Wang et al in 1996, [ 6 ] whereby a 21.5% efficient passivated emitter rear locally diffused (PERL) cell was fabricated using float‐zone (FZ) Si wafers ( w = 47 μm) and thinned by chemical etching.…”

Section: Introductionmentioning

confidence: 99%

“…It is worth noting that the efficiency limit is dependent on light trapping scheme and numerical simulation has predicted that η > 30% is possible for very thin c-Si cells (15 μm) by applying advanced light trapping using photonic crystals. [4,5] Experimentally, thin (w < 100 μm) and very thin (w < 70 μm) c-Si cells have been investigated based on various technologies such as sliced/thinned free-standing wafers, [6][7][8][9][10][11] epitaxially grown Si thin layers, [12][13][14][15][16][17][18][19][20] exfoliated Si films, [19,21] Si on insulator (SOI) wafers, [22][23][24] and polycrystalline Si thin films. [25,26] The first very thin c-Si cell having η > 20% was demonstrated by Wang et al in 1996, [6] whereby a 21.5% efficient passivated emitter rear locally diffused (PERL) cell was fabricated using float-zone (FZ) Si wafers (w ¼ 47 μm) and thinned by chemical etching.…”

Section: Introductionmentioning

confidence: 99%

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Very Thin (56 μm) Silicon Heterojunction Solar Cells with an Efficiency of 23.3% and an Open‐Circuit Voltage of 754 mV

2021

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The silicon heterojunction (SHJ) is a crystalline silicon (c‐Si) solar cell device architecture capable of achieving high efficiencies due to excellent surface passivation realized by hydrogenated amorphous silicon (a‐Si:H) thin layers. The SHJ architecture also allows to process thinner Si wafers due to the structural symmetry and the low processing temperature. Herein, an attempt to increase the performance of very thin c‐Si solar cells is made, using an advanced SHJ architecture. By replacing the conventional a‐Si:H by hydrogenated nanocrystalline silicon (nc‐Si:H) in the hole contact layer, an increase in all solar cell parameters over a wide range of wafer thicknesses from 50 to 400 μm is observed. This also provides an open‐circuit voltage (V OC) of 754 mV with the very thin absorber, which is the highest V OC independently confirmed under standard test conditions (STCs) among any c‐Si solar cells ever reported. As a result, a notable efficiency of 23.27% is realized in a SHJ cell with an average thickness of only 56.2 μm. These results demonstrate the high potential of very thin c‐Si solar cells that may open various opportunities for flexible and lightweight c‐Si modules, as well as reducing the carbon footprint of solar cell manufacture.

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“…In the bending experiments, an efficiency of 14.6% was independently confirmed after the film was transferred to a flexible plastic foil [64]. Solar cells prepared by transfer technology have achieved conversion efficiencies of up to 16% [63,65].…”

Section: (A) Transfer Technologiesmentioning

confidence: 85%

Silicon-Based Technologies for Flexible Photovoltaic (PV) Devices: From Basic Mechanism to Manufacturing Technologies

2021

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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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Thin‐film (25.5 μm) solar cells from layer transfer using porous silicon with 32.7 mA/cm² short‐circuit current density

Cited by 29 publications

References 5 publications

Comparison of periodic light-trapping structures in thin crystalline silicon solar cells

Comparison of periodic light-trapping structures in thin crystalline silicon solar cells

Very Thin (56 μm) Silicon Heterojunction Solar Cells with an Efficiency of 23.3% and an Open‐Circuit Voltage of 754 mV

Silicon-Based Technologies for Flexible Photovoltaic (PV) Devices: From Basic Mechanism to Manufacturing Technologies

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Thin‐film (25.5 μm) solar cells from layer transfer using porous silicon with 32.7 mA/cm2 short‐circuit current density

Cited by 29 publications

References 5 publications

Comparison of periodic light-trapping structures in thin crystalline silicon solar cells

Comparison of periodic light-trapping structures in thin crystalline silicon solar cells

Very Thin (56 μm) Silicon Heterojunction Solar Cells with an Efficiency of 23.3% and an Open‐Circuit Voltage of 754 mV

Silicon-Based Technologies for Flexible Photovoltaic (PV) Devices: From Basic Mechanism to Manufacturing Technologies

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Thin‐film (25.5 μm) solar cells from layer transfer using porous silicon with 32.7 mA/cm² short‐circuit current density