I. Usatii scite author profile

Nanostructured glass substrates endowed with high aspect ratio one-dimensional corrugations are prepared by defocused ion beam erosion through a self-organized gold (Au) stencil mask. The shielding action of the stencil mask is amplified by co-deposition of gold atoms during ion bombardment. The resulting glass nanostructures enable broadband anti-reflection functionality and at the same time ensure a high efficiency for diffuse light scattering (Haze). It is demonstrated that the patterned glass substrates exhibit a better photon harvesting than the flat glass substrate in p-i-n type thin film a-Si:H solar cells.

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Silicon oxide based n-doped layer for improved performance of thin film silicon solar cells

Veneri

Mercaldo

Usatii

2010

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We propose the use of n-doped silicon oxide as alternative n-layer in thin film Si p-i-n solar cells. By varying input gas ratios, films with a wide range of optical and electrical properties are obtained. Applying these layers in solar cells, good electrical and optical properties are demonstrated. A relative efficiency increase up to 13.6% has been observed on the cells adopting a simple Ag back contact. A similar spectral response as with the cell with standard n-layer plus ZnO/Ag back contact is obtained. The deposition of a buffer layer at the back contact can therefore be avoided.

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PECVD in-situ growth of silicon quantum dots in silicon nitride from silane and nitrogen

Mercaldo¹,

Veneri²,

Esposito³

et al. 2009

Materials Science and Engineering: B

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Properties of mixed phase n-doped silicon oxide layers and application in micromorph solar cells

Mercaldo

Veneri

Usatii

et al. 2013

Solar Energy Materials and Solar Cells

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Improved micromorph solar cells by means of mixed‐phase n‐doped silicon oxide layers

Veneri

Mercaldo

Usatii

2011

Progress in Photovoltaics

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A good light trapping scheme is necessary to improve the performance of amorphous/microcrystalline silicon tandem cells. This is generally achieved by using a highly reflective transparent conducting oxide/metal back contact plus an intermediate reflector between the component cells. In this work, the use of doped silicon oxide as alternative n‐layer in micromorph solar cells is proposed as a means to obtain high current values using a simple Ag back contact and no extra reflector between the component cells n‐doped silicon oxide layers with a wide range of optical and electrical properties have been prepared. The influence of different deposition regimes on the material properties has been studied. The main findings are the following: (i) when carbon dioxide is added to the gas mixture, sufficiently high hydrogen dilution is necessary to widen the transition region from highly conductive microcrystalline‐like films to amorphous material characterized by low electrical conductivity; (ii) lower refractive index values are found with lower deposition pressure. Optimal n‐doped silicon oxide layers have been used in both component cells of micromorph devices, adopting a simple Ag back contact. Higher current values for both cells are obtained in comparison with the values obtained using standard n‐doped microcrystalline silicon, whereas similar values of fill factor and open circuit voltage are measured. The current enhancement is particularly evident for the bottom cell, as revealed by the increased spectral response in the red/infrared region. The results prove the high potential of n‐doped silicon oxide as ideal reflector for thin‐film silicon solar cells. Copyright © 2011 John Wiley & Sons, Ltd.

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I. Usatii

Self-organized broadband light trapping in thin film amorphous silicon solar cells

Silicon oxide based n-doped layer for improved performance of thin film silicon solar cells

PECVD in-situ growth of silicon quantum dots in silicon nitride from silane and nitrogen

Properties of mixed phase n-doped silicon oxide layers and application in micromorph solar cells

Improved micromorph solar cells by means of mixed‐phase n‐doped silicon oxide layers

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