Reducing optical and resistive losses in graded silicon-germanium buffer layers for silicon based tandem cells using step-cell design

Evelina Polyzoeva; Sabina Abdul Hadi; Ammar Nayfeh; Judy L. Hoyt

doi:10.1063/1.4921945

Reducing optical and resistive losses in graded silicon-germanium buffer layers for silicon based tandem cells using step-cell design

Evelina Polyzoeva
, Sabina Abdul Hadi
, Ammar Nayfeh
, Judy L. Hoyt

Electrical Engineering

Massachusetts Institute of Technology

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Si solar cells with a SiGe graded buffer on top are fabricated as the initial step in GaAsP/Si tandem cell fabrication. Using this structure, the impact of the SiGe buffer layer on the Si solar cells is characterized. To mitigate the impact of the narrow-bandgap SiGe on the electrical and optical characteristics of the Si sub-cell, a portion of the underlying Si is exposed using a step-cell design. The step-cell design is demonstrated to increase the J_sc of the SiGe/Si stack from 5 to 20 mA/cm². The layout of the top mesa is shown to have an impact on the device characteristics with the finger design giving better results than the rectangular mesa with respect to fill factor and series resistance. In addition, utilizing the step-cell design increases overall spectral response of the bottom cell, with significant improvements in the short wavelength range.

Original language	British English
Article number	057161
Journal	AIP Advances
Volume	5
Issue number	5
DOIs	https://doi.org/10.1063/1.4921945
State	Published - 1 May 2015

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title = "Reducing optical and resistive losses in graded silicon-germanium buffer layers for silicon based tandem cells using step-cell design",

abstract = "Si solar cells with a SiGe graded buffer on top are fabricated as the initial step in GaAsP/Si tandem cell fabrication. Using this structure, the impact of the SiGe buffer layer on the Si solar cells is characterized. To mitigate the impact of the narrow-bandgap SiGe on the electrical and optical characteristics of the Si sub-cell, a portion of the underlying Si is exposed using a step-cell design. The step-cell design is demonstrated to increase the Jsc of the SiGe/Si stack from 5 to 20 mA/cm2. The layout of the top mesa is shown to have an impact on the device characteristics with the finger design giving better results than the rectangular mesa with respect to fill factor and series resistance. In addition, utilizing the step-cell design increases overall spectral response of the bottom cell, with significant improvements in the short wavelength range.",

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AU - Hoyt, Judy L.

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AB - Si solar cells with a SiGe graded buffer on top are fabricated as the initial step in GaAsP/Si tandem cell fabrication. Using this structure, the impact of the SiGe buffer layer on the Si solar cells is characterized. To mitigate the impact of the narrow-bandgap SiGe on the electrical and optical characteristics of the Si sub-cell, a portion of the underlying Si is exposed using a step-cell design. The step-cell design is demonstrated to increase the Jsc of the SiGe/Si stack from 5 to 20 mA/cm2. The layout of the top mesa is shown to have an impact on the device characteristics with the finger design giving better results than the rectangular mesa with respect to fill factor and series resistance. In addition, utilizing the step-cell design increases overall spectral response of the bottom cell, with significant improvements in the short wavelength range.

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Reducing optical and resistive losses in graded silicon-germanium buffer layers for silicon based tandem cells using step-cell design

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