Computational Modeling of Polycrystalline Silicon on Oxide Passivating Contact for Silicon Solar Cells
IEEE Transactions on Electron Devices • 2019
Publication Information
Authors
R. Younas; H. Imran; S. I. H. Shah; T. M. Abdolkader; N. Z. Butt
Keywords
solar cells; tunnelling; Photovoltaic cells
Journal
IEEE Transactions on Electron Devices
Publisher
Not Available
Volume
66
Issue
4
Pages
1819 - 1826
publication.type
International
Paper Link
Not Available
Supplementary Materials
Not Available
Abstract
Polycrystalline silicon on oxide (POLO) junction passivating contacts have recently been demonstrated as carrier selective contacts for high-efficiency silicon solar cells. The carrier transport through these contacts has been attributed to two competing mechanisms: 1) carrier tunneling through ultrathin oxide and 2) transport through weak spots (pinholes) - the nanoscale regions where oxide thickness has been completely or partially compromised during the processing. In this paper, we use two dimensional device simulations to compare the relative effects of these mechanisms on solar cell characteristics with ntype POLO contact. We show that variation in pinhole areal density (Dph) or the tunnel oxide thickness (tox) both result in qualitatively similar trends in the cell characteristics under dark and light. For a given tox, an exponential variation in Dph results in trends that are similar to those for a linear variation in tox. The effect of pinholes on contact resistance (ρc) and saturation current density (Jo) is most significant for relatively thicker oxides (≥ 2 nm). For tox ≤ 1 nm, ρc and Jo become essentially insensitive to pinholes for Dph
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