Mesoscale trumps nanoscale: Metallic mesoscale contact morphology for improved light trapping, optical absorption and grid conductance in silicon solar cells

R. Saive; H.A. Atwater

doi:10.1364/OE.26.00A275

Mesoscale trumps nanoscale: Metallic mesoscale contact morphology for improved light trapping, optical absorption and grid conductance in silicon solar cells

R. Saive
, H.A. Atwater

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

32 Citations (Scopus)

53 Downloads (Pure)

Abstract

We report on a computational study exploring the design of mesoscale metallic front contacts for solar cells. We investigated silver contact structures with circle, triangle and square cross-sections for various length scales and surface coverages. We found that for ‘nanoscale’ contacts with widths between 10 nm and 1000 nm, resonant coupling actually impairs light absorption in the semiconductor. Conversely, for ‘mesoscale’ contact widths > 1000 nm, the light interaction is determined by the geometric shadowing. We find that mesoscale silver contacts with triangular cross-section outperform other nanostructure morphologies in reducing shadow losses and yield contact transparency of >99% percent with sheet resistance

Original language	English
Pages (from-to)	A275-A282
Journal	Optics express
Volume	26
Issue number	6
DOIs	https://doi.org/10.1364/OE.26.00A275
Publication status	Published - 2018

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abstract = "We report on a computational study exploring the design of mesoscale metallic front contacts for solar cells. We investigated silver contact structures with circle, triangle and square cross-sections for various length scales and surface coverages. We found that for {\textquoteleft}nanoscale{\textquoteright} contacts with widths between 10 nm and 1000 nm, resonant coupling actually impairs light absorption in the semiconductor. Conversely, for {\textquoteleft}mesoscale{\textquoteright} contact widths > 1000 nm, the light interaction is determined by the geometric shadowing. We find that mesoscale silver contacts with triangular cross-section outperform other nanostructure morphologies in reducing shadow losses and yield contact transparency of >99\% percent with sheet resistance ",

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AU - Saive, R.

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AB - We report on a computational study exploring the design of mesoscale metallic front contacts for solar cells. We investigated silver contact structures with circle, triangle and square cross-sections for various length scales and surface coverages. We found that for ‘nanoscale’ contacts with widths between 10 nm and 1000 nm, resonant coupling actually impairs light absorption in the semiconductor. Conversely, for ‘mesoscale’ contact widths > 1000 nm, the light interaction is determined by the geometric shadowing. We find that mesoscale silver contacts with triangular cross-section outperform other nanostructure morphologies in reducing shadow losses and yield contact transparency of >99% percent with sheet resistance

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Mesoscale trumps nanoscale: Metallic mesoscale contact morphology for improved light trapping, optical absorption and grid conductance in silicon solar cells

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