Patterned Dielectric Back Contact Design for GaAs Thermophotovoltaic Devices: Article No. 113285

Madhan Arulanandam, Jeronimo Buencuerpo, Myles Steiner, Leah Kuritzky, Alexandra Young, Eric Tervo, Emmett E. Perl, Brendan Kayes, Justin Briggs, Richard King

Research output: Contribution to journalArticlepeer-review

Abstract

-Patterned-dielectric back contact structures in optoelectronic devices are designed to boost the reflectance of light from the device back surface while retaining a low-resistance pathway for electrical conductance. Their reduced light absorption at near- and sub-bandgap photon energies leads to improved luminescence in light-emitting diodes, greater photon recycling, voltage, and efficiency in photovoltaic cells, and greater recuperation of unabsorbed sub-bandgap light in thermophotovoltaic (TPV) systems. However, diffraction from the patterned features can deflect incident light in propagation directions that lead to light trapping and parasitic absorption in the cell. In this article, we use rigorous coupled-wave analysis (RCWA) to study three-dimensional diffractive scattering of electromagnetic waves by periodic metal point-contact gratings on 1.42-eV GaAs TPV cells, to analyze their effect on unwanted sub-bandgap absorption in order to achieve higher TPV system efficiency. Solutions of Maxwell's equations calculated using RCWA are compared to measured sub-bandgap reflectance in experimental GaAs TPV devices with varying metal point-contact diameters and spacing. Modeling and experiments indicate decreased total reflectance due to these diffractive effects for a small point contact diameter of 1 ..mu..m, and this effect is much stronger at higher contact coverage fractions.
Original languageAmerican English
Number of pages11
JournalSolar Energy Materials and Solar Cells
Volume281
DOIs
StatePublished - 2025

NREL Publication Number

  • NREL/JA-5900-92417

Keywords

  • diffraction grating
  • efficiency
  • GaAs
  • patterned dielectric back contact
  • rigorous coupled wave analysis
  • sub-bandgap spectrum
  • thermophotovoltaics

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