Measurement of Band Offsets and Shunt Resistance in CdTe Solar Cells Through Temperature and Intensity Dependence of Open Circuit Voltage and Photoluminescence

Marinus Van Hest, Benjia Dou, Joseph Luther, Gregory Pach, Matthew Reese, Craig Swartz, Sadia Rab, Sanjoy Paul, Corey Grice, Dengbing Li, Sandip Bista, Elizabeth LeBlanc, Mark Holtz, Thomas Myers, Yanfa Yan, Jian Li

Research output: Contribution to journalArticlepeer-review

10 Scopus Citations

Abstract

Band offsets at the back contact and front window layer in CdTe-based solar cells affect photovoltaic performance and challenge standard characterization methods. By analyzing the temperature and excitation dependence of both open circuit voltage and absolute photoluminescence intensity, we show that the effects band offsets can be separated from the effects of recombination and shunting. Solar cells were grown with MgZnO window layers and compared to cells with CdS window layers containing varying amounts of oxygen. It was demonstrated that band alignment rather than reduced recombination velocity is the reason for the success of MgZnO as a front interface contact. An assortment of thin back contact interlayers were also deposited, and a PbTe interlayer showed some promise as an Ohmic contact to the CdTe, though it appears to induce a photoconductive shunt. Finally, we show that the shunting resistance given by a standard current-voltage curve technique generally does not represent a physically meaningful quantity unless it is well below one kiloOhm square cm.

Original languageAmerican English
Pages (from-to)389-397
Number of pages9
JournalSolar Energy
Volume189
DOIs
StatePublished - 1 Sep 2019

Bibliographical note

Publisher Copyright:
© 2019

NREL Publication Number

  • NREL/JA-5K00-75058

Keywords

  • Contact barrier
  • Injection dependence
  • Loss analysis
  • Model fitting
  • Photovoltaic device characterization
  • Recombination

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