Investigation of Sub‐Bandgap Emission and Unexpected n‐Type Behavior in Undoped Polycrystalline CdSe_xTe_1‐x Article Swipe

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Cadmium telluride photovoltaics Crystallite Materials science Band gap Doping Analytical Chemistry (journal) Vacancy defect Annealing (glass) Diffusion Crystallography Optoelectronics Chemistry Metallurgy Physics Chromatography Thermodynamics

Deborah L. McGott , Steve Johnston , Chun‐Sheng Jiang , Tuo Liu , Darius Kuciauskas , Stephen Glynn , Matthew O. Reese ·

YOU? · · 2024 · Open Access · · DOI: https://doi.org/10.1002/advs.202309264 · OA: W4399292698

Se alloying has enabled significantly higher carrier lifetimes and photocurrents in CdTe solar cells, but these benefits can be highly dependent on CdSe x Te 1‐x processing. This work evaluates the optoelectronic, chemical, and electronic properties of thick (3 µm) undoped CdSe x Te 1‐x of uniform composition and varied processing conditions (CdSe x Te 1‐x evaporation rate, CdCl 2 anneal, Se content) chosen to reflect various standard device processing conditions. Sub‐bandgap defect emission is observed, which increased as Se content increased and with “GrV‐optimized CdCl 2 ” (i.e., CdCl 2 anneal conditions used for group‐V‐doped devices). Low carrier lifetime is found for GrV‐optimized CdCl 2 , slow CdSe x Te 1‐x deposition, and low‐Se films. Interestingly, all films (including CdTe control) exhibited n‐type behavior, where electron density increased with Se up to an estimated ≈10 17 cm −3 . This behavior appears to originate during the CdCl 2 anneal, possibly from Se diffusion leading to anion vacancy (e.g., V Se , V Te ) and Cl Te generation.