Identifying Electronic Properties Relevant to Improving the Performance and Stability of Amorphous Silicon Based Photovoltaic Cells: Final Subcontract Report, 27 November 2002--31 March 2005

    Research output: NRELSubcontract Report

    Abstract

    A major effort during this subcontract period has been to evaluate the microcrystalline Si material under development at United Solar Ovonics Corporation (USOC). This material is actually a hydrogenated nanocrystalline form of Si and it will be denoted in this report as nc-Si:H. Second, we continued our studies of the BP Solar high-growth samples. Third, we evaluated amorphous silicon-germaniumalloys produced by the hot-wire chemical vapor deposition growth process. This method holds some potential for higher deposition rate Ge alloy materials with good electronic properties. In addition to these three major focus areas, we examined a couple of amorphous germanium (a-Ge:H) samples produced by the ECR method at Iowa State University. Our studies of the electron cyclotron resonancea-Ge:H indicated that the Iowa State a Ge:H material had quite superior electronic properties, both in terms of the drive-level capacitance profiling deduced defect densities, and the transient photocapacitance deduced Urbach energies. Also, we characterized several United Solar a Si:H samples deposited very close to the microcrystalline phase transition. These samples exhibited good electronicproperties, with midgap defect densities slightly less than 1 x 1016 cm-3 in the fully light-degraded state.
    Original languageAmerican English
    Number of pages54
    StatePublished - 2005

    Bibliographical note

    Work performed by the University of Oregon, Eugene, Oregon

    NREL Publication Number

    • NREL/SR-520-38676

    Keywords

    • amorphous silicon
    • drive-level capacitance profiling (DLCP)
    • electron cyclotron resonance (ECR)
    • electronic properties
    • hot-wire chemical vapor deposition (HWCVD)
    • modulated photocurrent spectroscopy (MPS)
    • module
    • PV
    • solar cells
    • thin films
    • transient photocapacitance (TPC)

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