Abstract
Based on contactless carrier lifetime measurements performed on p-type boron-doped Czochralski-grown silicon (Cz-Si) wafers, we examine the rate constant Rde of the permanent deactivation process of the boron-oxygen-related defect center as a function of the illumination intensity I at 170°C. While at low illumination intensities, a linear increase of Rde on I is measured, at high illumination intensities, Rde seems to saturate. We are able to explain the saturation by assuming that Rde increases proportionally with the excess carrier concentration Δn and take the fact into account that at sufficiently high illumination intensities, the carrier lifetime decreases with increasing Δn and hence the slope of Δn(I) decreases, leading to an apparent saturation. Importantly, on low-lifetime Cz-Si samples no saturation of the deactivation rate constant is observed for the same illumination intensities, proving that the deactivation is stimulated by the presence of excess electrons and not directly by the photons.
Highlights
Kinetics of the permanent deactivation of the boron-oxygen complex in crystalline silicon as a function of illumination intensity
Since the 1970s it is known that the power output of solar cells fabricated on boron-doped Czochralski-grown silicon (Cz-Si) degrades under prolonged illumination at room temperature.[1]
In the past two decades, this light-induced degradation (LID) effect has been extensively investigated and it was shown that the simultaneous presence of boron and oxygen in the silicon material is a necessary prerequisite for the LID.[2,3]
Summary
Kinetics of the permanent deactivation of the boron-oxygen complex in crystalline silicon as a function of illumination intensity. While the impact of temperature on the deactivation rate constant Rde follows an Arrhenius law,[6,7] only very limited data has been published concerning the dependence of Rde on the illumination intensity during the process of permanent deactivation.
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