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The A Si –Si i Defect Model of Light‐Induced Degradation (LID) in Silicon: A Discussion and Review
Author(s) -
Lauer Kevin,
Peh Katharina,
Schulze Dirk,
Ortlepp Thomas,
Runge Erich,
Krischok Stefan
Publication year - 2022
Publication title -
physica status solidi (a)
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.532
H-Index - 104
eISSN - 1862-6319
pISSN - 1862-6300
DOI - 10.1002/pssa.202200099
Subject(s) - silicon , boron , materials science , electron paramagnetic resonance , annealing (glass) , doping , annihilation , wafer , crystallographic defect , crystallography , nanotechnology , chemistry , optoelectronics , nuclear magnetic resonance , physics , nuclear physics , metallurgy
The A Si –Si i defect model as one possible explanation for light‐induced degradation (LID) in typically boron‐doped silicon solar cells, detectors, and related systems is discussed and reviewed. Starting from the basic experiments which led to the A Si –Si i defect model, the A Si –Si i defect model (A: boron, or indium) is explained and contrasted to the assumption of a fast‐diffusing so‐called “boron interstitial.” An LID cycle of illumination and annealing is discussed within the conceptual frame of the A Si –Si i defect model. The dependence of the LID defect density on the interstitial oxygen concentration is explained within the A Si –Si i defect picture. By comparison of electron paramagnetic resonance data and minority carrier lifetime data related to the assumed fast diffusion of the “boron interstitial” and the annihilation of the fast LID component, respectively, the characteristic EPR signal Si‐G28 in boron‐doped silicon is related to a specific A Si –Si i defect state. Several other LID‐related experiments are found to be consistent with an interpretation by an A Si –Si i defect.