2015
DOI: 10.1109/jphotov.2015.2407158
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Micrometer-Scale Deep-Level Spectral Photoluminescence From Dislocations in Multicrystalline Silicon

Abstract: Abstract-Micrometer-scale deep-level spectral photoluminescence (PL) from dislocations is investigated around the subgrain boundaries in multicrystalline silicon. The spatial distribution of the D lines is found to be asymmetrically distributed across the subgrain boundaries, indicating that defects and impurities are decorated almost entirely on one side of the subgrain boundaries. In addition, the D1 and D2 lines are demonstrated to have different origins due to their significantly varying behaviors after pr… Show more

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Cited by 32 publications
(36 citation statements)
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“…The characteristic wavelength reported in the literature for the D4 line is consistent with our observed 1230 nm peak in Fig. 2, whereas the characteristic wavelength corresponding to the D3 is slightly lower than the literature value reported to vary between 1290 and 1305 nm depending on the relative position around dislocation sites [25]. We are not able to observe these luminescence peaks at all on unprocessed silicon, and therefore, we can reasonably conclude that the two deep-level peaks at 1230 and 1280 nm observed in Fig.…”
Section: Pl Spectra Of Excimer Laser-damaged Silicon Substratesupporting
confidence: 91%
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“…The characteristic wavelength reported in the literature for the D4 line is consistent with our observed 1230 nm peak in Fig. 2, whereas the characteristic wavelength corresponding to the D3 is slightly lower than the literature value reported to vary between 1290 and 1305 nm depending on the relative position around dislocation sites [25]. We are not able to observe these luminescence peaks at all on unprocessed silicon, and therefore, we can reasonably conclude that the two deep-level peaks at 1230 and 1280 nm observed in Fig.…”
Section: Pl Spectra Of Excimer Laser-damaged Silicon Substratesupporting
confidence: 91%
“…The locations of these two deep-level peaks are close to the so-called D4 and D3 lines, which are emitted from intrinsic dislocations in crystalline silicon and are particularly observable near liquid nitrogen temperatures [25,26]. The characteristic wavelength reported in the literature for the D4 line is consistent with our observed 1230 nm peak in Fig.…”
Section: Pl Spectra Of Excimer Laser-damaged Silicon Substratesupporting
confidence: 90%
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“…In recent years, with the advent of micro‐photoluminescence spectroscopy (μ‐PLS) tools, equipped with confocal optics, microstructures in Si wafers and solar cells can be investigated with very high spatial resolution, enabling the study of dislocation clusters, grain boundaries, metal and oxide precipitates, and locally laser‐doped regions . Currently, there are several μ‐PLS‐based methods to assess doping densities of heavily‐doped layers in c‐Si wafers and solar cells, proposed by different authors .…”
Section: Introductionmentioning
confidence: 99%
“…They reduce the carrier lifetime of silicon materials in both the dissolved state and the precipitated state, and are thus detrimental to silicon solar cells . Knowledge of the metal concentrations in silicon materials is also significant for the studies of other defects, including light and elevated temperature‐induced degradation, decorated crystal defects such as dislocations and grain boundaries, copper‐related light‐induced degradation, boron‐oxygen‐related defects, ring defects, and so on. The metal concentrations in multicrystalline silicon (mc‐Si) ingots have been successfully determined by applying neutron activation analysis in previous studies .…”
mentioning
confidence: 99%