2017
DOI: 10.1038/s41598-017-16724-4
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Probing spatial heterogeneity in silicon thin films by Raman spectroscopy

Abstract: Raman spectroscopy is a powerful technique for revealing spatial heterogeneity in solid-state structures but heretofore has not been able to measure spectra from multiple positions on a sample within a short time. Here, we report a novel Raman spectroscopy approach to study the spatial heterogeneity in thermally annealed amorphous silicon (a-Si) thin films. Raman spectroscopy employs both a galvano-mirror and a two-dimensional charge-coupled device detector system, which can measure spectra at 200 nm intervals… Show more

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Cited by 5 publications
(6 citation statements)
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“…For film structure investigation, thick films up to the micrometer scale allowing depth profile with confocal Raman microscopy [36]- [37] or materials with a high Raman cross-section are mostly investigated to get an exploitable Raman signal [38]- [39]- [40]. For instance, this technique is frequently used to investigate amorphous thin films with high-intensity Raman answer, in particular silicon, carbon [40]- [41]- [42]- [43] and chalcogenides [44]- [45]. For thin films (<1 µm), specific substrates (fluorides) with a low Raman background signal can be used [46]- [47] and, in some specific cases, surface-enhanced Raman scattering has a beneficial influence on the thin film signal intensity [48]- [49].…”
Section: Introductionmentioning
confidence: 99%
“…For film structure investigation, thick films up to the micrometer scale allowing depth profile with confocal Raman microscopy [36]- [37] or materials with a high Raman cross-section are mostly investigated to get an exploitable Raman signal [38]- [39]- [40]. For instance, this technique is frequently used to investigate amorphous thin films with high-intensity Raman answer, in particular silicon, carbon [40]- [41]- [42]- [43] and chalcogenides [44]- [45]. For thin films (<1 µm), specific substrates (fluorides) with a low Raman background signal can be used [46]- [47] and, in some specific cases, surface-enhanced Raman scattering has a beneficial influence on the thin film signal intensity [48]- [49].…”
Section: Introductionmentioning
confidence: 99%
“…The calculated power density was 1.27 mW μm −2 at 1 mW. For the nanostructure size measuring, the combination of a quasi-line excitation source obtained with a galvano-mirror and a two-dimensional charge-coupled device (CCD) detector system was used 19,27,28) to obtain both spatial and energy information simultaneously using a two-dimensional CCD pixel array. Thus, we can obtain 512 spectra at 200 nm intervals.…”
Section: Experimental Methodsmentioning
confidence: 99%
“…The accuracy of this measurement was compared with that of X-ray diffraction and showed good agreement in general. 19) For the thermal conductivity measurement, the laser-power was controlled by a variable neutral density filter in the incident light path. The exposure time of the UV excitation light was 30 s. Laser-power was measured at the poly-Si sample using a laser-power meter to avoid the damage on the poly-Si from laser heating.…”
Section: Experimental Methodsmentioning
confidence: 99%
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“…The laser spot size used was approximately 1 m with calculated power density of 1.27 mW/ m 2 at 1 mW. For the nanostructure size evaluation, the combination of a quasi-line excitation source obtained with a galvanomirror and a two-dimensional charge-coupled device (CCD) pixel array detector system was used (17)(18)(19) to obtain both spatial and energy information simultaneously. Thus, we can obtain 512 spectra at 200 nm intervals simultaneously.…”
Section: Figure 1 Schematics Of Poly-si Thin Film Formation Processesmentioning
confidence: 99%