Crystal quality and strain distribution in 501 layer of conventional strained-Si on insulator (SSOI) and super-critical thickness strained-Si on insulator (sc-SSOI) were evaluated by in-plane X-ray diffraction (XRD), Raman spectroscopy, and other techniques. The Surface defect distribution measured by wafer inspection system shows pit-type and line defects in both SSOI layers. More specifically, the sc-SSOI material has more line defects than conventional SSOI layers. Cross-hatched pattern defects were observed using X-ray topography (XRT) measurements. Raman mapping of 300 mm wafers shows the strain at the center of the wafer is larger than at the edge. In magnified close-up mapping, cross-hatched contrasts corresponding to misfit dislocations are observed, while the surface morphology is completely smoothed out. In-plane XRD measurements show the strain depth variations are quite uniform along the depth direction. The full width at half maximum (FWHM) of in-plane XRD peaks obtained from strained-Si layers is much larger than for un-strained SOI and bulk Si, reflecting poor crystal quality. SSOI was fabricated by the layer transfer of strained-Si on a virtual SiGe substrate. Therefore, we believe the crystal quality and strain distribution originate in the donor strained Si when virtual SiGe substrate is the starting material. (C) 2008 Elsevier Ltd. All rights reserved.