Abstract: A method for forming a semiconductor structure comprising a silicon-on-insulator layer structure with crystalline silicon oxide SiOx as the insulator material comprises: providing a crystalline silicon substrate having a substantially clean deposition surface in a vacuum chamber; heating the silicon substrate to an oxidation temperature To in the range of 550 to 1200 ° C.; supplying, while keeping the silicon substrate in the oxidation temperature, with an oxidation pressure Po in the range of 1·10?8 to 1·10?4 mbar in the vacuum chamber, molecular oxygen O2 into the vacuum chamber with an oxygen dose Do in the range of 0.1 to 1000 Langmuir; whereby a crystalline silicon oxide layer with a thickness of at least two molecular layers is formed within the silicon substrate, between a crystalline silicon base layer and a crystalline silicon top layer. Related semiconductor structures are described.

Abstract: A method for forming a semiconductor structure comprising a silicon-on-insulator layer structure with crystalline silicon oxide SiOx as the insulator material comprises: providing a crystalline silicon substrate having a substantially clean deposition surface in a vacuum chamber; heating the silicon substrate to an oxidation temperature To in the range of 550 to 1200 ° C.; supplying, while keeping the silicon substrate in the oxidation temperature, with an oxidation pressure Po in the range of 1·10?8 to 1·10?4 mbar in the vacuum chamber, molecular oxygen O2 into the vacuum chamber with an oxygen dose Do in the range of 0.1 to 1000 Langmuir; whereby a crystalline silicon oxide layer with a thickness of at least two molecular layers is formed within the silicon substrate, between a crystalline silicon base layer and a crystalline silicon top layer. Related semiconductor structures are described.

Abstract: A method (100) for forming a semiconductor structure (200) comprising a silicon-on-insulator layer structure with crystalline silicon oxide SiOx as the insulator material comprises: providing (120) a crystalline silicon substrate (201) having a substantially clean deposition surface (202) in a vacuum chamber; heating (130) the silicon substrate to an oxidation temperature To in the range of 550 to 1200, 550 to 1000, or 550 to 850° C.; supplying (140), while keeping the silicon substrate in the oxidation temperature, with an oxidation pressure Po in the range of 1·10?8 to 1·10?4 mbar in the vacuum chamber, molecular oxygen O2 into the vacuum chamber with an oxygen dose Do in the range of 0.1 to 1000 Langmuir; whereby a crystalline silicon oxide layer (204) with a thickness of at least two molecular layers is formed within the silicon substrate, between a crystalline silicon base layer (203) and a crystalline silicon top layer (205).

Abstract: This disclosure relates to a semiconductor structure (100), comprising a crystalline silicon substrate (110), having a surface (111), and a crystalline silicon oxide superstructure (120) on the surface (111) of the silicon substrate (110), the silicon oxide superstructure (120) having a thickness of at least two molecular layers and a (1×1) plane structure using Wood's notation.

Abstract: A tip assembly for an intraoral scanner includes a tip support body having a first end, a second, opposite end, and an outer surface located between the first end and the second end. The outer surface defines at least one protrusion or recess. The tip assembly further includes a disposable, flexible mirror strip having a first end, a second, opposite end, and a mirror fixed to the second end. The flexible mirror strip defines at least one protrusion or recess that engages the at least one protrusion or recess of the tip support body to releasably couple the flexible mirror strip to the tip support body. The tip assembly further includes a tip sleeve having a first end and a second, opposite end. The tip sleeve is sized and shaped to slide over at least a portion of both the tip support body and the flexible mirror strip.

Abstract: A method (100) for forming a semiconductor structure (200) comprising a silicon-on-insulator layer structure with crystalline silicon oxide SiOx as the insulator material comprises: providing (120) a crystalline silicon substrate (201) having a substantially clean deposition surface (202) in a vacuum chamber; heating (130) the silicon substrate to an oxidation temperature To in the range of 550 to 1200, 550 to 1000, or 550 to 850° C.; supplying (140), while keeping the silicon substrate in the oxidation temperature, with an oxidation pressure Po in the range of 1·10?8 to 1·10?4 mbar in the vacuum chamber, molecular oxygen O2 into the vacuum chamber with an oxygen dose Do in the range of 0.1 to 1000 Langmuir; whereby a crystalline silicon oxide layer (204) with a thickness of at least two molecular layers is formed within the silicon substrate, between a crystalline silicon base layer (203) and a crystalline silicon top layer (205).