A method of manufacturing a semiconductor device, includes: forming an insulating layer on a single crystal semiconductor substrate; forming a non-crystalline semiconductor layer on the insulating layer; forming an insulating film on the non-crystalline semiconductor layer; forming an opening section for exposing a part of a surface of the single crystal semiconductor substrate through the insulating film, the non-crystalline semiconductor layer and the insulating layer; forming a single crystal semiconductor layer embedded in the opening section so as to have contact with the non-crystalline semiconductor layer; removing the insulating film and the insulating layer while the single crystal semiconductor layer supporting the non-crystalline semiconductor layer above the single crystal semiconductor substrate; forming a single-crystallized semiconductor layer obtained by single-crystallizing the non-crystalline semiconductor layer using the single crystal semiconductor layer as a seed by providing a thermal treatment on the non-crystalline semiconductor layer from which the insulating film and the insulating layer are removed; filling a gap between the single-crystallized semiconductor layer and the single crystal semiconductor substrate with an embedded insulating layer; forming a gate electrode on the single-crystallized semiconductor layer; and forming in the single-crystallized semiconductor layer a source layer disposed on one side of the gate electrode and a drain layer disposed on the other side of the gate electrode.

A method of fabricating a semiconductor device includes forming an insulation layer structure on a single-crystalline silicon substrate, forming a first insulation layer structure pattern comprising a first opening by etching a portion of the insulation layer structure, filling the first opening with a non-single-crystalline silicon layer, and forming a single-crystalline silicon pattern by irradiating a first laser beam onto the non-single-crystalline silicon layer. The method also includes forming a second insulation layer structure pattern comprising a second opening by etching a portion of the first insulation layer structure, filling the second opening with a non-single-crystalline silicon-germanium layer, and forming a single-crystalline silicon-germanium pattern by irradiating a second laser beam onto the non-single-crystalline silicon-germanium layer.

A method of forming an integrated circuit can be provided by successively laterally forming single crystalline thin film regions from an amorphous thin film using a lower single crystalline seed layer.

The present invention provides silicon based thin-film structures that can be used to form high frequency optical modulators. Devices of the invention are formed as layered structures that have a thin-film dielectric layer, such as silicon dioxide, sandwiched between silicon layers. The silicon layers have high free carrier mobility. In one aspect of the invention a high mobility silicon layer can be provided by crystallizing an amorphous silicon layer. In another aspect of the invention, a high mobility silicon layer can be provided by using selective epitaxial growth and extended lateral overgrowth thereof.