Systems and methods herein relate to the fabrication of a single-crystal flexible semiconductor template that may be attached to a semiconductor device. The template fabricated comprises a plurality of single crystals grown by lateral epitaxial growth on a seed layer and bonded to a flexible substrate. The layer grown has portions removed to create windows that add to the flexibility of the template.

A method for forming a semiconductor device is provided. The method includes providing a semiconductor body with a horizontal surface. An epitaxy hard mask is formed on the horizontal surface. An epitaxial region is formed by selective epitaxy on the horizontal surface relative to the epitaxy hard mask so that the epitaxial region is adjusted to the epitaxy hard mask. The epitaxial region is polished by a chemical-mechanical polishing process stopping on the epitaxy hard mask. A vertical trench is formed in the semiconductor body. An insulated field plate is formed in a lower portion of the vertical trench and an insulated gate electrode is formed above the insulated field plate. Further, a method for forming a field-effect semiconductor device is provided.

An integrated circuit structure includes a gate stack over a semiconductor substrate, and an opening extending into the semiconductor substrate, wherein the opening is adjacent to the gate stack. A first silicon germanium region is in the opening, wherein the first silicon germanium region has a first germanium percentage. A second silicon germanium region is over the first silicon germanium region, wherein the second silicon germanium region has a second germanium percentage higher than the first germanium percentage. A third silicon germanium region is over the second silicon germanium region, wherein the third silicon germanium region has a third germanium percentage lower than the second germanium percentage.

A method of forming matched PFET/NFET spacers with differential widths for SG and EG structures and a method of forming differential width nitride spacers for SG NFET and SG PFET structures and PFET/NFET EG structures and respective resulting devices are provided. Embodiments include providing PFET SG and EG structures and NFET SG and EG structures; forming a first nitride layer over the substrate; forming an oxide liner; forming a second nitride layer on sidewalls of the PFET and NFET EG structures; removing horizontal portions of the first nitride layer and the oxide liner over the PFET SG and EG structures; forming RSD structures on opposite sides of each of the PFET SG and EG structures; removing horizontal portions of the first nitride layer and the oxide liner over the NFET SG and EG structures; and forming RSD structures on opposite sides of each of the NFET SG and EG structures.

A bonded wafer structure having a handle wafer, a device wafer, and an interface region with an abrupt transition between the conductivity profile of the device wafer and the handle wafer is used for making semiconductor devices. The improved doping profile of the bonded wafer structure is well suited for use in the manufacture of integrated circuits. The bonded wafer structure is especially suited for making radiation-hardened integrated circuits.

A bonded wafer structure having a handle wafer, a device wafer, and an interface region with an abrupt transition between the conductivity profile of the device wafer and the handle wafer is used for making semiconductor devices. The improved doping profile of the bonded wafer structure is well suited for use in the manufacture of integrated circuits. The bonded wafer structure is especially suited for making radiation-hardened integrated circuits.

A reactive material erasure element comprising a reactive material is located between PCM cells and is in close proximity to the PCM cells. The reaction of the reactive material is trigger by a current applied by a bottom electrode which has a small contact area with the reactive material erasure element, thereby providing a high current density in the reactive material erasure element to ignite the reaction of the reactive material. Due to the close proximity of the PCM cells and the reactive material erasure element, the heat generated from the reaction of the reactive material can be effectively directed to the PCM cells to cause phase transformation of phase change material elements in the PCM cells, which in turn erases data stored in the PCM cells.

A method of forming a non-volatile memory device. The method includes providing a substrate having a surface region and forming a first dielectric material overlying the surface region of the substrate. A first electrode structure is formed overlying the first dielectric material and a p+ polycrystalline silicon germanium material is formed overlying the first electrode structure. A p+ polycrystalline silicon material is formed overlying the first electrode structure using the polycrystalline silicon germanium material as a seed layer at a deposition temperature ranging from about 430 Degree Celsius to about 475 Degree Celsius without further anneal. The method forms a resistive switching material overlying the polycrystalline silicon material, and a second electrode structure including an active metal material overlying the resistive switching material.

A method for manufacturing a semiconductor device includes the steps of forming a fixing layer, coupling a third substrate different from the first substrate and the second substrate to the fixing layer, separating the semiconductor thin film layer from the first substrate by moving the third substrate away from the base material substrate with the third substrate coupled to the coupling region, and bonding the semiconductor thin film layer to the second substrate after separation from the base material substrate, wherein the forming the fixing layer forms the fixing layer having a thickness such lhat a crack is generated between the fixing layer formed on the first substrate and the fixing layer formed on a side surface of the semiconductor thin film layer by a force for moving the third substrate.

A method for manufacturing a semiconductor device includes the steps of forming a fixing layer, coupling a third substrate different from the first substrate and the second substrate to the fixing layer, separating the semiconductor thin film layer from the first substrate by moving the third substrate away from the base material substrate with the third substrate coupled to the coupling region, and bonding the semiconductor thin film layer to the second substrate after separation from the base material substrate, wherein the forming the fixing layer forms the fixing layer having a thickness such lhat a crack is generated between the fixing layer formed on the first substrate and the fixing layer formed on a side surface of the semiconductor thin film layer by a force for moving the third substrate.