A method for manufacturing a substrate includes the following steps: (a) providing a support substrate with a first coefficient of thermal expansion, having on one of its faces a first plurality of trenches parallel to each other in a first direction, and a second plurality of trenches parallel to each other in a second direction; (b) transferring a useful layer from a donor substrate to the support substrate, the useful layer having a second coefficient of thermal expansion; wherein an intermediate layer is inserted between the front face of the support substrate and the useful layer, the intermediate layer having a coefficient of thermal expansion between the first and second coefficients of thermal expansion.

A semiconductor device includes a metal layer, an insulating layer disposed above the metal layer, and a multi-layer diffusion barrier disposed on the metal layer between the metal layer and the insulating layer. The multi-layer diffusion barrier includes a first material layer including a metallic nitride and a second material layer including a metallic oxide.

Provided are a group III nitride composite substrate having a low sheet resistance and produced with a high yield, and a method for manufacturing the same, as well as a method for manufacturing a group III nitride semiconductor device using the group III nitride composite substrate. A group III nitride composite substrate includes a group III nitride film and a support substrate formed from a material different in chemical composition from the group III nitride film. The group III nitride film is joined to the support substrate in one of a direct manner and an indirect manner. The group III nitride film has a thickness of 10 m or more. A sheet resistance of a group III-nitride-film-side main surface is 200 /sq or less.

The present invention is in the field of an atomic scale data storage device which uses vacancy manipulation, a method of providing said device, and a method of operating said device. Prior art mass data storage devices typically rely on magnetic materials forming discrete arrays or on nanoscale transistors. Further examples are e.g. optical systems such as a DVD and a compact disk. These devices and systems have a large, but for some applications still limited, storage capacity.

A method includes etching a hybrid substrate to form a recess in the hybrid substrate, in which the hybrid substrate includes a first semiconductor layer, a dielectric layer over the first semiconductor layer, and a second semiconductor layer over the first semiconductor layer, in which after the etching, a top surface of the first semiconductor layer is exposed to the recess; forming a spacer on a sidewall of the recess, in which the spacer is slanted at a first angle relative to a top surface of the first semiconductor layer; reshaping the spacer such that the a first sidewall of the reshaped spacer is slanted at a second angle relative to the top surface of the first semiconductor layer, in which the second angle is greater than the first angle; and performing a first epitaxy process to grow an epitaxy semiconductor layer in the recess after reshaping the spacer.

Provided are a group III nitride composite substrate having a low sheet resistance and produced with a high yield, and a method for manufacturing the same, as well as a method for manufacturing a group III nitride semiconductor device using the group III nitride composite substrate. A group III nitride composite substrate includes a group III nitride film and a support substrate formed from a material different in chemical composition from the group III nitride film. The group III nitride film is joined to the support substrate in one of a direct manner and an indirect manner. The group III nitride film has a thickness of 10 m or more. A sheet resistance of a group III-nitride-film-side main surface is 200 /sq or less.

A semiconductor device comprising a first circuit component and a second circuit component, the first circuit component having a first wiring structure formed by stacking one or more wiring layers and one or more insulating layers on a first semiconductor substrate, the second circuit component having a second wiring structure formed by stacking one or more wiring layers and one or more insulating layers on a second semiconductor substrate, the first and second wiring structures being bonded to each other, their bonding planes being composed of oxygen atoms and carbon atoms and/or nitrogen atoms bonded to silicon atoms, and, numbers of their atoms satisfying a predetermined equation.

The present invention relates to a III-N single crystal adhering to a substrate, wherein III denotes at least one element of the third main group of the periodic table of the elements, selected from the group of Al, Ga and In, wherein the III-N single crystal exhibits, within a temperature range of an epitaxial crystal growth, a value (i) of deformation .sub.XX in the range of <0. Additionally or alternatively, the III-N single crystal exhibits at room temperature a value (ii) of deformation .sub.XX in the range of <0.

There is provided a template comprising a substrate comprising sapphire and at least one III-N crystal layer, wherein III denotes at least one element of the main group III of the periodic table of the elements, selected from the group of Al, Ga and In, wherein in a region of the at least one III-N layer above the substrate comprises a mask material as an interlayer, wherein the III-N crystal layer of the template is defined by one or both of the following values (i)/(ii) of the deformation .sub.xx: (i) at room temperature the .sub.xx value lies in the range of <0; and (ii) at growth temperature the .sub.xx value lies in the range of .sub.xx0.

The present invention relates to the production of III-N templates and also the production of III-N single crystals, III signifying at least one element of the third main group of the periodic table, selected from the group of Al, Ga and In. By adjusting specific parameters during crystal growth, III-N templates can be obtained that bestow properties on the crystal layer that has grown on the foreign substrate which enable flawless III-N single crystals to be obtained in the form of templates or even with large III-N layer thickness.