A self-supporting substrate includes a first nitride layer grown by hydride vapor deposition method or ammonothermal method and comprising a nitride of one or more element selected from the group consisting of gallium, aluminum and indium; and a second nitride layer grown by a sodium flux method on the first nitride layer and comprising a nitride of one or more element selected from the group consisting of gallium, aluminum and indium. The first nitride layer includes a plurality of single crystal grains arranged therein and being extended between a pair of main faces of the first nitride layer. The second nitride layer includes a plurality of single crystal grains arranged therein and being extended between a pair of main faces of the second nitride layer. The first nitride layer has a thickness larger than a thickness of the second nitride layer.

A self-supporting substrate includes a first nitride layer grown by hydride vapor deposition method or ammonothermal method and comprising a nitride of one or more element selected from the group consisting of gallium, aluminum and indium; and a second nitride layer grown by a sodium flux method on the first nitride layer and comprising a nitride of one or more element selected from the group consisting of gallium, aluminum and indium. The first nitride layer includes a plurality of single crystal grains arranged therein and being extended between a pair of main faces of the first nitride layer. The second nitride layer includes a plurality of single crystal grains arranged therein and being extended between a pair of main faces of the second nitride layer. The first nitride layer has a thickness larger than a thickness of the second nitride layer.

In a manufacturing method of a semiconductor element of the present disclosure, a first semiconductor part (SL1) includes a protruding portion (TS) protruding toward an underlying substrate (UK), the protruding portion contains a nitride semiconductor, the protruding portion and the underlying substrate are bonded to each other, a semiconductor substrate (HK) includes a hollow portion (TK) located between the underlying substrate and the first semiconductor part, the hollow portion is in contact with a side surface of the protruding portion and communicates with the outside of the semiconductor substrate, and the protruding portion (TS) is irradiated with the laser beam (LZ) before the first semiconductor part is separated from the semiconductor substrate.

Methods for growing microstructured and nanostructured graphene by growing the microstructured and nanostructured graphene from the bottom-up directly in the desired pattern are provided. The graphene structures can be grown via chemical vapor deposition (CVD) on substrates that are partially covered by a patterned graphene growth barrier which guides the growth of the graphene.

Methods for growing microstructured and nanostructured graphene by growing the microstructured and nanostructured graphene from the bottom-up directly in the desired pattern are provided. The graphene structures can be grown via chemical vapor deposition (CVD) on substrates that are partially covered by a patterned graphene growth barrier which guides the growth of the graphene.

A method for producing a plurality of semiconductor chips and a semiconductor chip are disclosed. The method includes applying a mask material on a growth surface of a growth substrate, wherein the growth surface includes sapphire, patterning the mask material into a multiply-connected mask layer by introducing openings into the mask material, wherein the growth surface is exposed at the bottom of at least some of the openings, applying a semiconductor layer sequence on the mask layer and on the growth surface and singulating at least the semiconductor layer sequence into the plurality of semiconductor chips, wherein each semiconductor chip includes lateral dimensions and the lateral dimensions are large compared to an average distance of the openings to the nearest opening.

A method for producing a plurality of semiconductor chips and a semiconductor chip are disclosed. The method includes applying a mask material on a growth surface of a growth substrate, wherein the growth surface includes sapphire, patterning the mask material into a multiply-connected mask layer by introducing openings into the mask material, wherein the growth surface is exposed at the bottom of at least some of the openings, applying a semiconductor layer sequence on the mask layer and on the growth surface and singulating at least the semiconductor layer sequence into the plurality of semiconductor chips, wherein each semiconductor chip includes lateral dimensions and the lateral dimensions are large compared to an average distance of the openings to the nearest opening.

The present invention provides a metal nitride platform for semiconductor devices, including, a pre-defined array of catalyst sites, disposed on a substrate. Metal nitride islands with lateral to vertical size ratios of at least greater than one (1) are disposed on the array of catalyst sites, where the surfaces of the metal nitride islands are with reduced dislocation densities and side walls with bending of dislocations. The platform of metal nitride islands is further used to build electrically and optically-active devices. The present invention also provides a process for the preparation of a metal nitride platform, selectively, on the array of catalyst sites, in the presence of a reactive gas and precursors and under preferred reaction conditions, to grow metal nitride islands with lateral to vertical size ratios of at least greater than one (1).

The present invention provides a method for manufacturing a diamond substrate, including: a first step of preparing patterned diamond on a foundation surface, a second step of removing a foreign substance adhered on a wall of the patterned diamond prepared in the first step, and a third step of growing diamond from the patterned diamond prepared in the first step to form the diamond in a pattern gap of the patterned diamond prepared in the first step. There can be provided a method for manufacturing a diamond substrate with few dislocation defects, in which generation of abnormal growth particles are suppressed.

The present invention provides a method for manufacturing a diamond substrate, including: a first step of preparing patterned diamond on a foundation surface, a second step of removing a foreign substance adhered on a wall of the patterned diamond prepared in the first step, and a third step of growing diamond from the patterned diamond prepared in the first step to form the diamond in a pattern gap of the patterned diamond prepared in the first step. There can be provided a method for manufacturing a diamond substrate with few dislocation defects, in which generation of abnormal growth particles are suppressed.