A method for forming a laterally-grown group III metal nitride crystal includes providing a substrate, the substrate including one of sapphire, silicon carbide, gallium arsenide, silicon, germanium, a silicon-germanium alloy, MgAl.sub.2O.sub.4 spinel, ZnO, ZrB.sub.2, BP, InP, AlON, ScAlMgO.sub.4, YFeZnO.sub.4, MgO, Fe.sub.2NiO.sub.4, LiGa.sub.5O.sub.8, Na.sub.2MoO.sub.4, Na.sub.2WO.sub.4, In.sub.2CdO.sub.4, lithium aluminate (LiAlO.sub.2), LiGaO.sub.2, Ca.sub.8La.sub.2(PO.sub.4).sub.6O.sub.2, gallium nitride, or aluminum nitride (AlN), forming a pattern on the substrate, the pattern comprising growth centers having a minimum dimension between 1 micrometer and 100 micrometers, and being characterized by at least one pitch dimension between 20 micrometers and 5 millimeters, growing a group III metal nitride from the pattern of growth centers vertically and laterally, and removing the laterally-grown group III metal nitride layer from the substrate. A laterally-grown group III metal nitride layer coalesces, leaving an air gap between the laterally-grown group III metal nitride layer and the substrate or a mask thereupon.

The present invention provides a new MOSFET structure with controllable channel length by forming lightly doped drains without using ion implantation. The MOSFET structure comprises a semiconductor wafer substrate with a semiconductor surface, a gate structure over the semiconductor surface, a channel region under the semiconductor surface, and a first conductive region electrically coupled to the channel region. The first conductive region comprises a lightly doped drain region independent from the semiconductor wafer substrate.

An IC structure comprises a first transistor formed on a substrate, a first interconnect structure over the first transistor, a dielectric layer over the first interconnect structure, a plurality of 2D semiconductor islands on the dielectric layer, and a plurality of second transistors formed on the plurality of 2D semiconductor islands.

A process for the production of a layer structure of a nitride semiconductor component on a silicon surface, comprising: provision of a substrate having a silicon surface; deposition of an aluminium-containing nitride nucleation layer on the silicon surface of the substrate; optional: deposition of an aluminium-containing nitride buffer layer on the nitride nucleation layer; deposition of a masking layer on the nitride nucleation layer or, if present, on the first nitride buffer layer; deposition of a gallium-containing first nitride semiconductor layer on the masking layer, wherein the masking layer is deposited in such a way that, in the deposition step of the first nitride semiconductor layer, initially separate crystallites grow that coalesce above a coalescence layer thickness and occupy an average surface area of at least 0.16 μm.sup.2 in a layer plane of the coalesced nitride semiconductor layer that is perpendicular to the growth direction.

A second semiconductor layer is oxidized through a groove and a fourth semiconductor layer is oxidized, a first oxide layer is formed, and a second oxide layer is formed. By oxidizing the entire second semiconductor layer and the fourth semiconductor layer, the first oxide layer and the second oxide layer in an amorphous state are formed.

A light emitting device, includes a selective growth mask layer 44; a first light reflection layer 41 thinner than the selective growth mask layer 44; a laminated structure including a first compound semiconductor layer 21, an active layer 23, and a second compound semiconductor layer 22, the first compound semiconductor layer 21 being formed on the first light reflection layer 41; and a second electrode 32 formed on the second compound semiconductor layer 22, and a second light reflection layer 42, in which the second light reflection layer 42 is opposed to the first light reflection layer 41, and the second light reflection layer is not formed on an upper side of the selective growth mask layer 44.

A semiconductor device includes a barrier layer, a channel layer, a regrowth layer, a vacancy generation region, and a source electrode or a drain electrode. The barrier layer includes a first nitride semiconductor. The channel layer includes a second nitride semiconductor and is bonded to the barrier layer at a first surface. The regrowth layer includes an n-type nitride semiconductor and is provided in a region dug deeper than an interface between the barrier layer and the channel layer from a second surface of the barrier layer. The second surface is on opposite side to the first surface. The vacancy generation region includes a nitrogen-capturing element and is provided in a region of the regrowth layer shallower than the interface between the barrier layer and the channel layer. The source electrode or the drain electrode is provided on the regrowth layer.

An object of the present invention is to provide a novel technique capable of manufacturing a large-diameter semiconductor substrate.

The present invention is a method for manufacturing a semiconductor substrate including a crystal growth step S30 of forming a growth layer 20 on an underlying substrate 10 having through holes 11. In addition, the present invention is a method for forming a growth layer 20 including the through hole formation step S10 of forming through holes 11 in the underlying substrate 10 before forming the growth layer 20 on a surface of the underlying substrate 10.

A manufacturing method for a semiconductor element includes providing a mask including an opening on a surface of a substrate while leaving a step difference in the mask at an upper surface region around the opening, epitaxially growing a semiconductor from the surface exposed through the opening to over the upper surface region around the opening, to produce a semiconductor element including a semiconductor layer including a first surface to which the step difference is transferred, and dry-etching the first surface of the semiconductor layer to transfer the step difference, the first surface being a contact surface with the mask before the dry etching is performed. The mask contains an element that serves as a donor or an acceptor in the semiconductor layer.

A method of producing an optoelectronic semiconductor chip includes in order: A) creating a nucleation layer on a growth substrate, B) applying a mask layer on to the nucleation layer, C) growing a coalescence layer, wherein the coalescence layer is grown starting from regions of the nucleation layer not covered by mask islands having a first main growth direction perpendicular to the nucleation layer so that ribs are formed, D) further growing the coalescence layer with a second main growth direction parallel to the nucleation layer to form a contiguous and continuous layer, E) growing a multiple quantum well structure on the coalescence layer, F) applying a mirror having metallic contact regions that impress current into the multiple quantum well structure and mirror islands for the total reflection of radiation generated in the multiple quantum well structure, and G) detaching the growth substrate and creating a roughening by etching.