The disclosure provides a preparation method of GaN field effect transistor based on diamond substrate, and relates to the technical field of semiconductor manufacturing. The method includes the following steps: preparing a GaN heterojunction layer on the front-side of a SiC substrate; thinning the SiC substrate; etching the SiC substrate; growing a diamond layer; removing a sacrificial layer and the diamond layer on the sacrificial layer; preparing a source electrode, a drain electrode and a gate electrode on the front surface of the GaN heterojunction layer; etching the SiC substrate and the GaN heterojunction layer to form a source through hole communicated with the source electrode; and removing the through hole mask layer, and preparing back grounding metal to complete the preparation of the diamond substrate GaN transistor device.

There is a method for forming a semiconductor nanostructure on a substrate. The method includes placing a substrate and a semiconductor material in a pulsed laser deposition chamber; selecting parameters including a fluence of a laser beam, a pressure P inside the chamber, a temperature T of the substrate, a distance d between the semiconductor material and the substrate, and a gas molecule diameter a.sub.0 of a gas to be placed inside the chamber so that conditions for a Stranski-Krastanov nucleation are created; and applying the laser beam with the selected fluence to the semiconductor material to form a plume of the semiconductor material. The selected parameters determine the formation, from the plume, of (1) a nanolayer that covers the substrate, (2) a polycrystalline wetting layer over the nanolayer, and (3) a single-crystal nanofeature over the polycrystalline wetting layer, and the single-crystal nanofeature is grown free of any catalyst or seeding layer.

The semiconductor manufacturing device includes: a lower substrate support base configured to support a diamond substrate; an upper substrate support base configured to support a semiconductor substrate; a support base drive unit configured to move the lower substrate support base and the upper substrate support base to bring the diamond substrate and the semiconductor substrate into close contact with each other under a state in which a pressure is applied to the diamond substrate and the semiconductor substrate in a thickness direction; and a second mechanism configured to deform a surface of the upper substrate support base opposed to the lower substrate support base so that a surface of the semiconductor substrate opposed to the diamond substrate forms a parallel surface or a parallel plane with respect to a surface of the diamond substrate opposed to the semiconductor substrate.

The present invention relates to methods for fabricating vertical homogenous and heterogeneous two-dimensional structures, the fabricated vertical two-dimensional structures, and methods of using the same. The methods demonstrated herein produce structures that are free standing and electrically isolated.

A method for manufacturing a diamond substrate, including: a first step of preparing patterned diamond on a foundation surface, a second 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, a third step of removing the patterned diamond prepared in the first step to form a patterned diamond composed of the diamond formed in the second step, and a fourth step of growing diamond from the patterned diamond formed in the third step to form the diamond in a pattern gap of the patterned diamond formed in the third step. There can be provided a method for manufacturing a diamond substrate which can sufficiently suppress dislocation defects, a high-quality diamond substrate, and a freestanding diamond substrate.

The present invention relates to methods for fabricating vertical homogenous and heterogeneous two-dimensional structures, the fabricated vertical two-dimensional structures, and methods of using the same. The methods demonstrated herein produce structures that are free standing and electrically isolated.

A method of growing a two-dimensional transition metal dichalcogenide (TMD) thin film and a method of manufacturing a device including the two-dimensional TMD thin film are provided. The method of growing the two-dimensional TMD thin film may include a precursor supply operation and an evacuation operation, which are periodically and repeatedly performed in a reaction chamber provided with a substrate for thin film growth. The precursor supply operation may include supplying two or more kinds of precursors of a TMD material to the reaction chamber. The evacuation operation may include evacuating the two or more kinds of precursors and by-products generated therefrom from the reaction chamber.

A semiconductor device having heterogeneous transistors integrated on a diamond substrate with a carbonized layer. An example semiconductor device generally includes a first semiconductor die and a second semiconductor die. The first semiconductor die includes a diamond substrate, a carbonized layer disposed above the diamond substrate, and a first transistor disposed above the carbonized layer, the first transistor comprising gallium nitride. The second semiconductor die is disposed above the first semiconductor die, where the second semiconductor die includes a second transistor comprising a different semiconductor material than the first transistor.

Embodiments of the disclosure relate to a method for creating a strip of electronic components. In the method, a ribbon of ceramic substrate is provided. The ceramic substrate defines a thickness of no more than 200 μm between a first outer surface and a second outer surface opposite of the first outer surface. A conductive layer is applied to at least one of the first outer surface or the second outer surface of the ceramic substrate. The ceramic substrate is then singulated into individual slabs, and the individual slabs are laminated to a strip of polymeric carrier. The polymeric carrier has a flexural rigidity less than the flexural rigidity of the ceramic substrate. Additionally, embodiments of a roll of electronic components are provided.

Provided is a single crystal diamond having a lowered dislocation density. The single crystal diamond (10) is provided with single crystal diamond layers (2, 3). One single crystal diamond layer (2) is formed on a diamond substrate (1) and contains point defects. The other single crystal diamond layer (3) is grown on the single crystal diamond layer (2). The single crystal diamond layers (2, 3) have a lower dislocation density than the diamond substrate.