Embodiments of the present disclosure generally relate to methods for forming epitaxial layers on a semiconductor device. In one or more embodiments, methods include removing oxides from a substrate surface during a cleaning process, flowing a processing reagent containing a silicon source and exposing the substrate to the processing reagent during an epitaxy process, and stopping the flow of the processing reagent. The method also includes flowing a purging gas and pumping residues from the processing system, stopping the flow of the purge gas, flowing an etching gas and exposing the substrate to the etching gas. The etching gas contains hydrogen chloride and at least one germanium and/or chlorine compound. The method further includes stopping the flow of the at least one compound while continuing the flow of the hydrogen chloride and exposing the substrate to the hydrogen chloride and stopping the flow of the hydrogen chloride.

A method includes forming a doped region on a top portion of a substrate, forming a first epitaxial layer over the substrate, forming a recess in the first epitaxial layer, the recess being aligned to the doped region, performing a surface clean treatment in the recess, the surface clean treatment includes: oxidizing surfaces of the recess to form an oxide layer in the recess, and removing the oxide layer from the surfaces of the recess, and forming a second epitaxial layer in the recess.

A method includes flowing first precursors over a semiconductor substrate to form an epitaxial region, the epitaxial region includes a first element and a second element; converting a second precursor into first radicals and first ions; separating the first radicals from the first ions; and flowing the first radicals over the epitaxial region to remove at least some of the second element from the epitaxial region.

A method includes etching a silicon layer in a wafer to form a first trench in a first device region and a second trench in a second device region, performing a pre-clean process on the silicon layer, performing a baking process on the wafer, and performing an epitaxy process to form a first silicon germanium region and a second silicon germanium region in the first trench and the second trench, respectively. The first silicon germanium region and the second silicon germanium region have a loading in a range between about 5 nm and about 30 nm.

A substrate is mounted on a rotator provided in a reaction chamber, while a first process gas containing no source gas is supplied to an upper surface of the substrate from above the substrate and the substrate is rotated at 300 rpm or more, a temperature of a wall surface is changed, and after a temperature of the substrate is allowed to rise, the substrate is controlled to a predetermined film formation temperature and a second process gas containing a source gas is supplied to the upper surface of the substrate from above the substrate to grow an SiC film on the substrate.

Provided is a method for manufacturing a semiconductor silicon wafer capable of inhibiting P-aggregation defects (Si-P defects) and SF in an epitaxial layer. The method includes a step of forming a silicon oxide film with a thickness of at least 300 nm or thicker only on the backside of the silicon wafer substrate by the CVD method at a temperature of 500° C. or lower after the step of forming the silicon oxide film, a step of heat treatment where the substrate is kept in an oxidizing atmosphere at a constant temperature of 1100° C. or higher and 1250° C. or lower for 30 minutes or longer and 120 minutes or shorter after the heat treatment, a step of removing surface oxide film formed on the front surface of the substrate, and a step of depositing a silicon monocrystalline epitaxial layer on the substrate after the step of removing the surface oxide film.

A light emitting display device includes: a light emitting element; a second transistor connected to a scan line; a first transistor which applies a current to the light emitting element; a capacitor connected to a gate electrode of the first transistor; and a third transistor connected to an output electrode of the first transistor and the gate electrode of the first transistor. Channels of the second transistor, the first transistor, and the third transistor are disposed in a polycrystalline semiconductor layer, and a width of a channel of the third transistor is in a range of about 1 .Math.m to about 2 .Math.m, and a length of the channel of the third transistor is in a range of about 1 .Math.m to about 2.5 .Math.m.

A fabrication method of a semiconductor substrate includes: performing a chemical mechanical polishing process on a silicon carbide wafer; and performing a heating process on the silicon carbide wafer to remove a naturally formed oxide layer, to remove contaminants, to obtain a scratch-free surface, and to planarize, wherein the heating process includes: heating a chamber of a furnace and the silicon carbide wafer to T degrees Celsius for a time t, and introducing hydrogen, argon, nitrogen, or/and hydrogen chloride into the chamber; and then cooling down the furnace.

A method for forming a doped layer is disclosed. The doped layer may be used in a NMOS or a silicon germanium application. The doped layer may be created using an n-type halide species in a n-type dopant application, for example.

The present document discloses a semiconductor device structure (1) comprising a SiC substrate (11), an In.sub.x1Al.sub.y1Ga.sub.1−x1−y1N buffer layer (13), wherein x1=0−1, y1=0−1 and x1+y1=1, and an In.sub.x2Al.sub.y2Ga.sub.1−x2−y2N nucleation layer (12), wherein x2=0−1, y2=0−1 and x2+y2=1, sandwiched between the SiC substrate (11) and the buffer layer (13). The buffer layer (13) presents a rocking curve with a (102) peak having a FWHM below 250 arcsec, and the nucleation layer (12) presents a rocking curve with a (105) peak having a FWHM below 200 arcsec, as determined by X-ray Diffraction (XRD).

Methods of making such a semiconductor device structure are disclosed.