The disclosure provides a film forming method that enables to obtain an epitaxial film with reduced defects such as dislocations due to a reduced facet growth industrially advantageously, even if the epitaxial film has a corundum structure. When forming an epitaxial film on a crystal-growth surface of a corundum-structured crystal substrate directly or via another layer, using the crystal substrate having an uneven portion on the crystal-growth surface of the crystal substrate, generating and floating atomized droplets by atomizing a raw material solution including a metal; carrying the floated atomized droplets onto a surface of the crystal substrate by using a carrier gas; and causing a thermal reaction of the atomized droplets in a condition of a supply rate limiting state.

In a method for semiconductor processing, a semiconductor substrate is provided. The semiconductor substrate defines at least one first trench therein. The at least one first trench has a first depth (d.sub.1). A coating layer is deposited onto the semiconductor substrate using at least one precursor under a setting for a processing temperature (T). The coating layer defines at least one second trench having a second depth (d.sub.2) above the at least one first trench. A first depth parameter (t) of the second depth (d.sub.2) relative to the first depth (d.sub.1) is determined. The processing temperature (T) is then determined based on the first depth parameter (t).

In a method for semiconductor processing, a semiconductor substrate is provided. The semiconductor substrate defines at least one first trench therein. The at least one first trench has a first depth (d.sub.1). A coating layer is deposited onto the semiconductor substrate using at least one precursor under a setting for a processing temperature (T). The coating layer defines at least one second trench having a second depth (d.sub.2) above the at least one first trench. A first depth parameter (t) of the second depth (d.sub.2) relative to the first depth (d.sub.1) is determined. The processing temperature (T) is then determined based on the first depth parameter (t).

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.

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.

A system for manufacturing one or more single crystals of a semiconductor material by physical vapor transport (PVT) includes a reactor having an inner chamber adapted to accommodate a PVT growth structure for growing the one or more single crystals inside. The reactor accommodates the PVT growth structure in an orientation with a growth direction of the one or more single crystals inside the PVT growth structure substantially horizontal with respect to a direction of gravity or within an angle from horizontal of less than a predetermined value.

A system for manufacturing one or more single crystals of a semiconductor material by physical vapor transport (PVT) includes a reactor having an inner chamber adapted to accommodate a PVT growth structure for growing the one or more single crystals inside. The reactor accommodates the PVT growth structure in an orientation with a growth direction of the one or more single crystals inside the PVT growth structure substantially horizontal with respect to a direction of gravity or within an angle from horizontal of less than a predetermined value.

The treating arrangement (900) for an epitaxial reactor (1000) comprises: a reaction chamber (100) for treating substrates, a transfer chamber (200) adjacent to the reaction chamber (100), for transferring substrates placed over substrates support devices, a loading/unloading group (300) at least in part adjacent to the transfer chamber (200), arranged to contain a substrates support device with one or more substrates, a loading/unloading chamber (400) at least in part adjacent to the loading/unloading group (300), having a first storage zone (410) for treated and/or untreated substrates and a second storage zone (420) for substrates support devices without any substrate, at least one external robot (500) for transferring treated substrates, untreated substrates and substrates support devices without any substrate between said loading/unloading chamber (400) and said loading/unloading group (300), at least one internal robot (600) for transferring substrates support devices with one or more substrates between said loading/unloading group (300) and said reaction chamber (100) via said transfer chamber (200); wherein said external robot (500) comprises an articulated arm (510) arranged to handle both treated substrates and untreated substrates as well as substrates support devices.

The treating arrangement (900) for an epitaxial reactor (1000) comprises: a reaction chamber (100) for treating substrates, a transfer chamber (200) adjacent to the reaction chamber (100), for transferring substrates placed over substrates support devices, a loading/unloading group (300) at least in part adjacent to the transfer chamber (200), arranged to contain a substrates support device with one or more substrates, a loading/unloading chamber (400) at least in part adjacent to the loading/unloading group (300), having a first storage zone (410) for treated and/or untreated substrates and a second storage zone (420) for substrates support devices without any substrate, at least one external robot (500) for transferring treated substrates, untreated substrates and substrates support devices without any substrate between said loading/unloading chamber (400) and said loading/unloading group (300), at least one internal robot (600) for transferring substrates support devices with one or more substrates between said loading/unloading group (300) and said reaction chamber (100) via said transfer chamber (200); wherein said external robot (500) comprises an articulated arm (510) arranged to handle both treated substrates and untreated substrates as well as substrates support devices.

An analysis method of crystal growth conditions includes a step of calculating an evaluation function on the basis of results obtained by measuring crystals grown under varied crystal growth conditions, a step of performing machine learning of the evaluation function, and a step of obtaining optimum crystal growth conditions from a result of the machine learning, wherein the evaluation function is based on a difference between crystal quality data of an ideal crystal and crystal quality data of the crystal having been grown.