Embodiments provide a way of treating source/drain recesses with a high heat treatment and an optional hydrogen plasma treatment. The high heat treatment smooths the surfaces inside the recesses and remove oxides and etching byproducts. The hydrogen plasma treatment enlarges the recesses vertically and horizontally and inhibits further oxidation of the surfaces in the recesses.

A semiconductor device includes a semiconductor fin, a gate structure, a doped semiconductor layer, and a dielectric structure. The semiconductor fin has a top portion and a lower portion extending from the top portion to a substrate. The gate structure extends across the semiconductor fin. The doped semiconductor layer interfaces the top portion of the semiconductor fin. In a cross-section taken along a lengthwise direction of the gate structure, the doped semiconductor layer has an outer profile conformal to a profile of the top portion of the semiconductor fin.

Implementations of the present disclosure generally relates to a transfer chamber coupled to at least one vapor phase epitaxy chamber a plasma oxide removal chamber coupled to the transfer chamber, the plasma oxide removal chamber comprising a lid assembly with a mixing chamber and a gas distributor; a first gas inlet formed through a portion of the lid assembly and in fluid communication with the mixing chamber; a second gas inlet formed through a portion of the lid assembly and in fluid communication with the mixing chamber; a third gas inlet formed through a portion of the lid assembly and in fluid communication with the mixing chamber; and a substrate support with a substrate supporting surface; a lift member disposed in a recess of the substrate supporting surface and coupled through the substrate support to a lift actuator; and a load lock chamber coupled to the transfer chamber.

Described herein is a method for growing indium nitride (InN) materials by growing hexagonal InN using a pulsed growth method at a temperature lower than 300° C.

Described herein is a method for growing indium nitride (InN) materials by growing hexagonal and/or cubic InN using a pulsed growth method at a temperature lower than 300° C. Also described is a material comprising InN in a face-centered cubic lattice crystalline structure having an NaCl type phase.

A semiconductor device including a cap layer and a method for forming the same are disclosed. In an embodiment, a method includes epitaxially growing a first semiconductor layer over an N-well; etching the first semiconductor layer to form a first recess; epitaxially growing a second semiconductor layer filling the first recess; etching the second semiconductor layer, the first semiconductor layer, and the N-well to form a first fin; forming a shallow trench isolation region adjacent the first fin; and forming a cap layer over the first fin, the cap layer contacting the second semiconductor layer, forming the cap layer including performing a pre-clean process to remove a native oxide from exposed surfaces of the second semiconductor layer; performing a sublimation process to produce a first precursor; and performing a deposition process wherein material from the first precursor is deposited on the second semiconductor layer to form the cap layer.

The present invention addresses the problem of providing a novel SiC substrate production method. The SiC substrate production method according to the present invention comprises an etching step S10 of etching a SiC base substrate 10, a crystal growth step S20 of growing a SiC substrate layer 13 on the SiC base substrate 10 to produce a SiC substrate body 20, and a peeling step S30 of peeling at least a portion of the SiC substrate body 20 to produce a SiC substrate 30, the method being characterized in that each of the etching step S10 and the crystal growth step S20 is a step of arranging the SiC base substrate 10 and a SiC material 40 so as to face each other and heating the SiC base substrate 10 and the SiC material 40 so as to form a temperature gradient between the SiC base substrate 10 and the SiC material 40.

A substrate is provided with a monocrystalline silicon-germanium layer with a first surface covered by a protective oxide obtained by wet process and having a degradation temperature. The protective oxide is transformed into fluorinated salt which is then eliminated. The substrate is placed in a processing chamber at a lower temperature than the degradation temperature and is subjected to a temperature ramp up to a higher temperature than the degradation temperature. The first surface is annealed in a hydrogen atmosphere devoid of silicon, germanium and precursors of the materials forming the target layer. When the temperature ramp is applied, a silicon precursor is inserted in the processing chamber between a loading temperature and the degradation temperature to deposit a monocrystalline buffer layer. A mono-crystalline target layer is deposited by chemical vapour deposition.

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 for growing a semi-polar gallium nitride epitaxial layer by inserting aluminum nitride and gallium nitride multi-layers includes the steps of cleaning m-sapphire substrates and activating the m-sapphire substrates by utilizing a combination of precursors and carrier gas. The method of growing a layer of semi-polar gallium nitride epitaxial layer on m-sapphire substrates further includes nitridating for initiating growth sequence and depositing a nucleation layer. The film stack of aluminum nitride and gallium nitride multi-layers is grown to initiate growth of a super lattice layer on m-plane sapphire substrates. Subsequently, a layer of the undoped gallium nitride is deposited on the m-plane sapphire substrate.