Metal gate formation methods are disclosed herein for providing metal gates with low work function to enhance semiconductor field effect transistor performance. An exemplary method includes forming a gate dielectric layer on a substrate and a barrier layer over the gate dielectric layer. An outer surface of the barrier layer is treated to increase its roughness. After the outer surface of the barrier layer is roughened, a metal layer is deposited over the barrier layer.

A process of forming a nitride semiconductor device is disclosed. The process first deposits a silicon nitride (SiN) film on a semiconductor layer by the lower pressure chemical vapor deposition (LPCVD) technique at a temperature, then, forming an opening in the SiN film for an ohmic electrode. Preparing a photoresist on the SiN film, where the photoresist provides an opening that fully covers the opening in the SiN film, the process exposes a peripheral area around the opening of the SiN film to chlorine (Cl) plasma that may etch the semiconductor layer to form a recess therein. Metals for the ohmic electrode are filled within the recess in the semiconductor layer and the peripheral area of the SiN film. Finally, the metals are alloyed at a temperature lower than the deposition temperature of the SiN film.

A display includes a substrate with a plurality of electronic control elements, an array of light-emitting diodes having a semiconductor layer, a plurality of light emitting units disposed on the semiconductor layer, and a plurality of first electrodes disposed on the semiconductor layer, an bonding layer disposed between the substrate and the array of light-emitting diodes, and a plurality of wavelength conversion elements disposed on the semiconductor layer and spaced apart from each other. The plurality of wavelength conversion elements and the plurality of light emitting units are disposed at different sides of the semiconductor layer. The plurality of wavelength conversion elements is arranged in positions corresponding to the plurality of light-emitting units.

A method is provided. In the method, a substrate having a first region and a second region on a substrate surface is provided. A film deposition material to form a first chemical bond in the first region and a second chemical bond in the second region is supplied to the substrate surface. The second bond has a second bond energy lower than a first bond energy of the first chemical bond. A film is selectively formed in the first region by supplying an energy lower than the first bond energy of the first chemical bond and higher than the second bond energy of the second chemical bond.

Systems and methods for forming semiconductor layers, including oxide-based layers, are disclosed in which a material deposition system has a rotation mechanism that rotates a substrate around a center axis of a substrate deposition plane of the substrate. A material source that supplies a material to the substrate has i) an exit aperture with an exit aperture plane and ii) a predetermined material ejection spatial distribution from the exit aperture plane. The exit aperture is positioned at an orthogonal distance, a lateral distance, and a tilt angle relative to the center axis of the substrate. The system can be configured for either i) minimum values for the orthogonal distance and the lateral distance to achieve a desired layer deposition uniformity using a set tilt angle, or ii) the tilt angle to achieve the desired layer deposition uniformity using a set orthogonal distance and a set lateral distance.

Systems and methods for forming semiconductor layers, including oxide-based layers, are disclosed in which a material deposition system has a rotation mechanism that rotates a substrate around a center axis of a substrate deposition plane of the substrate. A material source that supplies a material to the substrate has i) an exit aperture with an exit aperture plane and ii) a predetermined material ejection spatial distribution from the exit aperture plane. The exit aperture is positioned at an orthogonal distance, a lateral distance, and a tilt angle relative to the center axis of the substrate. The system can be configured for either i) minimum values for the orthogonal distance and the lateral distance to achieve a desired layer deposition uniformity using a set tilt angle, or ii) the tilt angle to achieve the desired layer deposition uniformity using a set orthogonal distance and a set lateral distance.

Systems and methods for forming semiconductor layers, including oxide-based layers, are disclosed in which a material deposition system has a rotation mechanism that rotates a substrate around a center axis of a substrate deposition plane of the substrate. A material source that supplies a material to the substrate has i) an exit aperture with an exit aperture plane and ii) a predetermined material ejection spatial distribution from the exit aperture plane. The exit aperture is positioned at an orthogonal distance, a lateral distance, and a tilt angle relative to the center axis of the substrate. The system can be configured for either i) minimum values for the orthogonal distance and the lateral distance to achieve a desired layer deposition uniformity using a set tilt angle, or ii) the tilt angle to achieve the desired layer deposition uniformity using a set orthogonal distance and a set lateral distance.

To improve field-effect mobility and reliability of a transistor including an oxide semiconductor film. Provided is a semiconductor device including an oxide semiconductor film. The semiconductor device includes a first insulating film, the oxide semiconductor film over the first insulating film, a second insulating film and a third insulating film over the oxide semiconductor film, and a gate electrode over the second insulating film. The oxide semiconductor film includes a first oxide semiconductor film, a second oxide semiconductor film over the first oxide semiconductor film, and a third oxide semiconductor film over the second oxide semiconductor film. The first to third oxide semiconductor films contain the same element. The second oxide semiconductor film includes a region where the crystallinity is lower than the crystallinity of one or both of the first oxide semiconductor film and the third oxide semiconductor film.

There is provided a technique that includes: forming an initial oxide layer on a surface of a substrate by performing a set m times (where m is an integer equal to or greater than 1), the set including non-simultaneously performing: (a) oxidizing the surface of the substrate under a condition that an oxidation amount of the substrate increases from an upstream side to a downstream side of a gas flow by supplying an oxygen-containing gas and a hydrogen-containing gas to the substrate; and (b) oxidizing the surface of the substrate under a condition that the oxidation amount of the substrate decreases from the upstream side to the downstream side of the gas flow by supplying the oxygen-containing gas and the hydrogen-containing gas to the substrate; and forming a film on the initial oxide layer by supplying a precursor gas to the substrate.

A semiconductor device includes a semiconductor substrate, a source/drain region, a source/drain contact, a conductive via and a first polymer layer. The source/drain region is in the semiconductor substrate. The source/drain contact is over the source/drain region. The source/drain via is over the source/drain contact. The first polymer layer extends along a first sidewall of the conductive via and is separated from a second sidewall of the conductive via substantially perpendicular to the first sidewall of the conductive via.