A semiconductor device that includes a semiconductor substrate having a first main surface and a second main surface opposed to each other, and a porous metal oxide film on a side of the first main surface of the semiconductor substrate, the porous metal oxide film having a plurality of pores. The semiconductor substrate has a connection electrically connected to the porous metal oxide film, and the semiconductor substrate is configured to provide a power supply path from the second main surface to the connection on the first main surface.

Embodiments of the present application relate to a method for manufacturing a semiconductor structure, includes: forming a contact metal layer on a silicon substrate; performing a plasma treatment process, and forming an oxygen isolation layer on a surface of the contact metal layer; and performing a silicidation reaction process, and converting the contact metal layer into a metal silicide layer.

A method for manufacturing a semiconductor memory includes: providing a portion to be processed, and performing a preset process step on the portion to be processed at least after a minimum waiting time; before performing the preset process step, performing a thermal oxidation process on the portion to be processed; and before performing the preset process step, performing a cleaning process, the cleaning process being used to remove oxides from the surface of the portion to be processed, the oxides being wholly or partly generated by the thermal oxidation process.

A plasma processing apparatus includes a plasma chamber that accommodates a substrate having a film including a side wall surface and a bottom surface that define an opening; and a controller that controls a process on the substrate in the plasma chamber. The controller includes a sequencer that performs a sequence including forming a precursor layer on the opening of the film; and generating a plasma to form a protective film on the side wall surface of the opening of the film from the precursor layer and to etch the bottom surface of the opening of the film. The controller simultaneously forms the protective film on the side wall surface of the opening of the film and etches the bottom surface of the opening of the film.

A method for fabricating a semiconductor device includes forming a stack structure including a horizontal recess over a substrate, forming a blocking layer lining the horizontal recess, forming an interface control layer including a dielectric barrier element and a conductive barrier element over the blocking layer, and forming a conductive layer over the interface control layer to fill the horizontal recess.

Passivated semiconductor nanoparticles and methods for the fabrication and use of passivated semiconductor nanoparticles is provided herein.

Disclosed are a thin-film transistor and a preparation method therefor, and a display substrate and a display panel. The thin-film transistor includes: a base substrate; an active layer located on the base substrate; and a source-drain electrode which is located on the side of the active layer facing away from the base substrate, and includes an electrode layer and a protective layer, where the material of the electrode layer includes a first metal element; the protective layer covers the surface of the side of the electrode layer facing away from the base substrate, and a side face of the electrode layer; and the material of the protective layer is an oxide of the first metal element.

A method for dielectric filling of a feature on a substrate yields a seamless dielectric fill with high-k for narrow features. In some embodiments, the method may include depositing a metal material into the feature to fill the feature from a bottom of the feature wherein the feature has an opening ranging from less than 20 nm to approximately 150 nm at an upper surface of the substrate and wherein depositing the metal material is performed using a high ionization physical vapor deposition (PVD) process to form a seamless metal gap fill and treating the seamless metal gap fill by oxidizing/nitridizing the metal material of the seamless metal gap fill with an oxidation/nitridation process to form dielectric material wherein the seamless metal gap fill is converted into a seamless dielectric gap fill with high-k dielectric material.

Processing methods described herein comprise forming a metal gate film on a narrow feature and a wide feature and depositing a hard mask on the metal gate film. The hard mask forms on the metal gate film at a top, bottom and sidewalls of the wide feature and on a top of the narrow feature to cover the metal gate film. Some processing methods comprise oxidizing the metal gate film on the narrow feature to convert a portion of the metal gate film to a metal oxide film. Some processing methods comprise etching the metal oxide film from the narrow feature to leave a gradient etch profile. Some processing methods comprise filling the narrow feature and the wide feature with a gap fill material comprising one or more of a metal nitride, titanium nitride (TiN) or titanium oxynitride (TiON), the gap fill material substantially free of seams and voids.

A semiconductor structure having metal contact features and a method for forming the same are provided. The method includes forming a dielectric layer covering an epitaxial structure over a semiconductor substrate and forming an opening in the dielectric layer to expose the epitaxial structure. The method includes forming a metal-containing layer over the dielectric layer and the epitaxial structure. The method includes heating the epitaxial structure and the metal-containing layer to transform a first portion of the metal-containing layer contacting the epitaxial structure into a metal-semiconductor compound layer. The method includes oxidizing the metal-containing layer to transform a second portion of the metal-containing layer over the metal-semiconductor compound layer into a metal oxide layer. The method includes applying a metal chloride-containing etching gas on the metal oxide layer to remove the metal oxide layer and forming a metal contact feature over the metal-semiconductor compound layer.