A method of manufacturing a semiconductor device includes forming an active fin extending longitudinally in a first direction along a surface of a substrate, forming a field insulating layer on the substrate, the field insulating layer covering a part of the active fin, forming a dummy gate electrode on the field insulating layer and the active fin, the dummy gate electrode extending in a second direction different from the first direction, forming a spacer on the sides of the dummy gate electrode, and removing the dummy gate electrode by a wet etching process that includes rinsing the dummy gate electrode intermittently during an etching away of the dummy gate electrode.

According to various embodiments, a method for processing a semiconductor region, wherein the semiconductor region comprises at least one precipitate, may include: forming a precipitate removal layer over the semiconductor region, wherein the precipitate removal layer may define an absorption temperature at which a chemical solubility of a constituent of the at least one precipitate is greater in the precipitate removal layer than in the semiconductor region; and heating the at least one precipitate above the absorption temperature.

A cleaning agent is provided for a semiconductor substrate superior in corrosion resistance of a tungsten wiring or a tungsten alloy wiring, and superior in removal property of polishing fines (particle) such as silica or alumina, remaining at surface of the semiconductor substrate, in particular, at surface of a silicon oxide film such as a TEOS film, after a chemical mechanical polishing process; and a method for processing a semiconductor substrate surface. A cleaning agent for a semiconductor substrate is to be used in a post process of a chemical mechanical polishing process of the semiconductor substrate having a tungsten wiring or a tungsten alloy wiring, and a silicon oxide film, comprising (A) a phosphonic acid-based chelating agent, (B) a primary or secondary monoamine having at least one alkyl group or hydroxyalkyl group in a molecule and (C) water, wherein a pH is over 6 and below 7.

A substrate processing apparatus includes a rotation driving mechanism configured to rotate a rotary table configured to hold a substrate; an electric heater provided in the rotary table to be rotated along with the rotary table and configured to heat the substrate; a power receiving electrode provided in the rotary table to be rotated along with the rotary table and electrically connected to the electric heater; a power feeding electrode configured to be contacted with the power receiving electrode and configured to supply a power to the electric heater via the power receiving electrode; an electrode moving mechanism; a power feeder configured to supply the power to the power feeding electrode; a processing cup surrounding the rotary table; at least one processing liquid nozzle configured to supply a processing liquid; a processing liquid supply mechanism configured to supply at least an electroless plating liquid; and a controller.

Methods for removing contamination from a surface disposed in a substrate processing system are provided herein. In some embodiments, a method for removing contaminants from a surface includes: providing a first process gas comprising a chlorine containing gas, a hydrogen containing gas, and an inert gas to a process chamber having the surface disposed within the process chamber; igniting the first process gas to form a plasma from the first process gas; and exposing the surface to the plasma to remove contaminants from the surface. In some embodiments, the surface is an exposed surface of a process chamber component. In some embodiments, the surface is a surface of a first layer disposed atop a substrate, such as a semiconductor wafer.

The present application discloses a method for fabricating a semiconductor device. The method for fabricating a semiconductor device includes providing a substrate, forming a pad structure above the substrate, and forming a top groove on a top surface of the pad structure.

A cleaner composition consisting essentially of (A) 90.0-99.9 wt % of an organic solvent and (B) 0.1-10.0 wt % of a C.sub.3-C.sub.6 alcohol, and containing (C) 20-300 ppm of sodium and/or potassium is effective for cleaning a surface of a silicon semiconductor substrate. A satisfactory degree of cleanness is achieved within a short time and at a high efficiency without causing corrosion to the substrate.

A semiconductor device includes semiconductor nanostructures disposed over a substrate, a source/drain epitaxial layer in contact with the semiconductor nanostructures, a gate dielectric layer disposed on and wrapping around each channel region of the semiconductor nanostructures, a gate electrode layer disposed on the gate dielectric layer and wrapping around each channel region, and insulating spacers disposed in spaces, respectively. The spaces are defined by adjacent semiconductor nanostructures, the gate electrode layer and the source/drain region. The source/drain epitaxial layer includes multiple doped SiGe layers having different Ge contents and at least one of the source/drain epitaxial layers is non-doped SiGe or Si.

Embodiments of the invention provide self-assembled monolayers (SAM) formulations and cleaning to promote quick depositions. A hydrogen-based plasma clean is performed on a structure, the structure including a metal layer and a dielectric layer. A self-assembled monolayers (SAM) solution is dispensed on the structure, the SAM solution including SAMs and a solvent, the SAMs being configured to assemble on the metal layer. The structure is rinsed with a rinse solution including the solvent.

In accordance with some embodiments, conductive material is removed from over a first plurality of fins and second plurality of fins, wherein the first plurality of fins is located within a small gate length region and the second plurality of fins is located in a large gate length region. The removal is performed by initially performed a dry etch with a low pressure and a high flow rate of at least one etchant, which causes the conductive material to have a larger thickness over the second plurality of fins than over the first plurality of fins. As such, when a wet etch is utilized to remove a remainder of the conductive material, dielectric material between the second plurality of fins and the conductive material is not damaged.