A plasma processing apparatus includes: a reaction tube provided in a processing container; a boat that holds a substrate, and is carried into and out from the reaction tube in order to form a film on the substrate; a plasma generation tube that communicates with the reaction tube, and generates plasma from a gas; a gas supply that supplies the gas to the plasma generation tube; electrode installation columns provided to sandwich the plasma generation tube therebetween, and including electrodes, respectively; an RF power supply that is connected to the electrodes, and supplies a radio frequency to the electrodes; a coil provided to be spaced apart from the electrodes in the electrode installation columns; and a DC power supply that is connected to the coil, and supplies a direct current to the coil.

A plasma processing apparatus includes: a reaction tube provided in a processing container; a boat that holds a substrate, and is carried into and out from the reaction tube in order to form a film on the substrate; a plasma generation tube that communicates with the reaction tube, and generates plasma from a gas; a gas supply that supplies the gas to the plasma generation tube; electrode installation columns provided to sandwich the plasma generation tube therebetween, and including electrodes, respectively; an RF power supply that is connected to the electrodes, and supplies a radio frequency to the electrodes; a coil provided to be spaced apart from the electrodes in the electrode installation columns; and a DC power supply that is connected to the coil, and supplies a direct current to the coil.

A film-forming apparatus for forming a predetermined film on a substrate by plasma ALD includes a chamber, a stage, a shower head having an upper electrode and a shower plate insulated from the upper electrode, a first high-frequency power supply connected to the upper electrode, and a second high-frequency power supply connected to an electrode contained in the stage. A high-frequency power is supplied from the first high-frequency power supply to the upper electrode, thereby forming a high-frequency electric field between the upper electrode and the shower plate and generating a first capacitively coupled plasma. A high-frequency power is supplied from the second high-frequency power supply to the electrode, thereby forming a high-frequency electric field between the shower plate and the electrode in the stage and generating a second capacitively coupled plasma that is independent from the first capacitively coupled plasma.

A film-forming apparatus for forming a predetermined film on a substrate by plasma ALD includes a chamber, a stage, a shower head having an upper electrode and a shower plate insulated from the upper electrode, a first high-frequency power supply connected to the upper electrode, and a second high-frequency power supply connected to an electrode contained in the stage. A high-frequency power is supplied from the first high-frequency power supply to the upper electrode, thereby forming a high-frequency electric field between the upper electrode and the shower plate and generating a first capacitively coupled plasma. A high-frequency power is supplied from the second high-frequency power supply to the electrode, thereby forming a high-frequency electric field between the shower plate and the electrode in the stage and generating a second capacitively coupled plasma that is independent from the first capacitively coupled plasma.

Methods and systems for forming a structure including a silicon carbide layer and structures formed using the methods and systems are disclosed. Exemplary methods include providing a silicon carbide precursor to the reaction chamber, forming a plasma within the reaction chamber to form an initially flowable, viscous silicon carbide material on a surface of the substrate, wherein the initially viscous carbon material becomes the silicon carbide layer. Exemplary methods can include use of a silicon carbide precursor that includes a carbon-carbon triple bond and/or use of a relatively low plasma power density (e.g., less than 3 W/cm.sup.2).

Embodiments described herein provide magnetic and electromagnetic housing systems and a method for controlling the properties of plasma generated in a process volume of a process chamber to affect deposition properties of a film. In one embodiment, the method includes rotation of the rotational magnetic housing about a center axis of the process volume to create dynamic magnetic fields. The magnetic fields modify the shape of the plasma, concentration of ions and radicals, and movement of concentration of ions and radicals to control the density profile of the plasma. Controlling the density profile of the plasma tunes the uniformity and properties of a deposited or etched film.

Embodiments described herein provide magnetic and electromagnetic housing systems and a method for controlling the properties of plasma generated in a process volume of a process chamber to affect deposition properties of a film. In one embodiment, the method includes rotation of the rotational magnetic housing about a center axis of the process volume to create dynamic magnetic fields. The magnetic fields modify the shape of the plasma, concentration of ions and radicals, and movement of concentration of ions and radicals to control the density profile of the plasma. Controlling the density profile of the plasma tunes the uniformity and properties of a deposited or etched film.

Provided by the invention disclosure is a coating equipment. The coating equipment comprises a reaction chamber body provided with a reaction chamber, a gas supply part configured to supply gas to the reaction chamber, a pumping device configured to communicate with the reaction chamber, a pulse power supply adapted to provide the reaction chamber body with a pulsed electric field and a radio frequency power supply adapted to provide the reaction chamber body with a radio frequency electric field, wherein the reaction chamber is adapted to accommodate a plurality of workpiece. When the pulse power supply and the radio frequency power supply are turned on, the gas in the reaction chamber body is ionized under the radio frequency electric field and the pulsed electric field to generate plasma, and the plasma is deposited on the surface of the workpieces.

Provided by the invention disclosure is a coating equipment. The coating equipment comprises a reaction chamber body provided with a reaction chamber, a gas supply part configured to supply gas to the reaction chamber, a pumping device configured to communicate with the reaction chamber, a pulse power supply adapted to provide the reaction chamber body with a pulsed electric field and a radio frequency power supply adapted to provide the reaction chamber body with a radio frequency electric field, wherein the reaction chamber is adapted to accommodate a plurality of workpiece. When the pulse power supply and the radio frequency power supply are turned on, the gas in the reaction chamber body is ionized under the radio frequency electric field and the pulsed electric field to generate plasma, and the plasma is deposited on the surface of the workpieces.

Exemplary semiconductor processing chambers may include a chamber body. The chambers may include a substrate support disposed within the chamber body. The substrate support may define a substrate support surface. The chambers may include a showerhead positioned supported atop the chamber body. The substrate support and a bottom surface of the showerhead may at least partially define a processing region within the semiconductor processing chamber. The showerhead may define a plurality of apertures through the showerhead. The bottom surface of the showerhead may define an annular groove or ridge that is positioned directly above at least a portion of the substrate support.