A substrate processing apparatus includes a process chamber, and a turntable provided in the process chamber and including a substrate holding region formed in a top surface along a circumferential direction of the turntable. A surface area increasing region is provided in the top surface of the turntable around the substrate holding region and is configured to increase a surface area of the top surface of the turntable to an area larger than a surface area of a flat surface by including a concavo-convex pattern in its top surface. A process gas supply unit is configured to supply a process gas to the top surface of the turntable.

Apparatus, methods, and computer programs for semiconductor processing in a capacitively-coupled plasma chamber are provided. A chamber includes a bottom radio frequency (RF) signal generator, a top RF signal generator, and an RF phase controller. The bottom RF signal generator is coupled to the bottom electrode in the chamber, and the top RF signal generator is coupled to the top electrode. Further, the bottom RF signal is set at a first phase, and the top RF signal is set at a second phase. The RF phase controller is operable to receive the bottom RF signal and operable to set the value of the second phase. Additionally, the RF phase controller is operable to track the first phase and the second phase to maintain a time difference between the maximum of the top RF signal and the minimum of the bottom RF signal at approximately a predetermined constant value, resulting in an increase of the negative ion flux to the surface of the wafer.

A plasma processing apparatus and method with an improved processing yield, the plasma processing apparatus including detector configured to detect an intensity of a first light of a plurality of wavelengths in a first wavelength range and an intensity of a second light of a plurality of wavelengths in a second wavelength range, the first light being obtained by receiving a light which is emitted into the processing chamber from a light source disposed outside the processing chamber and which is reflected by an upper surface of the wafer, and the second light being a light transmitted from the light source without passing through the processing chamber; and a determination unit configured to determine a remaining film thickness of the film layer by comparing the intensity of the first light corrected using a change rate of the intensity of the second light.

A sensor system includes a processing chamber and a sensor assembly disposed within the processing chamber. The sensor assembly includes a substrate and a plurality of sensors including at least one of pressure sensors or flow sensors disposed across a surface of the substrate. Each respective sensor is adapted to measure a respective pressure or a respective flow of an environment proximate the respective sensor. The sensor system further includes a processing device communicatively coupled to the sensor assembly. The processing device is adapted to receive at least one of the measured respective pressures or the measured respective flows and determine a pressure distribution or a flow distribution of the processing chamber.

A semiconductor manufacturing device comprising a support unit in a chamber. A showerhead disposed between first and second plasma regions. First and second gas supply units injecting first and second process gases, respectively, into the second plasma region through the showerhead. The showerhead includes plasma penetration portions passing a portion of the plasma generated in the first plasma region therethrough. First gas flow paths injecting the first process gas into a first zone of the showerhead. Second gas flow paths injecting the second process gas into a second zone of the showerhead that surrounds the first zone. First and second cavities connected to the first and second gas flow paths, respectively. The first and second cavities diffusing the first and second process gases, respectively. First and second gas spraying holes connected to the first and second cavities, respectively, and facing the second plasma region.

Embodiments of the present disclosure include an apparatus and methods for the plasma processing of a substrate. Some embodiments are directed to a plasma processing chamber. The plasma processing chamber generally includes a planar coil region comprising a concentric coil region comprising a first concentric coil and a second concentric coil, and a power supply circuit coupled to the first concentric coil and the second concentric coil. The first concentric coil may include a first coil with a diameter measured in a direction parallel to a first plane that is smaller than the diameter of a second coil included in the second concentric coil. The power supply circuit may be configured to bias the first concentric coil and the second concentric coil to adjust a generated magnetic field in a region of control of a plasma in the plasma processing chamber to control a plasma density of the plasma.

A method MT includes etching a wafer W using plasma generated in a processing container. The etching includes a process of inclining and rotating a holding structure holding the wafer W during execution of the etching and the process successively creating a plurality of inclined rotation states RT(?, t) with respect to the holding structure. In the inclined rotation states, the wafer W is rotated about a central axis of the wafer W over a predetermined process time while maintaining a state where the central axis is inclined with respect to a reference axis of the processing container which is in the same plane as the central axis. A combination of a value ? of an inclination angle AN of the central axis with respect to the reference axis and the process time t differs for each of the plurality of inclined rotation states.

A device and method of spreading plasma which allows for plasma etching over a larger range of process chamber pressures. A plasma source, such as a linear inductive plasma source, may be choked to alter back pressure within the plasma source. The plasma may then be spread around a deflecting disc which spreads the plasma under a dome which then allows for very even plasma etch rates across the surface of a substrate. The apparatus may include a linear inductive plasma source above a plasma spreading portion which spreads plasma across a horizontally configured wafer or other substrate. The substrate support may include heating elements adapted to enhance the etching.

A plasma processing apparatus 1 includes a chamber 10, a mounting table 16, a focus ring 24a, a first electrode plate 36 and a second electrode plate 35. The focus ring 24a is provided around the mounting table 16 to surround a mounting surface of the mounting table 16. The first electrode plate 36 is provided above the mounting table 16. The second electrode plate 35 is provided around the first electrode plate 36 to surround the first electrode plate 36 and is insulated from the first electrode plate 36. The plasma processing apparatus 1, in a first process, performs a preset processing on a semiconductor wafer W mounted on the mounting surface with plasma generated within the chamber, and, in a second process, increases an absolute value of a negative DC voltage applied to the second electrode plate 35 depending on an elapsed time of the first process.

Exemplary processing methods may include providing a silicon-containing precursor to a processing region of a semiconductor processing chamber. A substrate may be housed in the processing region. The substrate may define a feature within the substrate. The methods may include forming plasma effluents of the silicon-containing precursor. The methods may include depositing a silicon-containing material on the substrate. The methods may include providing a hydrogen-containing precursor to the processing region of the semiconductor processing chamber. The methods may include forming plasma effluents of the hydrogen-containing precursor. The methods may include etching the silicon-containing material from a sidewall of the feature within the substrate with the plasma effluents of the hydrogen-containing precursor. The methods may include densifying remaining silicon-containing material within the feature defined within the substrate.