Abstract: Methods for depositing a dielectric material using RF bias pulses along with remote plasma source deposition for manufacturing semiconductor devices, particularly for filling openings with high aspect ratios in semiconductor applications are provided. For example, a method of depositing a dielectric material includes providing a gas mixture into a processing chamber having a substrate disposed therein, forming a remote plasma in a remote plasma source and delivering the remote plasma to an interior processing region defined in the processing chamber, applying a RF bias power to the processing chamber in pulsed mode, and forming a dielectric material in an opening defined in a material layer disposed on the substrate in the presence of the gas mixture and the remote plasma.

Abstract: Embodiments of process kit shields and process chambers incorporating same are provided herein. In some embodiments a process kit configured for use in a process chamber for processing a substrate includes a shield having a cylindrical body having an upper portion and a lower portion; an adapter section configured to be supported on walls of the process chamber and having a resting surface to support the shield; and a heater coupled to the adapter section and configured to be electrically coupled to at least one power source of the processes chamber to heat the shield.

Abstract: Embodiments of the present invention provide an apparatus and methods for depositing a dielectric material using RF bias pulses along with remote plasma source deposition for manufacturing semiconductor devices, particularly for filling openings with high aspect ratios in semiconductor applications. In one embodiment, a method of depositing a dielectric material includes providing a gas mixture into a processing chamber having a substrate disposed therein, forming a remote plasma in a remote plasma source and delivering the remote plasma to an interior processing region defined in the processing chamber, applying a RF bias power to the processing chamber in pulsed mode, and forming a dielectric material in an opening defined in a material layer disposed on the substrate in the presence of the gas mixture and the remote plasma.

Abstract: Embodiments of the present invention provide an apparatus and methods for depositing a dielectric material using RF bias pulses along with remote plasma source deposition for manufacturing semiconductor devices, particularly for filling openings with high aspect ratios in semiconductor applications. In one embodiment, a method of depositing a dielectric material includes providing a gas mixture into a processing chamber having a substrate disposed therein, forming a remote plasma in a remote plasma source and delivering the remote plasma to an interior processing region defined in the processing chamber, applying a RF bias power to the processing chamber in pulsed mode, and forming a dielectric material in an opening defined in a material layer disposed on the substrate in the presence of the gas mixture and the remote plasma.

Abstract: Apparatus and methods for reducing and eliminating accumulation of excessive charged particles from substrate processing systems are provided herein. In some embodiments a process kit for a substrate process chamber includes: a cover ring having a body and a lip extending radially inward from the body, wherein the body has a bottom, a first wall, and a second wall, and wherein a first channel is formed between the second wall and the lip; a grounded shield having a lower inwardly extending ledge that terminates in an upwardly extending portion configured to interface with the first channel of the cover ring; and a bias power receiver coupled to the body and extending through an opening in the grounded shield.

Abstract: Embodiments of process kit shields and process chambers incorporating same are provided herein. In some embodiments a process kit configured for use in a process chamber for processing a substrate includes a shield having a cylindrical body having an upper portion and a lower portion; an adapter section configured to be supported on walls of the process chamber and having a resting surface to support the shield; and a heater coupled to the adapter section and configured to be electrically coupled to at least one power source of the processes chamber to heat the shield.

Abstract: A deposited amorphous carbon film includes at least 95% carbon. A percentage of sp3 carbon-carbon bonds present in the amorphous carbon film exceeds 30%, and a hydrogen content of the amorphous carbon film is less than 5%. A process of depositing amorphous carbon on a workpiece includes positioning the workpiece within a process chamber and positioning a magnetron assembly adjacent to the process chamber. The magnetron assembly projects a magnetic field into the process chamber. The method further includes providing a carbon target such that the magnetic field extends through the carbon target toward the workpiece. The method further includes providing a source gas to the process chamber, and providing pulses of DC power to a plasma formed from the source gas within the process chamber. The pulses of DC power are supplied in pulses of 40 microseconds or less, that repeat at a frequency of at least 4 kHz.

Abstract: Alignment systems employing actuators provide relative displacement between lid assemblies of process chambers and substrates, and related methods are disclosed. A process chamber includes chamber walls defining a process volume in which a substrate may be placed and the walls support a lid assembly of the process chamber. The lid assembly contains at least one of an energy source and a process gas dispenser. Moreover, an alignment system may include at least one each of a bracket, an interface member, and an actuator. By attaching the bracket to the chamber wall and securing the interface member to the lid assembly, the actuator may communicate with the bracket and the interface member to provide relative displacement between the chamber wall and the lid assembly. In this manner, the lid assembly may be positioned relative to the substrate to improve process uniformity across the substrate within the process chamber.

Abstract: A method may include depositing a carbon layer on a substrate using physical vapor deposition, wherein the carbon layer exhibits compressive stress, and is characterized by a first stress value; and directing a dose of low-mass species into the carbon layer, wherein, after the directing, the carbon layer exhibits a second stress value, less compressive than the first stress value.

Abstract: Embodiments of the present invention provide an apparatus and methods for depositing a dielectric material using RF bias pulses along with remote plasma source deposition for manufacturing semiconductor devices, particularly for filling openings with high aspect ratios in semiconductor applications. In one embodiment, a method of depositing a dielectric material includes providing a gas mixture into a processing chamber having a substrate disposed therein, forming a remote plasma in a remote plasma source and delivering the remote plasma to an interior processing region defined in the processing chamber, applying a RF bias power to the processing chamber in pulsed mode, and forming a dielectric material in an opening defined in a material layer disposed on the substrate in the presence of the gas mixture and the remote plasma.

Abstract: Embodiments of the present disclosure generally describe methods for depositing an amorphous carbon layer onto a substrate, including over previously formed layers on the substrate, using a high power impulse magnetron sputtering (HiPIMS) process, and in particular, biasing of the substrate during the deposition process and flowing a nitrogen source gas and/or a hydrogen source gas into the processing chamber in addition to an inert gas to improve the morphology and film stress of the deposited amorphous carbon layer.

Abstract: Embodiments presented herein relate to a pulse control system for a substrate processing system. The pulse control system includes a power source, a system controller, and a pulse shape controller. The pulse shape controller is coupled to the power source and in communication with the system controller. The pulse shape controller includes a first switch assembly and a second switch assembly. The first switch assembly includes a first switch having a first end and a second end. The first switch is configurable between an open state and a closed state. The second switch assembly includes a second switch having a first end and a second end. The first switch is in the closed state and the second switch is in the open state. The first switch in the closed state is configured to allow a pulse supplied by the power source to transfer through the pulse shape controller.

Abstract: Alignment systems employing actuators provide relative displacement between lid assemblies of process chambers and substrates, and related methods are disclosed. A process chamber includes chamber walls defining a process volume in which a substrate may be placed and the walls support a lid assembly of the process chamber. The lid assembly contains at least one of an energy source and a process gas dispenser. Moreover, an alignment system may include at least one each of a bracket, an interface member, and an actuator. By attaching the bracket to the chamber wall and securing the interface member to the lid assembly, the actuator may communicate with the bracket and the interface member to provide relative displacement between the chamber wall and the lid assembly. In this manner, the lid assembly may be positioned relative to the substrate to improve process uniformity across the substrate within the process chamber.

Abstract: Alignment systems employing actuators provide relative displacement between lid assemblies of process chambers and substrates, and related methods are disclosed. A process chamber includes chamber walls defining a process volume in which a substrate may be placed and the walls support a lid assembly of the process chamber. The lid assembly contains at least one of an energy source and a process gas dispenser. Moreover, an alignment system may include at least one each of a bracket, an interface member, and an actuator. By attaching the bracket to the chamber wall and securing the interface member to the lid assembly, the actuator may communicate with the bracket and the interface member to provide relative displacement between the chamber wall and the lid assembly. In this manner, the lid assembly may be positioned relative to the substrate to improve process uniformity across the substrate within the process chamber.

Abstract: A method may include depositing a carbon layer on a substrate using physical vapor deposition, wherein the carbon layer exhibits compressive stress, and is characterized by a first stress value; and directing a dose of low-mass species into the carbon layer, wherein, after the directing, the carbon layer exhibits a second stress value, less compressive than the first stress value.

Abstract: An apparatus and method of forming a dielectric film layer using a physical vapor deposition process include delivering a sputter gas to a substrate positioned in a processing region of a process chamber, the process chamber having a dielectric-containing sputter target, delivering an energy pulse to the sputter gas to create a sputtering plasma, the sputtering plasma being formed by energy pulses having an average voltage between about 800 volts and about 2000 volts and an average current between about 50 amps and about 300 amps at a frequency which is less than 50 kHz and greater than 5 kHz and directing the sputtering plasma toward the dielectric-containing sputter target to form an ionized species comprising dielectric material sputtered from the dielectric-containing sputter target, the ionized species forming a dielectric-containing film on the substrate.

Abstract: Embodiments presented herein relate to a method of and apparatus for processing a substrate in a semiconductor processing system. The method begins by initializing a pulse synchronization controller coupled between a pulse RF bias generator and a HIPIMs generator. A first timing signal is sent by the pulse synchronization controller to the pulse RF bias generator and the HIPIMs generator. A sputtering target and an RF electrode disposed in a substrate support is energized based on the first timing signal. The target and the electrode is de-energized based on an end of the timing signal. A second timing signal is sent by the pulse synchronization controller to the pulse RF bias generator and the electrode is energized and de-energized without energizing the target in response to the second timing signal.

Abstract: Methods for forming fin structures with desired profile and dimensions for three dimensional (3D) stacking of fin field effect transistor (FinFET) for semiconductor chips are provided. The methods include a structure reshaping process to reshape a shaped structure, such as a diamond like structure formed on a fin structure. In one embodiment, a method for forming a structure on a substrate includes performing an epitaxial deposition process to form a shaped structure on a fin structure disposed on a substrate, performing a mask layer deposition process to form a mask layer having a first width on the shaped structure, and performing a mask trimming process to trim the mask layer from the first width from a second width.

Abstract: Embodiments of the present disclosure generally describe methods for depositing an amorphous carbon layer onto a substrate, including over previously formed layers on the substrate, using a high power impulse magnetron sputtering (HiPIMS) process, and in particular, biasing of the substrate during the deposition process and flowing a nitrogen source gas and/or a hydrogen source gas into the processing chamber in addition to an inert gas to improve the morphology and film stress of the deposited amorphous carbon layer.

Abstract: Apparatus and methods for reducing and eliminating accumulation of excessive charged particles from substrate processing systems are provided herein. In some embodiments a process kit for a substrate process chamber includes: a cover ring having a body and a lip extending radially inward from the body, wherein the body has a bottom, a first wall, and a second wall, and wherein a first channel is formed between the second wall and the lip; a grounded shield having a lower inwardly extending ledge that terminates in an upwardly extending portion configured to interface with the first channel of the cover ring; and a bias power receiver coupled to the body and extending through an opening in the grounded shield.