Embodiments of the present disclosure generally relate to methods of depositing a conformal layer on surfaces of high aspect ratio structures and related apparatuses for performing these methods. The conformal layers described herein are formed using PECVD methods in which a semiconductor device including a plurality of high aspect ratio features is disposed on a substrate support in a process volume of a process chamber, gases are supplied to the process volume, and a plasma is generated in the process volume by pulsing RF power coupled to the process gases disposed in the process volume of the process chamber.

A processing method including a first step of supplying a first gas including a carbon-containing gas and an inert gas into an inside of a chamber and a second step of generating plasma from the supplied first gas by applying high frequency power for generating plasma and causing a chemical compound including organic matter on a pattern of a predetermined film formed on an object to be processed, wherein a ratio of the carbon-containing gas relative to the inert gas included in the first gas is 1% or less.

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.

A substrate processing method includes: providing a substrate in a processing container; selectively forming a first film on a surface of a substrate by plasma enhanced vapor deposition (PECVD); and forming a second film by atomic layer deposition (ALD) in a region of the substrate where the first film does not exist. The second film is formed by repeatedly performing a sequence including: forming a precursor layer on the surface of the substrate; purging an interior of the processing container after forming of the precursor; converting the precursor layer into the second film; and purging a space in the processing container after the converting. A plasma processing apparatus performing the method is also provided.

An aluminum gas distribution plate refurbishment system combines a multi-beam inductively coupled plasma (AP-ICP) torch and vacuum discharge chuck. Plasma beams are employed to clean and restore to service the many gas flow passages in aluminum type gas distribution plates. Several parallel supersonic plasma beams of uniform density are produced from a single upper and lower AP-ICP plasma reactor arranged in totem pole that are driven by two pairs of opposing spiral planar RF induction RF antennas. These plasma beams are focused inside the gas flow passages to etch, heat, and deposit nanoparticles within. The vacuum discharge chuck includes a capacitively coupled plasma (CCP) reactor to generate a positive species discharge immediately beneath the gas distribution plates. This overcomes and undoes a Debye Sheathing effect, a electron-fed negative space charge blocking occurring above, and unknots any congested plasma beams in the gas flow passages.

An aluminum gas distribution plate refurbishment system combines a multi-beam inductively coupled plasma (AP-ICP) torch and vacuum discharge chuck. Plasma beams are employed to clean and restore to service the many gas flow passages in aluminum type gas distribution plates. Several parallel supersonic plasma beams of uniform density are produced from a single upper and lower AP-ICP plasma reactor arranged in totem pole that are driven by two pairs of opposing spiral planar RF induction RF antennas. These plasma beams are focused inside the gas flow passages to etch, heat, and deposit nanoparticles within. The vacuum discharge chuck includes a capacitively coupled plasma (CCP) reactor to generate a positive species discharge immediately beneath the gas distribution plates. This overcomes and undoes a Debye Sheathing effect, a electron-fed negative space charge blocking occurring above, and unknots any congested plasma beams in the gas flow passages.

A magnetron sputter reactor for sputtering deposition materials such as tantalum, tantalum nitride and copper, for example and its method of use, in which self-ionized plasma (SIP) sputtering and inductively coupled plasma (ICP) sputtering are promoted, either together or alternately, in the same or different chambers. Also, bottom coverage may be thinned or eliminated by ICP resputtering in one chamber and SIP in another. SIP is promoted by a small magnetron having poles of unequal magnetic strength and a high power applied to the target during sputtering. ICP is provided by one or more RF coils which inductively couple RF energy into a plasma. The combined SIP-ICP layers can act as a liner or barrier or seed or nucleation layer for hole. In addition, an RF coil may be sputtered to provide protective material during ICP resputtering. In another chamber an array of auxiliary magnets positioned along sidewalls of a magnetron sputter reactor on a side towards the wafer from the target. The magnetron preferably is a small, strong one having a stronger outer pole of a first magnetic polarity surrounding a weaker outer pole of a second magnetic polarity and rotates about the central axis of the chamber. The auxiliary magnets preferably have the first magnetic polarity to draw the unbalanced magnetic field component toward wafer. The auxiliary magnets may be either permanent magnets or electromagnets.

A processing method including a first step of supplying a first gas including a carbon-containing gas and an inert gas into an inside of a chamber and a second step of generating plasma from the supplied first gas by applying high frequency power for generating plasma and causing a chemical compound including organic matter on a pattern of a predetermined film formed on an object to be processed, wherein a ratio of the carbon-containing gas relative to the inert gas included in the first gas is 1% or less.

A magnetron sputter reactor for sputtering deposition materials such as tantalum, tantalum nitride and copper, for example, and its method of use, in which self-ionized plasma (SIP) sputtering and inductively coupled plasma (ICP) sputtering are promoted, either together or alternately, in the same or different chambers. Also, bottom coverage may be thinned or eliminated by ICP resputtering in one chamber and SIP in another. SIP is promoted by a small magnetron having poles of unequal magnetic strength and a high power applied to the target during sputtering. ICP is provided by one or more RF coils which inductively couple RF energy into a plasma. The combined SIP-ICP layers can act as a liner or barrier or seed or nucleation layer for hole. In addition, an RF coil may be sputtered to provide protective material during ICP resputtering. In another chamber an array of auxiliary magnets positioned along sidewalls of a magnetron sputter reactor on a side towards the wafer from the target. The magnetron preferably is a small, strong one having a stronger outer pole of a first magnetic polarity surrounding a weaker outer pole of a second magnetic polarity and rotates about the central axis of the chamber. The auxiliary magnets preferably have the first magnetic polarity to draw the unbalanced magnetic field component toward the wafer. The auxiliary magnets may be either permanent magnets or electromagnets.

Aspects of the present disclosure generally relate to apparatus and methods for an adjustable de-chucking voltage associated with an electrostatically charged substrate in a processing chamber. An example method of de-chucking a substrate disposed in a process chamber includes processing a substrate in a chamber body, the substrate being coupled to a substrate support comprising a chucking electrode. The method further includes monitoring a property associated with a lift pin assembly movable relative to the chucking electrode via an actuator. The method further includes adjusting a first voltage level applied to the chucking electrode in response to the property associated with the lift pin assembly satisfying one or more criteria.