Abstract: A substrate processing system for depositing film on a substrate includes a processing chamber defining a reaction volume. A showerhead includes a stem portion having one end connected adjacent to an upper surface of the processing chamber. A base portion is connected to an opposite end of the stem portion and extends radially outwardly from the stem portion. The showerhead is configured to introduce at least one of process gas and purge gas into the reaction volume. A plasma generator is configured to selectively generate RF plasma in the reaction volume. An edge tuning system includes a collar and a parasitic plasma reducing element that is located around the stem portion between the collar and an upper surface of the showerhead. The parasitic plasma reducing element is configured to reduce parasitic plasma between the showerhead and the upper surface of the processing chamber.

Abstract: A process chamber for detecting formation of plasma during a semiconductor wafer processing, includes an upper electrode, for providing a gas chemistry to the process chamber. The upper electrode is connected to a radio frequency (RF) power source through a match network to provide RF power to the wafer cavity to generate a plasma. The process chamber also includes a lower electrode for receiving and supporting the semiconductor wafer during the deposition process. The lower electrode is disposed in the process chamber so as to define a wafer cavity between a surface of the upper electrode and a top surface of the lower electrode. The lower electrode is electrically grounded. A coil sensor is disposed at a base of the lower electrode that extends outside the process chamber. The coil sensor substantially surrounds the base of the lower electrode. The coil sensor is configured to measure characteristics of RF current conducting through the wafer cavity.

Abstract: A wafer is positioned on a wafer support apparatus beneath an electrode such that a plasma generation region exists between the wafer and the electrode. Radiofrequency power is supplied to the electrode to generate a plasma within the plasma generation region. Optical emissions are collected from the plasma using one or more optical emission collection devices, such as optical fibers, charge coupled device cameras, photodiodes, or the like. The collected optical emissions are analyzed to determine whether or not an optical signature of a plasma instability exists in the collected optical emissions. Upon determining that the optical signature of the plasma instability does exist in the collected optical emissions, at least one plasma generation parameter is adjusted to mitigate formation of the plasma instability.

Abstract: A wafer is positioned on a wafer support apparatus beneath an electrode such that a plasma generation region exists between the wafer and the electrode. Radiofrequency signals of a first signal frequency are supplied to the plasma generation region to generate a plasma within the plasma generation region. Formation of a plasma instability is detected within the plasma based on supply of the radiofrequency signals of the first signal frequency. After detecting formation of the plasma instability, radiofrequency signals of a second signal frequency are supplied to the plasma generation region in lieu of the radiofrequency signals of the first signal frequency to generate the plasma. The second signal frequency is greater than the first signal frequency and is set to cause a reduction in ion energy within the plasma and a corresponding reduction in secondary electron emission from the wafer caused by ion interaction with the wafer.

Abstract: An apparatus for supporting a wafer during a plasma processing operation includes a pedestal configured to have bottom surface and a top surface and a column configured to support the pedestal at a central region of the bottom surface of the pedestal. An electrical insulating layer is disposed over the top surface of the pedestal. An electrically conductive layer is disposed over the top surface of the electrical insulating layer. At least three electrically conductive support structures are distributed on the electrically conductive layer. The at least three support structures are configured to interface with a bottom surface of a wafer to physically support the wafer and electrically connect to the wafer. An electrical connection extends from the electrically conductive layer to connect with a positive terminal of a direct current power supply at a location outside of the pedestal.

Abstract: A wafer is positioned on a wafer support apparatus beneath an electrode such that a plasma generation region exists between the wafer and the electrode. Radiofrequency power is supplied to the electrode to generate a plasma within the plasma generation region during multiple sequential plasma processing cycles of a plasma processing operation. At least one electrical sensor connected to the electrode measures a radiofrequency parameter on the electrode during each of the multiple sequential plasma processing cycles. A value of the radiofrequency parameter as measured on the electrode is determined for each of the multiple sequential plasma processing cycles. A determination is made as to whether or not any indicatory trend or change exists in the values of the radiofrequency parameter as measured on the electrode over the multiple sequential plasma processing cycles, where the indicatory trend or change indicates formation of a plasma instability during the plasma processing operation.

Abstract: Systems and methods are disclosed for plasma enabled film deposition on a wafer in which a plasma is generated using radiofrequency signals of multiple frequencies and in which a phase angle relationship is controlled between the radiofrequency signals of multiple frequencies. In the system, a pedestal is provided to support the wafer. A plasma generation region is formed above the pedestal. An electrode is disposed in proximity to the plasma generation region to provide for transmission of radiofrequency signals into the plasma generation region. A radiofrequency power supply provides multiple radiofrequency signals of different frequencies to the electrode. A lowest of the different frequencies is a base frequency, and each of the different frequencies that is greater than the base frequency is an even harmonic of the base frequency. The radiofrequency power supply provides for variable control of the phase angle relationship between each of the multiple radiofrequency signals.

Abstract: A process chamber for detecting formation of plasma during a semiconductor wafer processing, includes an upper electrode, for providing a gas chemistry to the process chamber. The upper electrode is connected to a radio frequency (RF) power source through a match network to provide RF power to the wafer cavity to generate a plasma. The process chamber also includes a lower electrode for receiving and supporting the semiconductor wafer during the deposition process. The lower electrode is disposed in the process chamber so as to define a wafer cavity between a surface of the upper electrode and a top surface of the lower electrode. The lower electrode is electrically grounded. A coil sensor is disposed at a base of the lower electrode that extends outside the process chamber. The coil sensor substantially surrounds the base of the lower electrode. The coil sensor is configured to measure characteristics of RF current conducting through the wafer cavity.

Abstract: Disclosed are methods of performing film deposition. The methods may include volumetrically isolating a first process station from a second process station by flowing a curtain gas between them, and igniting first and second plasmas supported by first and second plasma feed gases, while flowing the curtain gas, to cause film deposition at the first and second process stations. The curtain gas and the first and second plasma feed gases may each include a high-breakdown voltage species that may be molecular oxygen. The high-breakdown voltage species may have a breakdown voltage of at least about 250 V for a pressure-distance (pd) value of 3.4 Torr-cm. The curtain gas may have a higher concentration of the high-breakdown voltage species than the first and second plasma feed gases. The high-breakdown voltage species may make up about 5-50% of the curtain gas by mole fraction. The high-breakdown voltage species may be molecular oxygen.

Abstract: A showerhead in a semiconductor processing apparatus can include faceplate through-holes configured to improve the flow uniformity during atomic layer deposition. The showerhead can include a faceplate having a plurality of through-holes for distributing gas onto a substrate, where the faceplate includes small diameter through-holes. For example, the diameter of each of the through-holes can be less than about 0.04 inches. In addition or in the alternative, the showerhead can include edge through-holes positioned circumferentially along a ring having a diameter greater than a diameter of the substrate being processed. The showerhead can be a low volume showerhead and can include a baffle proximate one or more gas inlets in communication with a plenum volume of the showerhead. The faceplate with small diameter through-holes and/or edge through-holes can improve overall film non-uniformity, improve azimuthal film non-uniformity at the edge of the substrate, and enable operation at higher RF powers.

Abstract: A substrate processing system includes a processing chamber including a showerhead, a plasma power source and a pedestal spaced from the showerhead to support a substrate. A filter is connected between the showerhead and the pedestal. A variable bleed current circuit is connected between the filter and the pedestal to vary a bleed current. A controller is configured to adjust a value of the bleed current and configured to perform curve fitting based on the bleed current and DC self-bias voltage to estimate at least one of electrode area ratio, Bohm current, and radio frequency (RF) voltage at a powered electrode.

Abstract: In situ wafer metrology is conducted to reliably obtain deposition thickness for each successive layer in a multi-layer deposition. A wafer to be processed is positioned in a processing station of a deposition process tool, the process tool having a reflectometer metrology apparatus for optically determining thickness of a deposited layer on the wafer. Prior to commencing a deposition, the wafer is aligned in the processing station such that an optical metrology spot generated by the reflectometer metrology apparatus will align with an unpatterned central region of a die on a wafer during a deposition conducted on the wafer in the tool. Thereafter, the thickness of a deposited layer on the wafer is reliably measured and monitored in situ.

Abstract: A plasma chamber includes a pedestal, an upper electrode, and an annular structure. The pedestal has a central region to support a wafer and a step region that circumscribes the central region. A sloped region circumscribes the step region, with the sloped region having a top surface that slopes downward from the step region such that a vertical distance between the inner boundary of the top surface and the central region is less than a vertical distance between the outer boundary of the top surface and the central region. The upper electrode is coupled to a radio frequency power supply. An inner perimeter of the annular structure is defined to circumscribe the central region of the pedestal when the annular structure is disposed over the pedestal, and a portion of the annular structure has a thickness that increases with a radius of the annular structure.

Abstract: A showerhead assembly for a substrate processing system includes a back plate connected to a gas channel. A face plate is connected adjacent to a first surface of the back plate and includes a gas diffusion surface. An electrode is arranged in one of the back plate and the face plate and is connected to one or more conductors. A gas plenum is defined between the back plate and the face plate and is in fluid communication with the gas channel. The back plate and the face plate are made of a non-metallic material.

Abstract: A substrate processing system includes a processing chamber including a showerhead, a plasma power source and a pedestal spaced from the showerhead to support a substrate. A filter is connected between the showerhead and the pedestal. A variable bleed current circuit is connected between the filter and the pedestal to vary a bleed current. A controller is configured to adjust a value of the bleed current and configured to perform curve fitting based on the bleed current and DC self-bias voltage to estimate at least one of electrode area ratio, Bohm current, and radio frequency (RF) voltage at a powered electrode.

Abstract: A substrate processing system for depositing film on a substrate includes a processing chamber defining a reaction volume. A showerhead includes a stem portion having one end connected adjacent to an upper surface of the processing chamber. A base portion is connected to an opposite end of the stem portion and extends radially outwardly from the stem portion. The showerhead is configured to introduce at least one of process gas and purge gas into the reaction volume. A plasma generator is configured to selectively generate RF plasma in the reaction volume. An edge tuning system includes a collar and a parasitic plasma reducing element that is located around the stem portion between the collar and an upper surface of the showerhead. The parasitic plasma reducing element is configured to reduce parasitic plasma between the showerhead and the upper surface of the processing chamber.

Abstract: A substrate processing system includes a processing chamber and an upper electrode arranged in the processing chamber. A pedestal is configured to support a substrate during processing and includes a lower electrode. An RF generating system is configured to generate RF plasma between the upper electrode and the lower electrode by supplying an RF voltage. A bias generating circuit is configured to selectively supply a DC bias voltage to one of the upper electrode and the lower electrode. A start of the DC bias voltage is initiated one of a first predetermined period before the RF plasma is extinguished and a second predetermined period after the RF plasma is extinguished. A substrate movement system is configured to move the substrate relative to the pedestal while the DC bias voltage is generated.

Abstract: A faceplate for a gas distribution system of a plasma processing chamber includes a faceplate body having a first surface, a second surface opposite to the first surface and a side surface. A first plurality of holes in the faceplate body extends from the first surface to the second surface. At least some of the first plurality of holes has a first size dimension and a second size dimension in a plane parallel to the first surface. The first size dimension is transverse to the second size dimension. The first size dimension is less than 3 plasma sheath thicknesses of plasma generated by the plasma processing chamber. The second size dimension is greater than 2 times the first size dimension.

Abstract: A showerhead assembly for a substrate processing system includes a back plate connected to a gas channel. A face plate is connected adjacent to a first surface of the back plate and includes a gas diffusion surface. An electrode is arranged in one of the back plate and the face plate and is connected to one or more conductors. A gas plenum is defined between the back plate and the face plate and is in fluid communication with the gas channel. The back plate and the face plate are made of a non-metallic material.

Abstract: A substrate processing system includes a processing chamber including a showerhead, a plasma power source and a pedestal spaced from the showerhead to support a substrate. A filter is connected between the showerhead and the pedestal. A variable bleed current circuit is connected between the filter and the pedestal to vary a bleed current. A controller is configured to adjust a value of the bleed current and configured to perform curve fitting based on the bleed current and DC self-bias voltage to estimate at least one of electrode area ratio, Bohm current, and radio frequency (RF) voltage at a powered electrode.