In a plasma processing apparatus, a high frequency power source is electrically connected to a lower electrode of a supporting table through a power feeding unit. The power feeding unit is surrounded by a conductor pipe outside the chamber. An electrostatic chuck of the supporting table has therein a plurality of heaters. A filter device is provided between the heaters and a heater controller. The filter device includes a plurality of coil groups, each of the coil groups including two or more coils. In each of the coil groups, the two or more coils are arranged such that winding portions of the two or more coils extend in a spiral shape around a central axis and turns of the winding portions are arranged sequentially and repeatedly, and the coil groups are provided coaxially to the central axis to surround the conductor pipe directly below the chamber.

Embodiments described herein relate to methods of tuning within semiconductor processes to improve plasma stability. In these embodiments, multiple matching networks are provided. Each of the matching networks couple a radio frequency (RF) source to one of multiple connection points located on an electrode. Based on tuning parameter information and physical geometry information, a controller determines a tuning sequence for the multiple matching networks. As such, some of the matching networks are tuned while the other matching networks are locked. Using multiple matching networks leads to a more uniform plasma within the process volume of the process chamber. Improved plasma uniformity leads to less substrate defects and better device performance. Additionally, in these embodiments, the ability to tune each of the matching networks in a sequence decreases or prevents interference from occurring between the matching networks.

A ceramic structure including a first conductive structure embedded therein and a second conductive structure embedded at a different depth from the first conductive structure is disclosed. In the ceramic structure, the first conductive structure and the second conductive structure are electrically connected to each other by an electrically conductive connection member capable of compensating for a vertical shrinkage rate of a ceramic sheet shape while being embedded therein when sintering the ceramic structure.

Embodiments of the present disclosure generally relate to a substrate support assembly in a semiconductor processing chamber. The semiconductor processing chamber may be a PECVD chamber including a substrate support assembly having a substrate support and a stem coupled to the substrate support. An RF electrode is embedded in the substrate support and a rod is coupled to the RF electrode. The rod is made of titanium (Ti) or of nickel (Ni) coated with gold (Au), silver (Ag), aluminum (Al), or copper (Cu). The rod made of Ti or of Ni coated with Au, Ag, Al or Cu has a reduced electrical resistivity and increased skin depth, which minimizes heat generation as RF current travels through the rod.

In a plasma processing of generating plasma of different processing gases within a processing vessel in sequence, a setting of a high frequency power can be changed at an appropriate time point after the processing gas output from a gas supply system is changed. A power level of a second high frequency power is increased at a time point when a first parameter which reflects impedance of plasma exceeds a first threshold value after the processing gas is changed while a first high frequency power is being supplied to a first electrode or a second electrode. Further, a power level of the first high frequency power is increased at a time point when a second parameter which reflects impedance of plasma exceeds a second threshold value after the processing gas is changed while the second high frequency power is being supplied to the second electrode.

In a plasma processing method of sequentially performing multiple cycles, each of which includes plural stages which generate plasma of different processing gases within a processing vessel and which are performed in sequence, a setting of a high frequency power and/or a setting of a level of a DC voltage is changed at an appropriate time point after transitioning from a preceding stage to a succeeding stage. The high frequency power is supplied to one of a first electrode and a second electrode of a plasma processing apparatus, and the processing gas output from a gas supply system is changed when transitioning from the preceding stage to the succeeding stage. Thereafter, the setting of the high frequency power and/or the setting of the level of the negative DC voltage is changed at a time point when a parameter reflecting an impedance of the plasma exceeds a threshold value.

In a plasma processing method in which multiple cycles, each of which includes a first stage of generating plasma of a first processing gas containing a first gas and a second stage of generating plasma of a second processing gas containing the first gas and a second gas, are performed, a time difference between a start time point of a time period during which the second stage is performed and a start time point of an output of the second gas from a gas supply system is decided automatically according to a recipe. A delay time corresponding to flow rates of the first gas and the second gas in the second stage is specified from a function or a table. The output of the second gas is begun prior to the start time point of the second stage by a time difference set based on the delay time.

A substrate treatment apparatus includes a chamber providing a reaction region and including first and second sides facing each other, a module connected to the first side, an upper electrode in the reaction region, a substrate holder facing the upper electrode, wherein a substrate is disposed on the substrate holder, and first and second points are defined on the substrate, wherein the first point corresponds to a center of the substrate, and the second point is distant from the first point toward the first side, and a feeding line for applying an RF power, the feeding line connected to the upper electrode corresponding to the second point.

A transmission line RF applicator apparatus and method for coupling RF power to a plasma in a plasma chamber. The apparatus comprises two conductors, one of which has a plurality of apertures. In one aspect, apertures in different portions of the conductor have different sizes, spacing or orientations. In another aspect, adjacent apertures at successive longitudinal positions are offset along the transverse dimension. In another aspect, the apparatus comprises an inner conductor and one or two outer conductors. The main portion of each of the one or two outer conductors includes a plurality of apertures that extend between an inner surface and an outer surface of the outer conductor.

Provided are apparatuses and methods for performing deposition and etch processes in an integrated tool. An apparatus may include a plasma processing chamber that is a capacitively-coupled plasma reactor, and the plasma processing chamber can include a showerhead that includes a top electrode and a pedestal that includes a bottom electrode. The apparatus may be configured with an RF hardware configuration so that an RF generator may power the top electrode in a deposition mode and power the bottom electrode in an etch mode. In some implementations, the apparatus can include one or more switches so that at least an HFRF generator is electrically connected to the showerhead in a deposition mode, and the HFRF generator and an LFRF generator is electrically connected to the pedestal and the showerhead is grounded in the etch mode.