Embodiments herein provide plasma processing chambers and methods configured for fine-tuning and control over a plasma sheath formed during the plasma-assisted processing of a semiconductor substrate. Embodiments include a sheath tuning scheme, including plasma processing chambers and methods, which can be used to tailor one or more characteristics of a plasma sheath formed between a bulk plasma and a substrate surface. Generally, the sheath tuning scheme provides differently configured pulsed voltage (PV) waveforms to a plurality of bias electrodes embedded beneath the surface of a substrate support in an arrangement where each of the electrodes can be used to differentially bias a surface region of a substrate positioned on the support. The sheath tuning scheme disclosed herein can thus be used to adjust and/or control the directionality, and energy and angular distributions of ions that bombard a substrate surface during a plasma-assisted etch process.

A method of performing a plasma process includes generating, at an output of a signal generator, a first RF signal at a first frequency. The signal generator is coupled to a plasma chamber through a matching circuit. Based on a feedback from the first RF signal, variable components of the matching circuit are moved to fixed positions. A second RF signal is generated at a second frequency at the output of the signal generator to ignite a plasma within the plasma chamber. In response to detecting the plasma, the signal generator switches to output a third RF signal at the first frequency to sustain the plasma, which is configured to process a substrate loaded into the plasma chamber while holding the matching circuit at the fixed positions.

Apparatus for generating a plasma via the transient hollow cathode discharge effect is disclosed. The apparatus comprises a chamber comprising an inlet through which gas may enter the chamber and an outlet through which the gas may exit the chamber, a cathode electrode disposed in the chamber, the cathode electrode comprising a plurality of hollow cathodes, an anode electrode spaced apart from the cathode, a power supply, and a power supply controller configured to reduce a power level of the electrical power below a level required to maintain the plasma at the plurality of hollow cathodes, after electrical breakdown has occurred. Each hollow cathode comprises a through-thickness hole through which the gas may pass from one side of the cathode electrode to another side of the cathode electrode. A modular apparatus is also disclosed, comprising a plurality of plasma reactor modules arranged in series and/or in parallel.

In one embodiment, an RF impedance matching network is disclosed. The matching network is coupled between an RF source having a variable frequency and a plasma chamber having a variable chamber impedance. The matching network includes a variable reactance element (VRE), and a control circuit coupled to the VRE and a sensor, the sensor configured to detect an RF parameter. To cause an impedance match between the RF source and the plasma chamber, the control circuit determines, based on the detected RF parameter and a VRE configuration, a new source frequency for the RF source. The impedance match then causes the variable frequency of the RF source to alter to the new source frequency.

In one embodiment, the present disclosure is directed to a method for impedance matching. A matching network includes first and second reactance elements configured to provide variable positions. A first parameter of the matching network is determined based on a detected value. The method determines first two-port parameters from a first one-dimensional array that corresponds to a first portion of the matching network using the first reactance element position, and second two-port parameters from a second one-dimensional array that corresponds to a second portion of the matching network using the second reactance element position. An output parameter is calculated based on the first parameter, the first two-port parameters, and the second two-port parameters. New first and second reactance element positions are determined from a match position table using the calculated output parameter. The method then alters the reactance elements accordingly to reduce a reflected power.

There is provided a method of analyzing data obtained from an etching apparatus for micromachining a wafer using plasma. This method includes the following steps: acquiring the plasma light-emission data indicating light-emission intensities at a plurality of different wavelengths and times, the plasma light-emission data being measured under a plurality of different etching processing conditions, and being obtained at the time of the etching processing, evaluating the relationship between changes in the etching processing conditions and changes in the light-emission intensities at the plurality of different wavelengths and times with respect to the wavelengths and times of the plasma light-emission data, and identifying the wavelength and the time of the plasma light-emission data based on the evaluation result, the wavelength and the time being to be used for the adjustment of the etching processing condition.

A plasma processing apparatus includes: a detector configured to detect a change in an intensity of light emission from plasma formed inside a processing chamber; and a unit configured to adjust conditions for forming the plasma or processing a wafer arranged inside the processing chamber using an output from the detector, wherein the detector detects a signal of the intensity of light emission at plural time instants before an arbitrary time instant during processing, and wherein the adjusting unit removes the component of a temporal change of a long cycle of the intensity of light emission from this detected signal and detects the component of a short temporal change of the intensity of light emission, and adjusts the conditions for forming the plasma or processing a wafer arranged inside the processing chamber based on the short temporal change of the detected intensity of light emission.

A substrate processing system for a substrate processing chamber includes a gas delivery system configured to direct process gases toward a substrate support in the substrate processing chamber and a controller. During processing of a substrate arranged on the substrate support the controller is configured to calculate, based on at least one of a position of an edge ring of the substrate support and characteristics of the process gases directed toward the substrate support, a distribution of etch by-product material redeposited onto the substrate during processing and, in response to the calculated distribution, generate control signals to cause an actuator to selectively adjust a position of the edge ring relative to the substrate and cause the gas delivery system to selectively adjust a flow of the process gases.

There is provided a method of analyzing data obtained from an etching apparatus for micromachining a wafer using plasma. This method includes the following steps: acquiring the plasma light-emission data indicating light-emission intensities at a plurality of different wavelengths and times, the plasma light-emission data being measured under a plurality of different etching processing conditions, and being obtained at the time of the etching processing, evaluating the relationship between changes in the etching processing conditions and changes in the light-emission intensities at the plurality of different wavelengths and times with respect to the wavelengths and times of the plasma light-emission data, and identifying the wavelength and the time of the plasma light-emission data based on the evaluation result, the wavelength and the time being to be used for the adjustment of the etching processing condition.

A plasma generator and a method for the pulsed provision of electrical power having a frequency of at least 40 KHz to at least two process chambers are described. The plasma generator comprises: a control unit configured to obtain and evaluate process data about processes in the at least two process chambers; a controllable power supply having an output, the controllable power supply being configured to output a direct current at a predetermined voltage and/or intensity at its output in response to a control signal from the control unit; and a switching unit having a first input connected to the output of the power supply and having at least two switching unit outputs for respective connection to one of the at least two process chambers. The switching unit is configured to form, from a direct current at the input, an alternating current having a predetermined frequency of at least 40 KHz as an output signal and to selectively output the output signal as a pulse for a predetermined pulse duration to one of the switching unit outputs in response to a control signal from the control unit. The control unit is configured to coordinate power requirements of the at least two process chambers and to drive the power supply and the switching unit such that at the respective switching unit outputs communicating with the process chambers, substantially the power corresponding to the power requirements is provided as pulses over a period of time, wherein the pulses of the respective process chambers are temporally offset from each other such that the process chambers can be operated simultaneously.