A plasma etching apparatus includes a second electrode configured to support a target substrate thereon, a second RF power supply unit configured to apply a second RF power for providing a bias for ion attraction to the second electrode, and a control system including and an RF controller. The RF controller is configured to switch the second RF power supply unit between a continuous mode that executes continuous supply of the second RF power at a constant power level and a power modulation mode that executes modulation of the second RF power between a first power and a second power larger than the first power. The RF controller is preset to control the second RF power supply unit such that the second RF power supply unit is first operated in the continuous mode for plasma ignition and then is switched into the power modulation mode.

An etching apparatus includes: a placement table serving as a lower electrode and configured to place a workpiece to be subjected to an etching processing thereon; a DC power supply configured to generate a negative DC voltage applied to the placement table; and a controller configured to: periodically apply a negative DC voltage to the placement table from the DC power supply when the etching processing on the workpiece placed on the placement table is initiated, and decrease a frequency of the negative DC voltage applied to the placement table with an elapse of processing time of the etching processing.

An apparatus may include a main chamber, a substrate holder, disposed in a lower region of the main chamber, and defining a substrate region, as well as an RF applicator, disposed adjacent an upper region of the main chamber, to generate an upper plasma within the upper region. The apparatus may further include a central chamber structure, disposed in a central portion of the main chamber, where the central chamber structure is disposed to shield at least a portion of the substrate position from the upper plasma. The apparatus may include a bias source, electrically coupled between the central chamber structure and the substrate holder, to generate a glow discharge plasma in the central portion of the main chamber, wherein the substrate region faces the glow discharge region.

Atomic layer etching of a substrate using a wafer scale wave of precisely controlled electrons is presented. A volume of gaseous plasma including diluent and reactive species and electrons of a uniform steady state composition is generated in a positive column of a DC plasma proximate the substrate. A corrosion layer is formed on the substrate by adsorption of the reactive species to atoms at the surface of the substrate. The substrate is positively biased to draw electrons from the volume to the surface of the substrate and impart an energy to the electrons so to stimulate electron transitions in the corrosion layer species, resulting in ejection of the corrosion layer species via electron stimulation desorption (ESD). The substrate is negatively biased to repel the electrons from the surface of the substrate back to the volume, followed by a zero bias to restore the steady state composition of the volume.

In an embodiment, there is provided a method of operating an electrostatic chuck of a plasma processing apparatus. The electrostatic chuck has a base, a dielectric layer formed on the base, and a chuck main body mounted on the dielectric layer. In the method, a temperature difference between the temperature of the base and the temperature of the chuck main body is reduced in a state in which the chuck main body is attracted to the dielectric layer with a relatively small electrostatic attractive force. In a case where the temperature difference between the temperature of the base and the temperature of the chuck main body becomes equal to or less than a predetermined value, the chuck main body is fixed to the base via the dielectric layer by a relatively large electrostatic attractive force.

A method of performing impedance matching between a power supply section of a plasma processing apparatus and a chamber in the plasma processing apparatus is provided. The plasma processing apparatus includes multiple matchers, each configured to perform impedance matching between the power supply section and the chamber, and the power supply section is configured to output superimposed voltage in which radio frequency voltage is superimposed on pulsating DC voltage. According to the method, the superimposed voltage from the power supply section is applied to the chamber, through one of the provided matchers, and the matcher through which the superimposed voltage is applied to the chamber is then switched in accordance with a state of the pulsating DC voltage.

One or more embodiments described herein generally relate to methods for chucking and de-chucking a substrate to/from an electrostatic chuck used in a semiconductor processing system. Generally, in embodiments described herein, the method includes: (1) applying a first voltage from a direct current (DC) power source to an electrode disposed within a pedestal; (2) introducing process gases into a process chamber; (3) applying power from a radio frequency (RF) power source to a showerhead; (4) performing a process on the substrate; (5) stopping application of the RF power; (6) removing the process gases from the process chamber; and (7) stopping applying the DC power.

A substrate processing apparatus for performing a predetermined processing on a substrate includes a power supply device configured to supply a DC power. The power supply device includes a power supply and a current detection unit configured to detect a current value of a DC power from the power supply. The current detection unit includes a plurality of current sensors used for detecting the current value in the current detection unit and having different detection ranges for the current value, and a switching unit configured to switch the current sensors. The power supply is controlled such that the DC power from the power supply is maintained at a set value based on a detection result of the current detection unit, and the switching unit switches the current sensors depending on the set value of the DC power from the power supply.

An etching apparatus includes: a placement table serving as a lower electrode and configured to place a workpiece to be subjected to an etching processing thereon; a DC power supply configured to generate a negative DC voltage applied to the placement table; and a controller configured to: periodically apply a negative DC voltage to the placement table from the DC power supply when the etching processing on the workpiece placed on the placement table is initiated, and decrease a frequency of the negative DC voltage applied to the placement table with an elapse of processing time of the etching processing.

A plasma processing apparatus includes: a processing container; an electrode that places a workpiece thereon; a plasma generation source that supplies plasma into the processing container; a bias power supply that supplies a bias power to the electrode; an edge ring disposed at a periphery of the workpiece; a DC power supply that supplies a DC voltage to the edge ring; a controller that executes a first control procedure in which the DC voltage periodically repeats a first state having a first voltage value and a second state having a second voltage value, the first voltage value is supplied in a partial time period within each period of a potential of the electrode, and the second voltage value is supplied such that the first and second states are continuous.