Abstract: A plasma processing apparatus includes a substrate chuck having a first surface for supporting a substrate, a second surface opposite to the first surface, and a sidewall, a focus ring for surrounding a perimeter of the substrate, and an edge block for supporting the focus ring. The edge block includes a side electrode on the sidewall of the substrate chuck and a bottom electrode on the second surface of the substrate chuck.

Abstract: In a plasma processing method, a substrate is loaded onto a lower electrode within a chamber. A plasma power is applied to form plasma within the chamber. A voltage function of a nonsinusoidal wave having a DC pulse portion and a ramp portion is generated. Generating the voltage function may include setting a slope of the ramp portion and setting a duration ratio of the ramp portion to a cycle of the voltage function in order to control an ion energy distribution generated at a surface of the substrate. A bias power of the nonsinusoidal wave is applied to the lower electrode.

Abstract: A semiconductor manufacturing apparatus includes a loadlock module including a loadlock chamber in which a substrate container is received, wherein the loadlock module is configured to switch an internal pressure of the loadlock chamber between atmospheric pressure and a vacuum; and a transfer module configured to transfer a substrate between the substrate container received in the loadlock chamber and a process module for performing a semiconductor manufacturing process on the substrate, wherein the loadlock module includes a purge gas supply unit configured to supply a purge gas into the substrate container through a gas supply line connected to the substrate container; and an exhaust unit configured to discharge a gas in the substrate container through an exhaust line connected to the substrate container.

Abstract: A plasma processing apparatus includes a process chamber having an inner space, an electrostatic chuck in the process chamber and to which a substrate is mounted, a gas injection unit to inject a process gas into the process chamber at a side of the process chamber, a plasma applying unit to transform the process gas injected into the process chamber into plasma, and a plasma adjusting unit disposed around the electrostatic chuck and operative to adjust the density of the plasma across the substrate.

Abstract: According to a method of controlling uniformity of plasma, a first RF driving pulse signal including first RF pulses is generated by pulsing a first RF signal having a first frequency, and a second RF driving pulse signal including second RF pulses is generated by pulsing a second RF signal having a second, lower frequency. The first and second RF driving signals are applied to a top electrode and/or a bottom electrode of a plasma chamber. A harmonic control signal including harmonic control pulses is generated based on timing of the first and second RF pulses. A harmonic component of the first and second RF driving pulse signals is reduced via intermittent activation and deactivation of a harmonic control circuit as controlled by the harmonic control signal. The uniformity of plasma is improved through the control based on timings of the RF driving pulses.

Abstract: A semiconductor manufacturing apparatus includes a loadlock module including a loadlock chamber in which a substrate container is received, wherein the loadlock module is configured to switch an internal pressure of the loadlock chamber between atmospheric pressure and a vacuum; and a transfer module configured to transfer a substrate between the substrate container received in the loadlock chamber and a process module for performing a semiconductor manufacturing process on the substrate, wherein the loadlock module includes a purge gas supply unit configured to supply a purge gas into the substrate container through a gas supply line connected to the substrate container; and an exhaust unit configured to discharge a gas in the substrate container through an exhaust line connected to the substrate container.

Abstract: In a plasma processing method, a substrate is loaded onto a lower electrode within a chamber. A plasma power is applied to form plasma within the chamber. A voltage function of a nonsinusoidal wave having a DC pulse portion and a ramp portion is generated. Generating the voltage function may include setting a slope of the ramp portion and setting a duration ratio of the ramp portion to a cycle of the voltage function in order to control an ion energy distribution generated at a surface of the substrate. A bias power of the nonsinusoidal wave is applied to the lower electrode.

Abstract: In a plasma processing method, a substrate is loaded onto a lower electrode within a chamber. A plasma power is applied to form plasma within the chamber. A voltage function of a nonsinusoidal wave having a DC pulse portion and a ramp portion is generated. Generating the voltage function may include setting a slope of the ramp portion and setting a duration ratio of the ramp portion to a cycle of the voltage function in order to control an ion energy distribution generated at a surface of the substrate. A bias power of the nonsinusoidal wave is applied to the lower electrode.

Abstract: A substrate support apparatus includes a substrate stage to support a substrate, and a ground ring assembly along a circumference of the substrate stage, the ground ring assembly including a ground ring body, the ground ring body having a plurality of recesses along a circumferential portion thereof, and a plurality of ground blocks movable to be received into respective recesses of the plurality of recesses, the plurality of ground blocks including a conductive material to be electrically grounded.

Abstract: A semiconductor manufacturing apparatus includes a loadlock module including a loadlock chamber in which a substrate container is received, wherein the loadlock module is configured to switch an internal pressure of the loadlock chamber between atmospheric pressure and a vacuum; and a transfer module configured to transfer a substrate between the substrate container received in the loadlock chamber and a process module for performing a semiconductor manufacturing process on the substrate, wherein the loadlock module includes a purge gas supply unit configured to supply a purge gas into the substrate container through a gas supply line connected to the substrate container; and an exhaust unit configured to discharge a gas in the substrate container through an exhaust line connected to the substrate container.

Abstract: A plasma processing apparatus includes a process chamber having an inner space, an electrostatic chuck in the process chamber and to which a substrate is mounted, a gas injection unit to inject a process gas into the process chamber at a side of the process chamber, a plasma applying unit to transform the process gas injected into the process chamber into plasma, and a plasma adjusting unit disposed around the electrostatic chuck and operative to adjust the density of the plasma across the substrate.

Abstract: Provided is a plasma monitoring apparatus including an objective lens configured to collect light that is emitted from plasma and passes through an optical window of a chamber, a beam splitter configured to divide the light collected by the objective lens into first light and second light, a first optical system and a second optical system that are provided on a first optical path of the first light and a second optical path of the second light, respectively, the first optical system and the second optical system having different focal lengths such that focal points of the first optical system and the second optical system are set at different regions in the plasma, and a light detector configured to detect the first light that has passed through the first optical system and the second light that has passed through the second optical system.

Abstract: A plasma processing apparatus includes a process chamber having an inner space, an electrostatic chuck in the process chamber and to which a substrate is mounted, a gas injection unit to inject a process gas into the process chamber at a side of the process chamber, a plasma applying unit to transform the process gas injected into the process chamber into plasma, and a plasma adjusting unit disposed around the electrostatic chuck and operative to adjust the density of the plasma across the substrate.

Abstract: A calibrator of an OES may include a cover, a reference light source and a controller. The cover may be detachably combined with a ceiling of a plasma chamber of a plasma processing apparatus. The reference light source may be installed at the cover to irradiate a reference light to the OES through an inner space of the plasma chamber. The controller may compare a spectrum of the reference light inputted into the OES with a spectrum of an actual light inputted into the OES during a plasma process in the plasma chamber to calibrate the OES. Thus, the OES may be calibrated without disassembling of the OES from the plasma chamber to decrease a time for calibrating the OES.

Abstract: According to a method of controlling uniformity of plasma, a first RF driving pulse signal including first RF pulses is generated by pulsing a first RF signal having a first frequency, and a second RF driving pulse signal including second RF pulses is generated by pulsing a second RF signal having a second, lower frequency. The first and second RF driving signals are applied to a top electrode and/or a bottom electrode of a plasma chamber. A harmonic control signal including harmonic control pulses is generated based on timing of the first and second RF pulses. A harmonic component of the first and second RF driving pulse signals is reduced via intermittent activation and deactivation of a harmonic control circuit as controlled by the harmonic control signal. The uniformity of plasma is improved through the control based on timings of the RF driving pulses.

Abstract: In a plasma processing method, a substrate is loaded onto a lower electrode within a chamber. A plasma power is applied to form plasma within the chamber. A voltage function of a nonsinusoidal wave having a DC pulse portion and a ramp portion is generated. Generating the voltage function may include setting a slope of the ramp portion and setting a duration ratio of the ramp portion to a cycle of the voltage function in order to control an ion energy distribution generated at a surface of the substrate. A bias power of the nonsinusoidal wave is applied to the lower electrode.

Abstract: A plasma processing apparatus includes a substrate chuck having a first surface for supporting a substrate, a second surface opposite to the first surface, and a sidewall, a focus ring for surrounding a perimeter of the substrate, and an edge block for supporting the focus ring. The edge block includes a side electrode on the sidewall of the substrate chuck and a bottom electrode on the second surface of the substrate chuck.

Abstract: Provided is a plasma monitoring apparatus including an objective lens configured to collect light that is emitted from plasma and passes through an optical window of a chamber, a beam splitter configured to divide the light collected by the objective lens into first light and second light, a first optical system and a second optical system that are provided on a first optical path of the first light and a second optical path of the second light, respectively, the first optical system and the second optical system having different focal lengths such that focal points of the first optical system and the second optical system are set at different regions in the plasma, and a light detector configured to detect the first light that has passed through the first optical system and the second light that has passed through the second optical system.

Abstract: A substrate support apparatus includes a substrate stage to support a substrate, and a ground ring assembly along a circumference of the substrate stage, the ground ring assembly including a ground ring body, the ground ring body having a plurality of recesses along a circumferential portion thereof, and a plurality of ground blocks movable to be received into respective recesses of the plurality of recesses, the plurality of ground blocks including a conductive material to be electrically grounded.

Abstract: A semiconductor manufacturing apparatus includes a loadlock module including a loadlock chamber in which a substrate container is received, wherein the loadlock module is configured to switch an internal pressure of the loadlock chamber between atmospheric pressure and a vacuum; and a transfer module configured to transfer a substrate between the substrate container received in the loadlock chamber and a process module for performing a semiconductor manufacturing process on the substrate, wherein the loadlock module includes a purge gas supply unit configured to supply a purge gas into the substrate container through a gas supply line connected to the substrate container; and an exhaust unit configured to discharge a gas in the substrate container through an exhaust line connected to the substrate container.