Abstract: A prediction method includes a calculation process and a prediction process. The calculation process calculates a correlation between a spatial distribution value of a magnetic field in a chamber when a plasma etching process is performed on a substrate disposed in the chamber, and a process result of the plasma etching process on the substrate. The prediction process predicts the process result of the plasma etching process on the substrate from the spatial distribution value of the magnetic field in the chamber based on the calculated correlation.

Abstract: To achieve properties such as a desirable compression fracture property, desirable compression set, and the like in the elastomer composition and the seal material using same. The elastomer composition of the present disclosure therefore includes an elastomer, phenol resin in powder form, and silica in powder form. The seal material of the present disclosure is obtained by crosslinking and molding the elastomer composition of the present disclosure. The seal material may be used in a semiconductor manufacturing device.

Abstract: The present disclosure provides a non-transitory computer-readable storage medium storing a control program of a plasma processing apparatus which performs a plasma processing by supplying a source power to a plasma generator and supplying a bias power to a stage that places a processing target substrate thereon. The control program causes a computer to execute a process including: monitoring a peak-to-peak voltage value of the source power or the bias power; and correcting the source power supplied to the plasma generator and the bias power supplied to the stage according to a fluctuation of the peak-to-peak voltage value, to make the monitored peak-to-peak voltage value approach an initial set value while fixing a ratio of the source power and the bias power.

Abstract: A plasma processing apparatus includes a pedestal to receive a substrate thereon; a temperature control mechanism provided in the pedestal; a heat transfer gas supply mechanism configured to supply a heat transfer gas to a back surface of the substrate; a first radio frequency power source configured to output first high frequency power having a first frequency; a second radio frequency power source configured to output second high frequency power having a second frequency that is lower than the first frequency; and a temperature measurement unit configured to control a surface temperature of the substrate to have a temperature lower than ?35 degrees C. by using the temperature control mechanism provided in the pedestal and to perform feedback control of stopping the output of the second radio frequency power from the second radio frequency power source.

Abstract: An etching method performed by an etching apparatus includes a first process of causing a first high-frequency power supply to output a first high-frequency power with a first frequency and causing a second high-frequency power supply to output a second high-frequency power with a second frequency lower than the first frequency in a cryogenic environment where the temperature of a wafer is ?35° C. or lower, to generate plasma from a hydrogen-containing gas and a fluorine-containing gas and to etch, with the plasma, a multi-layer film of silicon dioxide and silicon nitride and a single-layer film of silicon dioxide that are formed on the wafer; and a second process of stopping the output of the second high-frequency power supply. The first process and the second process are repeated multiple times, and the first process is shorter in time than the second process.

Abstract: An etching method performed by an etching apparatus includes a first process of causing a first high-frequency power supply to output a first high-frequency power with a first frequency and causing a second high-frequency power supply to output a second high-frequency power with a second frequency lower than the first frequency in a cryogenic environment where the temperature of a wafer is ?35° C. or lower, to generate plasma from a hydrogen-containing gas and a fluorine-containing gas and to etch, with the plasma, a multi-layer film of silicon dioxide and silicon nitride and a single-layer film of silicon dioxide that are formed on the wafer; and a second process of stopping the output of the second high-frequency power supply. The first process and the second process are repeated multiple times, and the first process is shorter in time than the second process.

Abstract: A plasma processing apparatus includes a pedestal to receive a substrate thereon; a temperature control mechanism provided in the pedestal; a heat transfer gas supply mechanism configured to supply a heat transfer gas to a back surface of the substrate; a first radio frequency power source configured to output first high frequency power having a first frequency; a second radio frequency power source configured to output second high frequency power having a second frequency that is lower than the first frequency; and a temperature measurement unit configured to control a surface temperature of the substrate to have a temperature lower than ?35 degrees C. by using the temperature control mechanism provided in the pedestal and to perform feedback control of stopping the output of the second radio frequency power from the second radio frequency power source.

Abstract: An etching method performed by an etching apparatus includes a first process of causing a first high-frequency power supply to output a first high-frequency power with a first frequency and causing a second high-frequency power supply to output a second high-frequency power with a second frequency lower than the first frequency in a cryogenic environment where the temperature of a wafer is ?35° C. or lower, to generate plasma from a hydrogen-containing gas and a fluorine-containing gas and to etch, with the plasma, a multi-layer film of silicon dioxide and silicon nitride and a single-layer film of silicon dioxide that are formed on the wafer; and a second process of stopping the output of the second high-frequency power supply. The first process and the second process are repeated multiple times, and the first process is shorter in time than the second process.

Abstract: An etching method is provided. In the etching method, a silicon oxide film is etched by using plasma in a first condition. In the first condition, a surface temperature of a substrate is controlled to have a temperature lower than ?35 degrees C., and the plasma is generated from a hydrogen-containing gas and a fluorine-containing gas by using first radio frequency power output from a first radio frequency power source and second radio frequency power output from a second radio frequency power source. Next, the silicon oxide film is etched by using the plasma in a second condition. In the second condition, the output of the second radio frequency power from the second radio frequency power source is stopped. The silicon oxide film is etched by using the plasma alternately in the first condition and in the second condition multiple times.

Abstract: An etching method performed by an etching apparatus includes a first process of causing a first high-frequency power supply to output a first high-frequency power with a first frequency and causing a second high-frequency power supply to output a second high-frequency power with a second frequency lower than the first frequency in a cryogenic environment where the temperature of a wafer is ?35° C. or lower, to generate plasma from a hydrogen-containing gas and a fluorine-containing gas and to etch, with the plasma, a multi-layer film of silicon dioxide and silicon nitride and a single-layer film of silicon dioxide that are formed on the wafer; and a second process of stopping the output of the second high-frequency power supply. The first process and the second process are repeated multiple times, and the first process is shorter in time than the second process.

Abstract: An etching method is provided. In the etching method, a temperature of a chiller configured to cool a pedestal is controlled so as to become ?20 degrees C. or lower. Plasma is generated from a hydrogen-containing gas and a fluoride-containing gas supplied from a gas supply source by supplying first high frequency power having a first frequency supplied to the pedestal from a first high frequency power source. A silicon oxide film deposited on a substrate placed on the pedestal is etched by the generated plasma. Second high frequency power having a second frequency lower than the first frequency of the first high frequency power is supplied to the pedestal from a second high frequency power source in a static eliminating process after the step of etching the silicon oxide film.

Abstract: Provided is a plasma etching method capable of favorably forming masks used when etching a multilayer film. This plasma etching method for etching boron-doped amorphous carbon involves using a plasma of a gas mixture comprising a chlorine gas and an oxygen gas, and setting the temperature of a mounting stage (3) to 100° C. or greater.

Abstract: An etching method is provided. In the etching method, a silicon oxide film is etched by using plasma in a first condition. In the first condition, a surface temperature of a substrate is controlled to have a temperature lower than ?35 degrees C., and the plasma is generated from a hydrogen-containing gas and a fluorine-containing gas by using first radio frequency power output from a first radio frequency power source and second radio frequency power output from a second radio frequency power source. Next, the silicon oxide film is etched by using the plasma in a second condition. In the second condition, the output of the second radio frequency power from the second radio frequency power source is stopped. The silicon oxide film is etched by using the plasma alternately in the first condition and in the second condition multiple times.

Abstract: An etching method is provided. In the etching method, a temperature of a chiller configured to cool a pedestal is controlled so as to become ?20 degrees C. or lower. Plasma is generated from a hydrogen-containing gas and a fluoride-containing gas supplied from a gas supply source by supplying first high frequency power having a first frequency supplied to the pedestal from a first high frequency power source. A silicon oxide film deposited on a substrate placed on the pedestal is etched by the generated plasma. Second high frequency power having a second frequency lower than the first frequency of the first high frequency power is supplied to the pedestal from a second high frequency power source in a static eliminating process after the step of etching the silicon oxide film.

Abstract: Provided is a plasma etching method capable of favorably forming masks used when etching a multilayer film. This plasma etching method for etching boron-doped amorphous carbon involves using a plasma of a gas mixture comprising a chlorine gas and an oxygen gas, and setting the temperature of a mounting stage (3) to 100° C. or greater.