Abstract: Bending of a hole or a groove formed in a multilayered film including silicon oxide films and silicon nitride films alternately stacked on top of each other is suppressed. A plasma etching method includes a first etching process of etching, by plasma, the multilayered film including the silicon oxide films and the silicon nitride films alternately stacked on top of each other; and a second etching process of etching, by plasma, the multilayered film under a processing condition that an inclination of a portion of an inner sidewall of the hole or the groove, which is formed by the etching of the multilayered film, corresponding to the silicon nitride film with respect to a depth direction of the hole or the groove is reduced.

Abstract: First and second silicon containing films can be etched selectively against each other with high efficiency. A method includes preparing a processing target object within a chamber; etching the first silicon containing film of the processing target object by generating plasma of a processing gas within the chamber in a state that a temperature of the processing target object is set to a first temperature; and etching the second silicon containing film of the processing target object by generating the plasma of the processing gas within the chamber in a state that the temperature of the processing target object is set to a second temperature higher than the first temperature.

Abstract: A deposit on a target object can be removed or the amount thereof can be reduced after plasma etching is completed and before the target object is carried out of a chamber. A method of processing the target object is provided. The method includes etching including a main etching of etching an etching target film of the target object placed on a stage at a low temperature by generating plasma of a processing gas containing a fluorocarbon gas and/or a hydrofluorocarbon gas; raising, immediately after the etching is performed or immediately after the main etching is performed, a temperature of an electrostatic chuck; and carrying-out the target object from the chamber in a state that the temperature of the electrostatic chuck is set to a high temperature.

Abstract: Silicon oxide and silicon nitride can be etched selectively against each other with high efficiency. A method includes preparing a processing target object within a chamber; etching the silicon oxide of the processing target object by generating plasma of a processing gas containing carbon, hydrogen and fluorine within the chamber in a state that a temperature of the processing target object is set to a first temperature; and etching the silicon nitride of the processing target object by generating the plasma of the processing gas containing carbon, hydrogen and fluorine within the chamber in a state that the temperature of the processing target object is set to a second temperature higher than the first temperature.

Abstract: A method of etching a multilayered film including multiple silicon oxide films and multiple silicon nitride films is provided. A mask containing carbon is provided on the multilayered film. The method includes performing a first plasma processing and performing a second plasma processing. In the performing of the first plasma processing and in the performing of the second plasma processing, plasma of a processing gas is generated within a chamber in a state that a temperature of an electrostatic chuck, on which a processing target object is placed, is set to be equal to or less than ?15° C. The processing gas contains a hydrogen atom, a fluorine atom, a carbon atom and an oxygen atom, and also contains a sulfur-containing gas. A pressure of the chamber in the performing of the first plasma processing is set to be lower than that in the performing of the second plasma processing.

Abstract: A deposit on a target object can be removed or the amount thereof can be reduced after plasma etching is completed and before the target object is carried out of a chamber. A method of processing the target object is provided. The method includes etching including a main etching of etching an etching target film of the target object placed on a stage at a low temperature by generating plasma of a processing gas containing a fluorocarbon gas and/or a hydrofluorocarbon gas; raising, immediately after the etching is performed or immediately after the main etching is performed, a temperature of an electrostatic chuck; and carrying-out the target object from the chamber in a state that the temperature of the electrostatic chuck is set to a high temperature.

Abstract: A time period for cleaning performed to remove a deposit formed within a chamber main body can be reduced. A plasma processing method including the cleaning of an inside of the chamber main body of a plasma processing apparatus is provided. The method includes etching including a main etching of etching an etching target film of a processing target object placed on a stage in a low temperature by generating plasma of a processing gas containing a fluorocarbon gas and/or a hydrofluorocarbon gas; carrying-out the processing target object from a chamber; and cleaning the inside of the chamber main body by generating plasma of a cleaning gas in a state that a temperature of an electrostatic chuck is set to be high.

Abstract: Silicon oxide and silicon nitride can be etched selectively against each other with high efficiency. A method includes preparing a processing target object within a chamber; etching the silicon oxide of the processing target object by generating plasma of a processing gas containing carbon, hydrogen and fluorine within the chamber in a state that a temperature of the processing target object is set to a first temperature; and etching the silicon nitride of the processing target object by generating the plasma of the processing gas containing carbon, hydrogen and fluorine within the chamber in a state that the temperature of the processing target object is set to a second temperature higher than the first temperature.

Abstract: An etching method includes a cooling process of controlling a temperature of a processing target object provided within a processing vessel to ?20° C. or less; a generating process of generating plasma of a processing gas containing hydrogen atoms, fluorine atoms, carbon atoms and oxygen atoms within the processing vessel; and an etching process of etching a region by using the plasma. The processing gas is a mixed gas of a first gas, a second gas and an oxygen atom-containing gas which are different from each other. A mixed gas of the first gas and the second gas contains the hydrogen atoms, the fluorine atoms and the carbon atoms. A ratio between a number of the hydrogen atoms and a number of the fluorine atoms contained in the first gas is different from that in the second gas.

Abstract: An etching method for etching a silicon oxide film is provided that includes generating a plasma from a gas including a hydrogen-containing gas and a fluorine-containing gas using a high frequency power for plasma generation, and etching the silicon oxide film using the generated plasma. The fluorine-containing gas includes a hydrofluorocarbon gas, and the sticking coefficient of radicals generated from the hydrofluorocarbon gas is higher than the sticking coefficient of radicals generated from carbon tetrafluoride (CF4).

Abstract: A mounting table includes a base and an electrostatic chuck provided on the base. The base has first and second top surface on which the electrostatic chuck and a focus ring are respectively provided. The second top surface is provided below the first top surface. A coolant path in the base has central and peripheral paths extending below the first and second top surfaces, respectively. The peripheral path has a portion extending along a side surface toward the first top surface. The mounting surface has central and peripheral regions. The mounting surface has protrusions formed in a dot shape. The protrusions are formed such that a contact area between the protrusions of the peripheral region and the backside of an object per unit area becomes greater than a contact area between the protrusions of the central region and the backside of the object per unit area.