Abstract: In a plasma processing apparatus including a vacuum chamber, a sample table for mounting a member to be processed thereon, the sample table having a coolant path to control a temperature of the member to be processed, an electrostatic chuck power supply for electrostatically adsorbing the member to be processed on the sample table, and a plurality of gas hole parts provided in the sample table to supply heat transfer gas between the member to be processed and the sample table and thereby control a temperature of the member to be processed, each of the gas hole parts includes a boss formed of a dielectric, a sleeve, and a plurality of small tubes, and the small tubes are arranged in a range of 10 to 50% of a radius when measured from a center of the gas hole part toward outside.

Abstract: A plasma processing apparatus wherein a layer structure consisting of plural layers formed in stack one upon another on a semiconductor wafer placed on the sample holder located in the process chamber, is etched with plasma generated in the process chamber by supplying high frequency power to the electrode disposed in the sample holder, the apparatus comprising a ring-shaped electrode disposed above the electrode and around the periphery of the top portion of the sample holder, an outer circumferential ring of dielectric material disposed above the ring-shaped electrode and opposite to the plasma, and a power source for supplying power at different values to the ring-shaped electrode depending on the sorts of layers of the layer structure.

Abstract: An apparatus for treating with plasma a specimen mounted on a specimen table and a next specimen mounted thereon after the treatment of the specimen is completed in a vacuumed container, comprises, a detector for measuring a temperature of the specimen table, and an adjustor for adjusting the temperature of the specimen table obtained when the next specimen is treated to have a value determined from a predetermined change in temperature of the specimen and one of the temperature of the specimen table measured by the detector and a temperature of returning refrigerant obtained after the treatment of the specimen is started, wherein the adjustor obtains the predetermined change in temperature of the specimen from the temperatures of the specimen measured in respective conditions in each of which conditions the treatment is continued until a changing rate of the temperature of the specimen becomes not more than a predetermined degree.

Abstract: A plasma processing method includes mounting a workpiece to be processed on an upper surface of a sample table disposed at a lower portion of an interior of a processing chamber disposed within a vacuum vessel and processing the workpiece by use of plasma formed within the processing chamber while applying thereto a first high frequency power for adjustment of a surface potential of the workpiece which is disposed on the sample table. The method further includes starting, prior to application of the first high frequency power, to adjust a temperature of a heat exchange medium flowing in a passage disposed inside of the sample table so as to have a predetermined value based on information of this high frequency power.

Abstract: A plasma processing apparatus includes a processing chamber disposed within a vacuum vessel for forming therein a plasma, a sample table disposed beneath the processing chamber for mounting on its upper surface a workpiece to be processed, an electrode disposed within the sample table for allowing application of high frequency power for adjustment of a surface potential of the workpiece, a passage disposed within the sample table for causing a refrigerant to flow therein, and a control device for adjusting a temperature of the refrigerant flowing in the passage. The workpiece is processed using a plasma created within the processing chamber under application of the high frequency power. Before application of the high frequency power, the control device starts to adjust the temperature of the refrigerant based on information of the high frequency power so that it has a predetermined value.

Abstract: A vacuum processing apparatus includes a vacuum container which can be depressurized, a sample holder inside of the vacuum container for mounting a sample to be processed, wherein films laid over a surface of the sample are etched with plasma generated in a space above the sample holder. The apparatus further includes a gas supply channel for feeding a heat conducting gas between a sample mounting surface and the backside of the sample, and a pressure control unit for changing stepwise the pressure of the gas supply channel between the sample mounting surface and the backside of the sample in accordance with the progress of the processing of the films of the sample by the etching.

Abstract: A plasma processing apparatus wherein a layer structure consisting of plural layers formed in stack one upon another on a semiconductor wafer placed on the sample holder located in the process chamber, is etched with plasma generated in the process chamber by supplying high frequency power to the electrode disposed in the sample holder, the apparatus comprising a ring-shaped electrode disposed above the electrode and around the periphery of the top portion of the sample holder, an outer circumferential ring of dielectric material disposed above the ring-shaped electrode and opposite to the plasma, and a power source for supplying power at different values to the ring-shaped electrode depending on the sorts of layers of the layer structure.

Abstract: A plasma processing method for processing a sample by reducing a pressure within a processing chamber, including mounting the sample on a sample holder disposed in the processing chamber, and processing using a plasma generated in the processing chamber above the sample holder while supplying a gas for heat transfer to a space between a surface of the sample holder having the sample mounted thereon and a rear surface of the sample. The sample holder has a plurality of substantially ring-shaped depressed portions at the surface where the sample is mounted. A pressure in a space between the depressed portions arranged at a central portion of the sample holder with respect to outer circumferential portion and the sample is set to be lower than a pressure in a space between the depressed portions at the outer circumferential portion and the sample.

Abstract: A plasma processing method for processing a sample by reducing a pressure within a processing chamber, including mounting the sample on a sample holder disposed in the processing chamber, and processing using a plasma generated in the processing chamber above the sample holder while supplying a gas for heat transfer to a space between a surface of the sample holder having the sample mounted thereon and a rear surface of the sample. The sample holder has a plurality of substantially ring-shaped depressed portions at the surface where the sample is mounted. A pressure in a space between the depressed portions arranged at a central portion of the sample holder with respect to outer circumferential portion and the sample is set to be lower than a pressure in a space between the depressed portions at the outer circumferential portion and the sample.

Abstract: A vacuum processing method includes mounting a sample to be processed on a sample mounting surface on a sample holder placed in a vacuum container whose inside can be depressurized, feeding a processing gas and electric field to a space above the sample holder inside of the vacuum container to generate plasma, and etching films of a plurality of layers laid over the surface of the sample into a predetermined shape. A heat conducting gas is fed between the sample mounting surface and the backside of the sample, and at the same time, the pressure of the heat conducting gas is changed stepwise in accordance with the progress of the processing of the films of a plurality of layers of the sample.

Abstract: An electrostatic chuck which is built in a heater and can change, at a high speed, the temperature distribution of a wafer being processed by a plasma is provided at low cost. Also, there is provided a processing method which realizes uniform etching by suppressing CD variations in the plane of the wafer even when etching conditions change. The electrostatic chuck includes a base material in which multiple coolant grooves are formed, a high resistance layer which is formed on the base material, multiple heaters which are formed by thermally spraying conductors within the high resistance layer, multiple electrostatic chuck electrodes which are formed similarly by thermally spraying conductors within the high resistance layer, and temperature measuring means, and adjusts outputs of the heaters on the basis of temperature information of the temperature measuring means.

Abstract: A plasma processing apparatus includes a processing chamber disposed within a vacuum vessel for forming therein a plasma, a sample table disposed beneath the processing chamber for mounting on its upper surface a workpiece to be processed, an electrode disposed within the sample table for allowing application of high frequency power for adjustment of a surface potential of the workpiece, a passage disposed within the sample table for causing a refrigerant to flow therein, and a control device for adjusting a temperature of the refrigerant flowing in the passage. The workpiece is processed using a plasma created within the processing chamber under application of the high frequency power. Before application of the high frequency power, the control device starts to adjust the temperature of the refrigerant based on information of the high frequency power so that it has a predetermined value.

Abstract: Provided is a vacuum processing apparatus or processing method which, when films of a plurality of layers are etched into a predetermined shape, eliminates a deficiency in shape formed by sample processing, increases the aspect ratio of the processed shape, and provides a more precise shape.

Abstract: A plasma processing method for processing a sample by reducing a pressure within a processing chamber, including mounting the sample on a sample holder disposed in the processing chamber, and processing using a plasma generated in the processing chamber above the sample holder while supplying a gas for heat transfer to a space between a surface of the sample holder having the sample mounted thereon and a rear surface of the sample. The sample holder has a plurality of substantially ring-shaped depressed portions at the surface where the sample is mounted. A pressure in a space between the depressed portions arranged at a central portion of the sample holder with respect to outer circumferential portion and the sample is set to be lower than a pressure in a space between the depressed portions at the outer circumferential portion and the sample.

Abstract: A plasma processing apparatus capable of processing a sample with high precision by adjusting the temperature of a wafer in a wide range is provided.

Abstract: A video conversation/monitoring system having a remote monitoring function includes a center station and multiple end stations linked through the ISDN network. The center station includes a video conversation/monitoring circuit, video input device, video output device, audio input device, audio output device, system controller, facsimile, and ISDN line terminating unit. Each end station includes a video conversation/monitoring circuit, system controller, first video input device, second video input device, audio input device, audio output device, calling device, first notification device, second notification device, detection device, facsimile, and ISDN line terminating unit. Based on the remote monitoring function of the video input device and the remote control function of the system controller for switching the video input device, various guidance services are accomplished in addition to the video-phonic conversation service.

Abstract: A video conversation/monitoring system, having a remote monitoring function and a remote peripheral device control function in addition to a video-phonic conversation function, includes a center station linked to multiple end stations through an ISDN network. The center station includes a video conversation/monitoring unit, a conversation camera, a monitor screen, a conversation microphone, a conversation speaker, a system controller, a facsimile, and an ISDN line terminating unit. Each end station includes a video conversation/monitoring unit, a system controller, a monitoring camera, a conversation camera, a conversation microphone, a conversation speaker, a sending key set for making calls, a first notification device, a second notification device, a detection device, a facsimile, and an ISDN line terminating unit.