Abstract: A plasma processing apparatus capable of detecting sealing abnormality of each gate is disclosed. This apparatus includes an outer chamber constituting a vacuum vessel, an inner chamber disposed within the outer chamber for permitting a plasma to be formed in a vacuumed processing chamber as internally provided therein, a workpiece table below the processing chamber for holding thereon a wafer to be processed, a first gate valve disposed in a sidewall of the inner chamber for driving a gate to open and close while the wafer is transferred therethrough, and a second gate valve disposed in a sidewall of the outer chamber for opening and closing a gate while the wafer is transferred therethrough. After the wafer is put on the table, a pressure variation of an intermediate room formed between the inner and outer chambers sealed by the gate valves closed, thereby detecting a decrease in sealing performance.

Abstract: A plasma processing apparatus includes in a processing chamber, a sample stage, a bell jar, a coil antenna, a Faraday shield, and a gas ring member located below a skirt portion of the bell jar and above the sample stage. The gas ring member supplies a process gas to a plasma generating space inside the bell jar from a gas port disposed on an inner surface of the gas ring member. A ring shaped plate is disposed near a periphery of the Faraday shield and having an inner surface facing and covering along the inner surface of the gas ring member and being spaced from the inner surface of the gas ring member so as to delimit a gap therebetween.

Abstract: A vacuum processing apparatus includes a transfer unit disposed at a center thereof, plural processing chambers, each processing chamber having a processing table for supporting an object to be processed and carrying out processing using a gas, and a mass flow controller unit interposed between two of the processing chambers for supplying gas to the chambers.

Abstract: A vacuum processing apparatus includes a transfer unit disposed at a center thereof, plural processing chambers, each processing chamber having a processing table for supporting an object to be processed and carrying out processing using a gas, and a mass flow controller unit interposed between two of the processing chambers for supplying gas to the chambers.

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: A plasma processing method for a plasma processing apparatus which includes, a gas ring, a bell jar, an antenna, a sample table, a Faraday shield, and an RF power source circuit for supplying a power source voltage to the antenna and the Faraday shield. The RF power source circuit includes an RF power source, an antenna connected with the RF power source, a resonance circuit connected in series with the antenna and supplying a resonance voltage, a detection circuit for detecting the resonance voltage of the resonance circuit, and a comparator circuit for comparing the resonance voltage detected by the detection circuit with a predetermined set value. A RF bias voltage is adjusted based on the result of comparison by the comparison circuit.

Abstract: A vacuum processing apparatus comprising a transfer unit disposed at a center thereof, plural processing chambers, each processing chamber having a processing table for supporting an object to be processed and carrying out processing using a gas; and amass flow controller unit interposed between two processing chambers for supplying gas to the chambers.

Abstract: A vacuum processing apparatus includes an outer chamber comprising a vacuum container, an inner chamber in which a plasma used for processing a wafer is generated, the inner chamber being detachably disposed inside of the outer chamber, a wafer holder on which the wafer is located is disposed inside of the inner chamber, and an exhausting device disposed below the wafer holder which exhausts the inside of the inner chamber. The inner chamber is sealed in air-tight manner with respect to a space between the inner chamber and the outer chamber while the space is maintained at a vacuum pressure.

Abstract: The invention provides a plasma processing apparatus and a method for purging the apparatus, capable of preventing damage of components caused by pressure difference during purging operation of a vacuum reactor, and capable of preventing residual processing gas from remaining in the vacuum reactor. Inert gas is introduced through an inert gas feed port 233 on a side wall of a depressurized processing chamber (V1) 226 of a plasma processing apparatus, and the interior of the processing chamber (V1) 226 is brought to predetermined pressure by the inert gas, and thereafter, the inert gas is supplied to processing gas supply paths 213 and 216 (V2) communicated to a plurality of through holes 224 for introducing processing gas, so as to introduce the inert gas through the plurality of through holes 224 into the processing chamber (V1) 226.

Abstract: A plasma processing apparatus includes a gas ring forming a portion of a vacuum processing chamber and having a blowing port for a processing gas, a bell jar to define a vacuum processing chamber, an antenna for supplying an RF electric field into the vacuum processing chamber to form plasmas, a sample table, a Faraday shield, and a deposition preventive plate attached detachably at least to the inner surface of the gas ring excluding the blowing port. An area of the inner surface of the gas ring including the deposition preventive plate that can be viewed from the sample surface is set to about ½ or more of the area of the sample. A susceptor made of a dielectric material covers the outer surface and the outer lateral side of the sample table. A metal film is disposed with respect to the susceptor, and an RF voltage is applied to the metal film.

Abstract: A vacuum processing apparatus that includes an inner wall member disposed inside of an outer side wall member of a vacuum container, the inner wall member surrounding a side of a sample stand on which a sample to be processed is placed and facing to a plasma generated in a chamber inside of the inner wall member. The apparatus also includes an upper member arranged in the vacuum chamber above a flange portion of the inner wall member, contacting with an upper surface of the flange portion and transmitting a force pressing downwardly in a state where the inside of the vacuum container is reduced in pressure. The inner wall member is thermally connected with a temperature adjusting device which controls a temperature of the inner wall member through the upper surface of the flange portion and the upper member.

Abstract: A plasma processing apparatus includes a sample stage disposed at a lower part of a processing chamber, a bell jar made of an insulative material constituting an upper portion of a vacuum vessel, a coil antenna disposed outside and around the bell jar to which electric power is supplied so as to generate the plasma in a plasma generating space inside of the bell jar, and a Faraday shield mounted on the bell jar and disposed between an external surface of the bell jar and the coil antenna. A ring shaped member made of an electric conductive material is disposed inside of an inner surface of a ring portion of the processing chamber located below a skirt portion of the bell jar and constitutes a part of the processing chamber. The ring shaped member extends upwardly so as to cover a portion of an inner surface of the bell jar.

Abstract: A plasma processing apparatus includes in a processing chamber, a sample stage, a bell jar, a coil antenna, a Faraday shield, and a gas ring member located below a skirt portion of the bell jar and above the sample stage. The gas ring member supplies a process gas to a plasma generating space inside the bell jar from a gas port disposed on an inner surface of the gas ring member. A ring shaped plate is disposed near a periphery of the Faraday shield and having an inner surface facing and covering along the inner surface of the gas ring member and being spaced from the inner surface of the gas ring member so as to delimit a gap therebetween.

Abstract: A vacuum processing apparatus comprising a transfer unit disposed at a center thereof, plural processing chambers, each processing chamber having a processing table for supporting an object to be processed and carrying out processing using a gas; and amass flow controller unit interposed between two processing chambers for supplying gas to the chambers.

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 vacuum processing apparatus includes an outer chamber comprising a vacuum container, an inner chamber in which a plasma used for processing a wafer is generated, the inner chamber being detachably disposed inside of the outer chamber, a wafer holder on which the wafer is located is disposed inside of the inner chamber, and an exhausting device disposed below the wafer holder which exhausts the inside of the inner chamber. The inner chamber is sealed in air-tight manner with respect to a space between the inner chamber and the outer chamber while the space is maintained at a vacuum pressure.

Abstract: Described is a vacuum processing apparatus that includes a vacuum container which has a processing chamber inside thereof, wherein a plasma used for processing a sample is formed inside the processing chamber. The processing chamber has an upper side wall which surrounds a space in which the plasma is formed and contacts the plasma, and a lower side wall inside of which a sample stand, supporting the sample to be processed, is arranged. A connecting portion is provided between the upper and lower side walls, and a heater is provided for heating the upper side wall. The apparatus also includes structure at the connecting portion to impede heat transfer between the upper and lower side walls.

Abstract: A vacuum processing apparatus includes a transfer unit disposed at a center thereof, plural processing chambers, each processing chamber having a processing table for supporting an object to be processed and carrying out processing using a gas, and a mass flow controller unit interposed between two of the processing chambers for supplying gas to the chambers.

Abstract: The invention provides a semiconductor processing apparatus having a high throughput capable of appropriately coping with the positional displacement that may occur during transfer of the wafer after correcting the position thereof, without slowing down the transfer speed of the wafer. A position correction quantity of the wafer with respect to a vacuum robot is computed based on the outputs of a ? axis sensor for detecting the interception angle of the wafer during rotation of the vacuum robot and an R axis sensor for detecting the interception distance of the wafer during expansion and contraction of the vacuum robot. If the position correction quantity exceeds a predetermined standard value, an operation to change the position data is performed, and if the distance data obtained based on the outputs from the ? axis sensor and the R axis sensor exceeds a predetermined permissible value, it is determined that a displacement error has occurred and the operation is stopped.

Abstract: A vacuum processing apparatus comprising a transfer unit disposed at a center thereof, plural processing chambers, each processing chamber having a processing table for supporting an object to be processed and carrying out processing using a gas; and a mass flow controller unit interposed between two processing chambers for supplying gas to the chambers.