Abstract: An isolation amplifier of an embodiment includes: a primary circuit including an encoder configured to encode an input signal and output the encoded input signal and an anomaly detection circuit configured to detect anomaly having occurred to the input signal and generate a detection signal; an isolation unit configured to insulate the primary circuit from a secondary circuit; an output circuit configured to generate an output signal corresponding to the input signal; and an anomaly-input sensing-output circuit configured to generate an output signal from the secondary circuit by changing the output signal from the output circuit based on the detection signal.

Abstract: A connector (50) includes a tubular member (52) and a base tube (58). A light-guiding tube (60) is drawn out from the base tube (58) toward the opposite side to the tubular member (52). An adapter (1) includes: a first connecting portion (10) that can be connected to and disconnected from a light source device (70); a second connecting portion (20) that can be connected to and disconnected from the connector (50); and a light-guiding member (30) that guides light emitted from the light source device (70) to a proximal end surface (61) of the tube (60).

Abstract: A disclosed plasma processing apparatus includes a chamber, a substrate support, an electric path, and a measuring device. The substrate support is accommodated in the chamber. The electric path is coupled to or capacitively coupled to an edge ring on the substrate support. The measuring device measures an electrical characteristic value of the edge ring with a voltage applied to the edge ring on the substrate support through the electric path. The electrical characteristic value measured by the measuring device is variable in accordance with a thickness of the edge ring.

Abstract: A method of high-throughput dry etching of silicon oxide and silicon nitride materials by in-situ autocatalyst formation. The method includes providing a substrate having a film thereon in a process chamber, the film containing silicon oxide, silicon nitride, or both silicon oxide and silicon nitride, introducing an etching gas containing fluorine and hydrogen, and setting a gas pressure in the process chamber that is between about 1 mTorr and about 300 mTorr, and a substrate temperature that is below about ?30° C. The method further includes plasma-exciting the etching gas, and exposing the film to the plasma-excited etching gas, where the film is continuously etched during the exposing.

Abstract: A disclosed plasma processing apparatus includes a chamber, a substrate support, an electric path, and a measuring device. The substrate support is accommodated in the chamber. The electric path is coupled to or capacitively coupled to an edge ring on the substrate support. The measuring device measures an electrical characteristic value of the edge ring with a voltage applied to the edge ring on the substrate support through the electric path. The electrical characteristic value measured by the measuring device is variable in accordance with a thickness of the edge ring.

Abstract: A plasma processing apparatus includes a process container that forms a process space to accommodate a target substrate, and a first electrode and a second electrode disposed opposite each other inside the process container. The first electrode is an upper electrode and the second electrode is a lower electrode and configured to support the target substrate through a mount face. A correction ring is disposed to surround the target substrate placed on the mount face of the second electrode. The correction ring includes a combination of a first ring to be around the target substrate and a second ring arranged around or above the first ring. A power supply unit is configured to apply a first electric potential and a second electric potential respectively to the first ring and the second ring to generate a potential difference between the first and second rings. The power supply unit is configured to variably set the potential difference.

Abstract: A plasma processing method includes executing an etching process that includes supplying an etching gas into a process container in which a target substrate is supported on a second electrode serving as a lower electrode, and applying an RF power for plasma generation and an RF power for ion attraction to turn the etching gas into plasma and to subject the target substrate to etching. The etching process includes applying a negative DC voltage to a first electrode serving as an upper electrode during the etching to increase an absolute value of self-bias on the first electrode. The etching process includes releasing DC electron current generated by the negative DC voltage to ground through plasma and a conductive member disposed as a ring around the first electrode, by using a first state where the conductive member is connected to a ground potential portion.

Abstract: A plasma processing method includes executing an etching process that includes supplying an etching gas into a process container in which a target substrate is supported on a second electrode serving as a lower electrode, and applying an RF power for plasma generation and an RF power for ion attraction to turn the etching gas into plasma and to subject the target substrate to etching. The etching process includes applying a negative DC voltage to a first electrode serving as an upper electrode during the etching to increase an absolute value of self-bias on the first electrode. The etching process includes releasing DC electron current generated by the negative DC voltage to ground through plasma and a conductive member disposed as a ring around the first electrode, by using a first state where the conductive member is connected to a ground potential portion.

Abstract: A plasma etching apparatus includes an upper electrode and a lower electrode, between which plasma of a process gas is generated to perform plasma etching on a wafer W. The apparatus further comprises a cooling ring disposed around the wafer, a correction ring disposed around the cooling ring, and a variable DC power supply directly connected to the correction ring, the DC voltage being preset to provide the correction ring with a negative bias, relative to ground potential, for attracting ions in the plasma and to increase temperature of the correction ring to compensate for a decrease in temperature of a space near the edge of the target substrate due to the cooling ring.

Abstract: An apparatus includes an upper electrode and a lower electrode for supporting a wafer disposed opposite each other within a process chamber. A first RF power supply configured to apply a first RF power having a relatively higher frequency, and a second RF power supply configured to apply a second RF power having a relatively lower frequency is connected to the lower electrode. A variable DC power supply is connected to the upper electrode. A process gas is supplied into the process chamber to generate plasma of the process gas so as to perform plasma etching.

Abstract: Provided is a capacitively coupled plasma processing apparatus which improves a controllability of the RF bias function and reliably prevents unwanted resonance from being generated on a RF transmission line between a counter electrode and ground potential to enhance reliability of the plasma process. In the capacitive coupled type plasma processing apparatus, three kinds of RF powers from a first, second and third RF power supplies (35, 36, 38) are superimposed and applied to susceptor (lower electrode) (16). In such a three-frequency superimposing and applying application scheme, the frequency-impedance characteristic around upper electrode (48) is considered to prevent a serial resonance from occurring on an RF transmission line around upper electrode (48) in consideration of all the low order frequencies of the IMD relevant to and affecting the plasma process.

Abstract: A plasma processing apparatus and a plasma processing method are provided which can sufficiently suppress an abnormal discharge in a gas space. A plasma processing apparatus includes a high frequency power source connected between a processing chamber and a base stand; a gas storage unit provided within the base stand and configured to store a gas; a blocking mechanism configured to block a gas introducing port of the gas storage unit; and a connection unit configured to connect a space between a disposition position of a wafer and the base stand, to the gas storage unit.

Abstract: An apparatus includes an upper electrode and a lower electrode for supporting a wafer disposed opposite each other within a process chamber. A first RF power supply configured to apply a first RF power having a relatively higher frequency, and a second RF power supply configured to apply a second RF power having a relatively lower frequency is connected to the lower electrode. A variable DC power supply is connected to the upper electrode. A process gas is supplied into the process chamber to generate plasma of the process gas so as to perform plasma etching.

Abstract: A plasma etching apparatus includes an upper electrode and a lower electrode, between which plasma of a process gas is generated to perform plasma etching on a wafer W. The apparatus further comprises a cooling ring disposed around the wafer, a correction ring disposed around the cooling ring, and a variable DC power supply directly connected to the correction ring, the DC voltage being preset to provide the correction ring with a negative bias, relative to ground potential, for attracting ions in the plasma and to increase temperature of the correction ring to compensate for a decrease in temperature of a space near the edge of the target substrate due to the cooling ring.

Abstract: An apparatus includes an upper electrode and a lower electrode for supporting a wafer disposed opposite each other within a process chamber. A first RF power supply configured to apply a first RF power having a relatively higher frequency is connected to the upper electrode. A second RF power supply configured to apply a second RF power having a relatively lower frequency is connected to the lower electrode. A variable DC power supply is connected to the upper electrode. A process gas is supplied into the process chamber while any one of application voltage, application current, and application power from the variable DC power supply to the upper electrode is controlled, to generate plasma of the process gas so as to perform plasma etching.

Abstract: A plasma processing apparatus includes a first and second electrodes disposed on upper and lower sides and opposite each other within a process container, a first RF power application unit and a DC power supply both connected to the first electrode, and second and third radio frequency power application units both connected to the second electrode. A conductive member is disposed within the process container and grounded to release through plasma a current caused by a DC voltage applied from the DC power supply. The conductive member is supported by a first shield part around the second electrode and laterally protruding therefrom at a position between the mount face of the second electrode and an exhaust plate for the conductive member to be exposed to the plasma. The conductive member is grounded through a conductive internal body of the first shield part.

Abstract: A plasma processing apparatus includes a processing chamber; a conductive base within the processing chamber; an electrostatic chuck, having an electrode, provided on the base; a high frequency power supply that applies a high frequency power to the base; a first DC power supply that applies a DC voltage to the electrostatic chuck; and a plasma generation unit that generates plasma of a processing gas within the processing chamber. A plasma processing method performed in the plasma processing apparatus includes connecting the first DC power supply to the electrode of the electrostatic chuck; cutting off connection between the first DC power supply and the electrode of the electrostatic chuck; and generating the plasma within the processing chamber by applying the high frequency power to the base in a state that the connection between the first DC power supply and the electrode of the electrostatic chuck is cut off.

Abstract: In a plasma etching apparatus, a first high frequency for plasma generation and a second high frequency for ion attraction are respectively applied from two high frequency supplies to a susceptor. Further, DC voltage is applied from a variable DC power supply to an upper electrode via a filter circuit. An annular DC ground part attached to an upper side surface of the susceptor is connected to a filter circuit. This filter circuit allows a specific frequency component of the intermodulation distortion generated in a plasma by a series resonant to selectively flow to a ground line.

Abstract: A degree of tilting caused by consumption of a focus ring can be suppressed. A plasma processing apparatus includes a chamber configured to perform a plasma process on a target object; a mounting table which is provided within the chamber and has a mounting surface on which the target object is mounted; and the focus ring, provided on the mounting table to surround the target object mounted on the mounting surface, having a first flat portion lower than the mounting surface, a second flat portion higher than the first flat portion and not higher than a target surface of the target object, and a third flat portion higher than the second flat portion and the target surface of the target object in sequence from an inner peripheral side thereof to an outer peripheral side thereof.

Abstract: Provided is a chamber cleaning method capable of efficiently removing a CF-based shoulder deposit containing Si and Al deposited on an outer periphery of an ESC. A mixed gas of an O2 gas and a F containing gas is supplied toward an outer periphery 24a of an ESC 24 at a pressure ranging from about 400 mTorr to about 800 mTorr; plasma generated from the mixed gas is irradiated onto the outer periphery 24a of the ESC 24; an O2 single gas as a mask gas is supplied to the top surface of ESC 24 except the outer periphery 24a; and the shoulder deposit 50 adhered to the outer periphery 24a is decomposed and removed while preventing the top surface of ESC 24 except the outer periphery 24a from being exposed to a F radical.