Abstract: An ion beam etching device includes a grid provided between a treatment chamber and a plasma generation chamber, and for forming an ion beam by drawing ions from the plasma generation chamber; a gas introduction unit for introducing discharge gas into the plasma generation chamber; an exhaust for exhausting the treatment chamber; a substrate holder; a control unit to receive a measurement result of an in-plane film thickness distribution before the substrate is processed; and an electromagnetic coil provided outside of the plasma generation chamber in a ceiling portion opposite to the grid of the plasma generation chamber. The electromagnetic coil includes an outer coil provided on an outer circumference of the ceiling portion and an inner coil provided on an inner circumference of the ceiling portion, and the control unit controls the currents applied to the outer coil and the inner coil in accordance with the measurement result.

Abstract: Provided is a plasma treatment apparatus capable of uniform substrate treatment by correction of unevenness in a plasma density distribution. The apparatus has a configuration such that a substrate is treated with plasma, and an evacuated container is provided with an annular antenna arranged around an outer periphery of the container, and is formed of a power supply container, and a process container where the substrate is placed, which communicates with an internal space of the power supply container. The plasma is generated in the power supply container by radio-frequency power supplied to the antenna. The plasma is diffused into the process container by a magnetic field of solenoid coils arranged around an outer periphery of the antenna. The inclination of the magnetic field is adjusted by an inclination adjustment means for adjusting the inclination of the solenoid coils with respect to the process substrate.

Abstract: An ion beam etching device includes a grid provided between a treatment chamber and a plasma generation chamber, and for forming an ion beam by drawing ions from the plasma generation chamber; a gas introduction unit for introducing discharge gas into the plasma generation chamber; an exhaust for exhausting the treatment chamber; a substrate holder; a control unit to receive a measurement result of an in-plane film thickness distribution before the substrate is processed; and an electromagnetic coil provided outside of the plasma generation chamber in a ceiling portion opposite to the grid of the plasma generation chamber. The electromagnetic coil includes an outer coil provided on an outer circumference of the ceiling portion and an inner coil provided on an inner circumference of the ceiling portion, and the control unit controls the currents applied to the outer coil and the inner coil in accordance with the measurement result.

Abstract: A film thickness distribution exists in a substrate plane after CMP step. This film thickness distribution results in, for example, variation in gate threshold value voltages of metal gates, and causes variation in element characteristics. It is an object of the present invention to easily improve the film thickness distribution processed by this CMP step. By using the ion beam etching method after the CMP step, the film thickness distribution in the plane of the substrate 111 is corrected. More specifically, when the ion beam etching is performed, the plasma density in the plasma generation chamber 102 is caused to be different between a position facing a central portion in the plane of the substrate 111 and a position facing an outer peripheral portion, so that the etching rate in the central portion in the plane of the substrate 111 and the etching rate in the outer peripheral portion in the substrate plane 111 are caused to be different.

Abstract: This invention provides a production process in which in a process for producing a magnetoresistive effect element, noble metal atoms in a re-deposited film adhered to a side wall after element isolation are efficiently removed to prevent short-circuiting due to the re-deposited film. The noble metal atoms are selectively removed from the re-deposited film by applying an ion beam, formed using a plasma of a Kr gas or a Xe gas, to the re-deposited film formed on the side wall of the magnetoresistive effect element after the element isolation.

Abstract: A film thickness distribution exists in a substrate plane after CMP step. This film thickness distribution results in, for example, variation in gate threshold value voltages of metal gates, and causes variation in element characteristics. It is an object of the present invention to easily improve the film thickness distribution processed by this CMP step. By using the ion beam etching method after the CMP step, the film thickness distribution in the plane of the substrate 111 is corrected. More specifically, when the ion beam etching is performed, the plasma density in the plasma generation chamber 102 is caused to be different between a position facing a central portion in the plane of the substrate 111 and a position facing an outer peripheral portion, so that the etching rate in the central portion in the plane of the substrate 111 and the etching rate in the outer peripheral portion in the substrate plane 111 are caused to be different.

Abstract: This invention provides a production process in which in a process for producing a magnetoresistive effect element, noble metal atoms in a re-deposited film adhered to a side wall after element isolation are efficiently removed to prevent short-circuiting due to the re-deposited film. The noble metal atoms are selectively removed from the re-deposited film by applying an ion beam, formed using a plasma of a Kr gas or a Xe gas, to the re-deposited film formed on the side wall of the magnetoresistive effect element after the element isolation.

Abstract: Provided is a plasma treatment apparatus capable of uniform substrate treatment by correction of unevenness in a plasma density distribution. The apparatus has a configuration such that a substrate is treated with plasma, and an evacuated container is provided with an annular antenna arranged around an outer periphery of the container, and is formed of a power supply container, and a process container where the substrate is placed, which communicates with an internal space of the power supply container. The plasma is generated in the power supply container by radio-frequency power supplied to the antenna. The plasma is diffused into the process container by a magnetic field of solenoid coils arranged around an outer periphery of the antenna. The inclination of the magnetic field is adjusted by an inclination adjustment means for adjusting the inclination of the solenoid coils with respect to the process substrate.

Abstract: A vacuum processing apparatus including at least three transfer chambers that have transfer robot arms for transferring a substrate, one or more processing chambers connected to each of the transfer chambers; one or more substrate mounts disposed in the interior thereof; a single common vacuum chamber in which the transfer robot arms of the at least three transfer chambers are disposed in positions that allow the arms to reach the substrate mount, and which is used for handing off the substrate by the transfer robot arms between at least two transfer chambers and at least one substrate mount; and load-lock chambers connected to at least one transfer chamber.