Abstract: A polishing apparatus has a polishing pad, a top ring for holding a semiconductor wafer, and a vertical movement mechanism operable to move the top ring in a vertical direction. The polishing apparatus also has a distance measuring sensor operable to detect a position of the top ring when a lower surface of the top ring is brought into contact with the polishing pad, and a controller operable to calculate an optimal position of the top ring to polish the semiconductor wafer based on the position detected by the distance measuring sensor. The vertical movement mechanism includes a ball screw mechanism operable to move the top ring to the optimal position.

Abstract: A polishing apparatus polishes a substrate by bringing the substrate into sliding contact with a polishing surface. The polishing apparatus includes: a substrate holder having a substrate holding surface configured to press the substrate against the polishing surface, a retaining ring coupled to the substrate holding surface and configured to surround the substrate, wherein the retaining ring is brought into contact with the polishing surface during operation of the polishing apparatus, the retaining ring being configured to be tiltable independently of the substrate holding surface; a rotating mechanism configured to rotate the substrate holder about its own axis; and at least one local load exerting mechanism configured to exert a local load on a part of the retaining ring in a direction perpendicular to the polishing surface, the at least one local load exerting mechanism being arranged so as not to move in accordance with the substrate holder.

Abstract: An apparatus for processing a substrate is disclosed. The apparatus includes a polishing section configured to polish a substrate, a transfer mechanism configured to transfer the substrate, and a cleaning section configured to clean and dry the polished substrate. The cleaning section has plural cleaning lines for cleaning plural substrates. The plural cleaning lines have plural cleaning modules and plural transfer robots for transferring the substrates.

Abstract: A polishing apparatus capable of preventing wear of rollers which are to transmit a load to a retainer ring and capable of preventing wear particles from escaping outside is disclosed. The polishing apparatus includes: a retainer ring disposed so as to surround the substrate and configured to press the polishing surface while rotating together with a head body; a rotary ring secured to the retainer ring and configured to rotate together with the retainer ring; a stationary ring disposed on the rotary ring; and a local-load exerting device configured to apply a local load to a part of the retainer ring through the rotary ring and the stationary ring. The rotary ring has rollers which are in contact with the stationary ring.

Abstract: An elastic membrane capable of precisely controlling a polishing profile in a narrow area of a wafer edge portion is disclosed. The elastic membrane includes a contact portion to be brought into contact with a substrate; a first edge circumferential wall extending upwardly from a peripheral edge of the contact portion; and a second edge circumferential wall having a horizontal portion connected to an inner circumferential surface of the first edge circumferential wall. The inner circumferential surface of the first edge circumferential wall includes an upper inner circumferential surface and a lower inner circumferential surface, both of which are perpendicular to the contact portion. The upper inner circumferential surface extends upwardly from the horizontal portion of the second edge circumferential wall, and the lower inner circumferential surface extends downwardly from the horizontal portion.

Abstract: A polishing device is provided to suppress deterioration in reproducibility of a polishing profile due to a variation or change with time of a shape of a retaining ring of a substrate holding member for each of retaining rings. The polishing device includes: a polishing head configured to press a substrate against a polishing pad and have a retainer ring surrounding the substrate pressed against the polishing pad; a measurement sensor configured to measure a surface shape of the retainer ring; and a controller configured to determine a polishing condition of the substrate based on the surface shape of the retainer ring measured by the measurement sensor.

Abstract: A substrate holding apparatus and a polishing apparatus which can reduce vibrations of a top ring in its entirety by damping vibrations transmitted from a retaining ring to a top ring body is disclosed. The substrate holding apparatus includes a top ring body having a substrate holding surface configured to hold and press a substrate against a polishing surface, a retaining ring configured to surround the substrate and to contact the polishing surface, and a drive ring comprising a ring member configured to hold the retaining ring on a lower surface thereof, a central member disposed at a central part of the top ring body and supported by the top ring body, and a connecting portion configured to connect the ring member and the central member. The drive ring includes a first material and a second material having a modulus of longitudinal elasticity smaller than the first material.

Abstract: A polishing apparatus capable of stably controlling a pressure in a pressure chamber of a top ring is disclosed. The polishing apparatus includes: a rotatable polishing table for supporting a polishing pad; a rotatable top ring having a pressure chamber for pressing a substrate against the polishing pad; a pressure regulator configured to regulate a pressure of a gas in the pressure chamber; and a buffer tank provided between the pressure chamber and the pressure regulator. The pressure regulator includes a pressure-regulating valve, a pressure gauge configured to measure the pressure of the gas at a downstream side of the pressure-regulating valve, and a valve controller configured to control an operation of the pressure-regulating valve so as to minimize a difference between a target value of the pressure in the pressure chamber and a pressure value measured by the pressure gauge.

Abstract: A substrate holder capable of preventing an increase in a polishing rate of an edge portion of a substrate, even when polishing a plurality of substrates successively, is disclosed. The substrate holder includes: a top ring body configured to hold the substrate; and a retaining ring disposed so as to surround the substrate held by the top ring body. The retaining ring includes a pad pressing structure in an annular shape which is to be brought into contact with the polishing pad and the pad pressing structure has a width in a range of 3 mm to 7.5 mm.

Abstract: An apparatus for processing a substrate is disclosed. The apparatus includes a polishing section configured to polish a substrate, a transfer mechanism configured to transfer the substrate, and a cleaning section configured to clean and dry the polished substrate. The cleaning section has plural cleaning lines for cleaning plural substrates. The plural cleaning lines have plural cleaning modules and plural transfer robots for transferring the substrates.

Abstract: A polishing apparatus capable of precisely controlling a polishing profile, particularly a polishing profile in an edge portion, of a wafer is disclosed. The polishing apparatus includes: a top ring shaft; a housing fixed to the top ring shaft; a flexible membrane configured to press a wafer against a polishing pad; a top ring body configured to hold the flexible membrane; a retaining ring coupled to the top ring body and disposed so as to surround the flexible membrane; a gimbal mechanism configured to allow the top ring body and the retaining ring to tilt with respect to the housing; and a local load exerting mechanism configured to exert a downward local load on a part of the retaining ring.

Abstract: A polishing apparatus has a polishing pad, a top ring for holding a semiconductor wafer, and a vertical movement mechanism operable to move the top ring in a vertical direction. The polishing apparatus also has a distance measuring sensor operable to detect a position of the top ring when a lower surface of the top ring is brought into contact with the polishing pad, and a controller operable to calculate an optimal position of the top ring to polish the semiconductor wafer based on the position detected by the distance measuring sensor. The vertical movement mechanism includes a ball screw mechanism operable to move the top ring to the optimal position.

Abstract: A polishing apparatus has a polishing pad, a top ring for holding a semiconductor wafer, and a vertical movement mechanism operable to move the top ring in a vertical direction. The polishing apparatus also has a distance measuring sensor operable to detect a position of the top ring when a lower surface of the top ring is brought into contact with the polishing pad, and a controller operable to calculate an optimal position of the top ring to polish the semiconductor wafer based on the position detected by the distance measuring sensor. The vertical movement mechanism includes a ball screw mechanism operable to move the top ring to the optimal position.

Abstract: An elastic member for use in a substrate holding apparatus includes an elastic member and a first reinforcing member. The first reinforcing member has a higher rigidity than the elastic membrane and reinforces substantially an entire area of the contact portion of the elastic membrane. The contact portion of the elastic member has a contact portion for contact with the substrate. The first peripheral wall portion of the elastic membrane is coupled to a peripheral end of the contact portion and extends upwardly. The second peripheral wall portion of the elastic member defines a first chamber on an outer side thereof and a second chamber on an inner side thereof. The first reinforcing member is embedded in substantially the entire area of the contact portion of the elastic membrane.

Abstract: A polishing apparatus has a polishing pad, a top ring for holding a semiconductor wafer, and a vertical movement mechanism operable to move the top ring in a vertical direction. The polishing apparatus also has a distance measuring sensor operable to detect a position of the top ring when a lower surface of the top ring is brought into contact with the polishing pad, and a controller operable to calculate an optimal position of the top ring to polish the semiconductor wafer based on the position detected by the distance measuring sensor. The vertical movement mechanism includes a ball screw mechanism operable to move the top ring to the optimal position.

Abstract: An apparatus for processing a substrate is disclosed. The apparatus includes a polishing section configured to polish a substrate, a transfer mechanism configured to transfer the substrate, and a cleaning section configured to clean and dry the polished substrate. The cleaning section has plural cleaning lines for cleaning plural substrates. The plural cleaning lines have plural cleaning modules and plural transfer robots for transferring the substrates.