The substrate polishing apparatus capable of measuring a film thickness of a substrate with high accuracy without decreasing a transmittance of light when measuring the film thickness of a substrate being polished is disclosed. The substrate polishing apparatus includes: a stage; a polishing head configured to hold a polishing pad; a polishing-liquid supply nozzle; a film-thickness measuring head; a spectrum analyzer; and a head nozzle to which the film-thickness measuring head is attached. The head nozzle includes a first flow-passage system and a second flow-passage system each configured to form a flow of liquid across an optical path of light and reflected light, the first flow-passage system has an aperture located on the optical path, the second flow-passage system has a liquid outlet port and a liquid suction port located at both sides of the aperture.

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.

Provided is a method of lapping a semiconductor wafer, which can suppress the formation of a ring-shaped pattern in a nanotopography map. The method of lapping a semiconductor wafer includes: a stopping step of stopping lapping of a semiconductor wafer; a reversing step of reversing surfaces of the semiconductor wafer facing a upper plate and a lower plate after the stopping step; and a resuming step of resuming lapping of the semiconductor wafer after the reversing step while maintaining the reversal of the surfaces facing the plates.

The invention is directed to a multi-layer polishing pad for chemical-mechanical polishing comprising a top layer, a middle layer and a bottom layer, wherein the top layer and bottom layer are joined together by the middle layer, and without the use of an adhesive. The invention is also directed to a multi-layer polishing pad comprising an optically transmissive region, wherein the layers of the multi-layer polishing pad are joined together without the use of an adhesive.

The present invention provides a polishing composition for use in polishing a material having a Vickers hardness of 1500 Hv or higher. The polishing composition has an oxidation-reduction potential ORP.sub.x mV and the material to be polishing has an oxidation-reduction potential ORP.sub.y mV, with their relation satisfying ORP.sub.x−ORP.sub.y≧100 mV.

According to one embodiment, a substrate polishing method includes: conveying a substrate to a position above a polishing pad by sucking the substrate by a first region of an elastic film; polishing the substrate while bringing the substrate into contact with the polishing pad; and lifting off the substrate by sucking the substrate by a second region of the elastic film, the second region being larger than the first region.

A polishing method which can remove foreign matters from an entire back surface of a substrate at a high removal rate is provided. The polishing method includes placing a polishing tool in sliding contact with an outer circumferential region of a back surface of a substrate while holding a center-side region of the back surface of the substrate, and placing a polishing tool in sliding contact with the center-side region of the back surface of the substrate while holding a bevel portion of the substrate to polish the back surface in its entirety.

A polishing apparatus includes a platen having a first surface to support a polishing pad and a second surface, a carrier head to hold a substrate against the polishing pad, a plurality of through-holes defined in the platen, and a pad pressure control assembly adjacent on a side of the platen opposite the carrier head.

A semiconductor manufacturing method includes several operations. One operation is catching an image of a predetermined location on a surface of a pad installed in a chemical mechanical polishing (CMP) apparatus by a surface detector. One operation is transferring the image of the predetermined location to a processor. One operation is calculating a surface roughness value of the predetermined location from the image. One operation is comparing the surface roughness value with a threshold value by the processor to determine if the surface roughness condition at the predetermined location is smaller than the threshold value, and the surface is configured for polishing a to-be-polished surface of a wafer.

One object is to provide a polishing machine and a polishing method capable of improving a processing accuracy on the surface of an object. A method of polishing an object is provided. Such a method comprises: a first step of polishing an object by moving the object and a first polishing pad having a smaller dimension than that of the object relative to each other while the first polishing pad is made to contact the object, a second step of polishing the object, after the first step of polishing, by moving the object and a second polishing pad having a larger dimension than that of the object relative to each other while the second polishing pad is made to contact the object, and a step of detecting the state of the surface of the object before the first step of polishing.