The polishing pad is suitable for polishing or planarizing a wafer of at least one of semiconductor, optical and magnetic substrates. The polishing pad includes radial feeder grooves in a polishing layer separating the polishing layer into polishing regions. The radial feeder grooves extend at least from a location adjacent the center to a location adjacent the outer edge of the polishing pad. Each polishing region including a series of biased grooves that connects a pair of adjacent radial feeder grooves. A majority of the biased grooves having either an inward bias toward the center of the polishing pad or an outward bias for directing polishing fluid toward the outer edge of the polishing pad.

In a substrate polishing apparatus where a polishing liquid passes through inside a rotary joint, the rotary joint requires maintenance. There is provided a substrate polishing apparatus that includes: a polishing head for holding a substrate; a rotary table that has a surface to which a first opening portion is provided; a polishing liquid discharge mechanism disposed to the rotary table; and a controller configured to control at least the polishing liquid discharge mechanism. The polishing liquid discharge mechanism includes a first cylinder, a first piston, and a driving mechanism that drives the first piston. The first opening portion is communicated with a liquid holding space defined by the first cylinder and the first piston. The controller controls the driving of the first piston by the driving mechanism to increase and decrease a volume of the liquid holding space.

A chemical-mechanical planarization device and a method for using a chemical-mechanical planarization device in conjunction with a semiconductor substrate is provided. In accordance with some embodiments, the device includes: a pad disposed over a rotatable platen; a carrier head disposed over the pad and configured to retain a semiconductor substrate between the pad and the carrier head; a tank configured to retain a liquid containing composition; at least one tube fluidly coupled with the tank, the at least one tube comprising a photocatalyst therein; a nozzle fluidly coupled with the tank through the at least one tube and configured to supply the liquid containing composition onto the pad; and a light source configured to provide light to irradiate the photocatalyst, and the liquid containing composition passing through the at least one tube.

A chemical-mechanical planarization device and a method for using a chemical-mechanical planarization device in conjunction with a semiconductor substrate is provided. In accordance with some embodiments, the device includes: a pad disposed over a rotatable platen; a carrier head disposed over the pad and configured to retain a semiconductor substrate between the pad and the carrier head; a tank configured to retain a liquid containing composition; at least one tube fluidly coupled with the tank, the at least one tube comprising a photocatalyst therein; a nozzle fluidly coupled with the tank through the at least one tube and configured to supply the liquid containing composition onto the pad; and a light source configured to provide light to irradiate the photocatalyst, and the liquid containing composition passing through the at least one tube.

A polishing apparatus including: a turntable with an attached polishing pad; a polishing head that holds a wafer; a tank that stores a polishing agent; a polishing agent supply mechanism which supplies the stored polishing agent to the polishing pad; a waste liquid receiver which collects the polishing agent flowing from the turntable; and a circulation mechanism which is connected to the waste liquid receiver and supplies the collected polishing agent to the tank, the polishing agent is supplied to the polishing pad from the tank with the polishing agent supply mechanism, the used polishing agent which flows from the turntable is collected by the waste liquid receiver, a surface of the wafer held by the polishing head is rubbed against the pad to polish it while supplying the collected polishing agent to the tank to circulate the polishing agent, and the waste liquid receiver is fixed to the turntable and the waste liquid receiver having a bottom plate and a removable side plate.

A polishing apparatus including: a turntable with an attached polishing pad; a polishing head that holds a wafer; a tank that stores a polishing agent; a polishing agent supply mechanism which supplies the stored polishing agent to the polishing pad; a waste liquid receiver which collects the polishing agent flowing from the turntable; and a circulation mechanism which is connected to the waste liquid receiver and supplies the collected polishing agent to the tank, the polishing agent is supplied to the polishing pad from the tank with the polishing agent supply mechanism, the used polishing agent which flows from the turntable is collected by the waste liquid receiver, a surface of the wafer held by the polishing head is rubbed against the pad to polish it while supplying the collected polishing agent to the tank to circulate the polishing agent, and the waste liquid receiver is fixed to the turntable and the waste liquid receiver having a bottom plate and a removable side plate.

Provided is a method for polishing an article including a Co-containing portion to be polished by a polishing liquid, in which the polishing liquid contains water, abrasive particles, and a metal dissolving agent, a pH of the polishing liquid is 6.0 or more, and a content of hydrogen peroxide in the polishing liquid is 0.0001% by mass or less based on the total mass of the polishing liquid.

Polishing liquid comprising abrasive grains, a phosphonic acid compound having a molecular weight of 210 or more, and at least one selected from the group consisting of amino acids and amino acid derivatives, in which a silanol group density of the abrasive grains is 6.5 groups/nm.sup.2 or less, and a degree of association of the abrasive grains is 1.5 or more.

A polishing liquid composition for a silicon oxide film according to the present invention includes cerium oxide particles, a water-soluble macromolecular compound, and an aqueous medium, and the water-soluble macromolecular compound is a water-soluble macromolecular compound including a betaine structure, excluding carbobetaine homopolymers and sulfobetaine homopolymers. The water-soluble macromolecular compound is preferably a water-soluble macromolecular compound containing a constitutional unit A including a betaine structure, and a constitutional unit B that is a constitutional unit other than the constitutional unit A and contains at least one group of a primary amino group, a secondary amino group, a tertiary amino group, a quaternary ammonium group, and salts thereof.

A polishing liquid used for chemical mechanical polishing includes colloidal silica, in which a zeta potential of the colloidal silica measured in a state where the colloidal silica is present in the polishing liquid is 20 mV or less, an electrical conductivity is 200 S/cm or less, a pH is 2 to 6, and a transmittance is 70% to 99%.