A slurry for polishing surfaces or substrates that at least partially comprise ruthenium and copper, wherein the slurry includes an alkali hydroxide, oxygenated halogen compound, and a halogen alkyl benzotriazole. The slurry may further include abrasive, acid(s), and, optionally, an alkoxylated alcohol. With these components, the slurry exhibits a high ruthenium to copper removal rate ratio.

A method for CMP includes following operations. A dielectric structure is received. The dielectric structure includes a metal layer stack formed therein. The metal layer stack includes at least a first metal layer and a second metal layer, and the first metal layer and the second metal layer are exposed through a surface of the dielectric structure. A first composition is provided to remove a portion of the first metal layer from the surface of the dielectric structure. A second composition is provided to form a protecting layer over the second metal layer. The protecting layer is removed from the second metal layer. A CMP operation is performed to remove a portion of the second metal layer. In some embodiments, the protecting layer protects the second metal layer during the removal of the portion of the first metal layer.

To provide modified colloidal silica capable of improving the stability of the polishing speed with time when used as abrasive grains in a polishing composition for polishing a polishing object that contains a material to which charged modified colloidal silica easily adheres, such as a SiN wafer, and to provide a method for producing the modified colloidal silica. Modified colloidal silica, being obtained by modifying raw colloidal silica, wherein the raw colloidal silica has a number distribution ratio of 10% or less of microparticles having a particle size of 40% or less relative to a volume average particle size based on Heywood diameter (equivalent circle diameter) as determined by image analysis using a scanning electron microscope.

A polishing liquid containing abrasive grains, a hydroxy acid, a polyol, and a liquid medium, in which a zeta potential of the abrasive grains is positive, and the hydroxy acid has one carboxyl group and one to three hydroxyl groups.

One aspect of the present invention provides a polishing method including polishing a sliding part of a machine device by producing fullerene-aggregated particles by making the sliding part slide while a polishing-agent composition containing fullerenes and a solvent of the fullerenes is applied to the sliding part.

A composition comprises, consists of, or consists essentially of a polymer including a derivatized amino acid monomer unit. A chemical mechanical polishing composition includes a water based liquid carrier, abrasive particles dispersed in the liquid carrier, and a cationic polymer having a derivatized amino acid monomer unit. A method of chemical mechanical polishing includes utilizing the chemical mechanical polishing composition to remove at least a portion of a metal or dielectric layer from a substrate and thereby polish the substrate.

A method for CMP includes following operations. A metal stack is received. The metal layer stack includes at least a first metal layer and a second metal layer, and a top surface of the first metal layer and a top surface of the second metal layer are exposed. A protecting layer is formed over the second metal layer. A portion of the first metal layer is etched. The protecting layer protects the second metal layer during the etching of the portion of the first metal layer. A top surface of the etched first metal layer is lower than a top surface of the protecting layer. The protecting layer is removed from the second metal layer.

Examples are disclosed that relate to planarizing substrates without use of an abrasive. One example provides a method of chemically planarizing a substrate, the method comprising introducing an abrasive-free planarization solution onto a porous pad, contacting the substrate with the porous pad while moving the porous pad and substrate relative to one another such that higher portions of the substrate contact the porous pad and lower portions of the substrate do not contact the porous pad, and removing material from the higher portions of the substrate via contact with the porous pad to reduce a height of the higher portions of the substrate relative to the lower portions of the substrate. In some examples, linear motion may be used for chemically planarizing.

Provided are improved slurry compositions useful in the CMP polishing of glass and other dielectric materials. In one aspect, the compositions of the invention are comprised of water; silica abrasive; a cationic surfactant; and ceria abrasive. The compositions effect a high removal rate while limiting the number of scratches typically observed when utilizing ceria alone.

A Chemical Mechanical Polishing, CMP, process applied to a wafer of Silicon Carbide having a thickness of, or lower than, 200 μm, comprising the steps of: arranging the wafer on a supporting head of a CMP processing apparatus, the wafer having a front side and a back side opposite to one another, the front side housing at least one electronic component and being coupled to the supporting head; deliver a polishing slurry on the wafer, wherein the polishing slurry has a pH in the range 2-3; pressing the back side of the wafer against a polishing pad of the CMP apparatus exerting, by the supporting head, a pressure on the polishing pad in the range 5-20 kPa; setting a rotation of the polishing pad in the range 30-180 rpm, and setting a rotation of polishing head in the range 30-180 rpm; setting and maintaining a CMP process temperature equal to, or below, 50° C.