A chemical mechanical polish apparatus and methods for manufacturing and use of the chemical mechanical polishing apparatus are discussed herein. In an embodiment, a polishing apparatus is provided that includes: a polishing pad coated with polypeptides; and an enzyme spraying device positioned adjacent to the polishing pad.

According to an aspect of the present disclosure, a substrate polishing apparatus including a turntable for supporting a polishing pad, a dresser that dresses the polishing pad, a dresser drive module that presses the dresser against the polishing pad and rotates the dresser, a support member that supports the dresser drive module, and a plurality of force sensors which are provided between the dresser drive module and the support member and each of which outputs information related to each of forces in three axis directions is provided.

According to an aspect of the present disclosure, a substrate polishing apparatus including a turntable for supporting a polishing pad, a dresser that dresses the polishing pad, a dresser drive module that presses the dresser against the polishing pad and rotates the dresser, a support member that supports the dresser drive module, and a plurality of force sensors which are provided between the dresser drive module and the support member and each of which outputs information related to each of forces in three axis directions is provided.

A coupling mechanism which enables a rotating body to follow an undulation of a polishing surface without generating flutter or vibration of the rotating body, and can finely control a load on the rotating body on a polishing surface in a load range which is smaller than the gravity of rotating body is disclosed. The coupling mechanism includes an upper spherical bearing and a lower spherical bearing disposed between a drive shaft and the rotating body. The upper spherical bearing has a first concave contact surface and a second convex contact surface which are in contact with each other, and the lower spherical bearing has a third concave contact surface and a fourth convex contact surface which are in contact with each other. The first concave contact surface and the second convex contact surface are located above the third concave contact surface and the fourth convex contact surface. The first concave contact surface, the second convex contact surface, the third concave contact surface, the fourth convex contact surface are arranged concentrically.

A chemical mechanical planarization (CMP) pad conditioning assembly that includes one or more support structures positioned between one or more abrasive regions of the pad conditioning assembly is disclosed. The support structures and abrasive regions can be separated by one or more channels. A top surface of the one or more support structures is not co-planar with the top surface of the abrasive regions of the pad conditioning assembly, and the height of the top surface of the one or more support structures when measured to the pad facing surface of the pad conditioning assembly backing plate is less than the height of the top surfaces of the abrasive regions when measured to the pad facing surface of the pad conditioning assembly.

A method of using a chemical mechanical polishing (CMP)apparatus that includes a apparatus is provided. The method includes providing a conditioning disc for conditioning the polishing pad, where the conditioning disc includes a plurality of portions of subsystem discs. The portions may be regions of the disc that are concentric. Each portion of the disc is operable to rotate at a different angular velocity. In some embodiments, a different applied loading is provided to each of the portions of the disc in addition to or in lieu of the different angular velocities.

A method of using a chemical mechanical polishing (CMP)apparatus that includes a apparatus is provided. The method includes providing a conditioning disc for conditioning the polishing pad, where the conditioning disc includes a plurality of portions of subsystem discs. The portions may be regions of the disc that are concentric. Each portion of the disc is operable to rotate at a different angular velocity. In some embodiments, a different applied loading is provided to each of the portions of the disc in addition to or in lieu of the different angular velocities.

Superabrasive tools and their methods of manufacture are disclosed. In one aspect, a method of improving retention of superabrasive particles held in a solidified organic material layer of an abrading tool, a portion of each of said superabrasive particles protruding out of the solidified organic material layer is provided. The method may include securing a plurality of superabrasive particles in the solidified organic material layer in an arrangement that minimizes mechanical stress impinging on the protruding portion of any individual superabrasive particle when used to abrade a work piece. As an example, the arrangement of the plurality of superabrasive particles may be configured to uniformly distribute frictional forces across substantially each superabrasive particle.

Superabrasive tools and their methods of manufacture are disclosed. In one aspect, a method of improving retention of superabrasive particles held in a solidified organic material layer of an abrading tool, a portion of each of said superabrasive particles protruding out of the solidified organic material layer is provided. The method may include securing a plurality of superabrasive particles in the solidified organic material layer in an arrangement that minimizes mechanical stress impinging on the protruding portion of any individual superabrasive particle when used to abrade a work piece. As an example, the arrangement of the plurality of superabrasive particles may be configured to uniformly distribute frictional forces across substantially each superabrasive particle.

Systems and methods are disclosed herein for adding surface features to grinding wheels. A laser may be directed substantially perpendicular to a grinding surface of a grinding wheel. The laser may be pulsed and may ablate material from the grinding surface. The laser may move relative to the grinding wheel in order to ablate shaped surface features into the grinding surface.