The present disclosure provides an apparatus and a method for polishing a semiconductor substrate in semiconductor device manufacturing. The apparatus can include: a carrier configured to hold the substrate; a polishing pad configured to polish a first surface of the substrate; a chemical mechanical polishing (CMP) slurry delivery arm configured to dispense a CMP slurry onto the first surface of the substrate; and a pad conditioner configured to condition the polishing pad. In some embodiments, the pad conditioner can include: a conditioning disk configured to scratch the polishing pad; a conditioning arm configured to rotate the conditioning disk; a plurality of magnetic screws configured to secure the conditioning disk onto the conditioning arm and including a respective plurality of screw heads; and a plurality of blocking devices respectively positioned beneath the plurality of screw heads and configured to block debris particles from entering a respective plurality of screw holes.

A polishing apparatus capable of accurately detecting a polishing end point of a periphery of a substrate, such as a wafer, is disclosed. The polishing apparatus includes a polishing head configured to press a polishing tool against the periphery of the substrate on a substrate holding surface. The polishing head includes a pressing member configured to press the polishing tool against the periphery of the substrate, and a shear-force detection sensor configured to detect a shear force acting on the pressing member and output an index value indicating a magnitude of the shear force. An operation controller has a memory storing a program configured to determine a polishing end point at which the index value reaches a threshold value, and a processer configured to execute the program.

A polishing apparatus capable of forming a step-shaped recess having a right-angled cross section in an edge portion of a substrate, such as a wafer, is disclosed. The polishing apparatus includes: a substrate rotating device configured to rotate the substrate about a rotation axis; a first roller having a first circumferential surface configured to press a polishing tape against the edge portion of the substrate; and a second roller having a second circumferential surface in contact with the first circumferential surface. The second roller has a tape stopper surface that restricts movement of the polishing tape in a direction away from the rotation axis. The tape stopper surface is located radially outward of the first circumferential surface.

A display device including a substrate including: a top surface, a bottom surface, and a plurality of side surfaces connecting the top surface and the bottom surface; a signal line disposed on the top surface; a sidewall electrode in electrical contact with the signal line and disposed on a first side surface of the side surfaces; and a connection electrode in electrical contact with the sidewall electrode and disposed on the first side surface.

A substrate processing method capable of preventing an adherence of a foreign matter to a substrate is disclosed. The substrate processing method comprises: a substrate rotating step of rotating a substrate W while holding the substrate W; a first-liquid upper supply step of supplying a first liquid onto an upper surface of the substrate W while rotating the substrate W; a polishing step of pressing a polishing tape 23 to the substrate W while supplying the first liquid in a state of rotating the substrate W; a second-liquid upper supply step of supplying a second liquid onto the upper surface of the substrate W while rotating the substrate W; and a cleaning step of pressing a cleaning tape 29 to the substrate W while supplying the second liquid in a state of rotating the substrate W and terminating after the polishing step is terminated. The second liquid is either of a conducting water, a surfactant solution, or ozone water.

A grinding wheel includes a plurality of wheel tips. The plurality of wheel tips include a plurality of diamond abrasive grains and a bonding material mixed with the diamond abrasive grains. The plurality of diamond abrasive grains have a ratio of a length in a long axis direction to a width in a short axis direction of 1:2.5 to 1:3.5 and includes edges or vertices having a grinding angle of 90? or less.

A method for processing a ceramic honeycomb structure, the method comprising subjecting an outer peripheral surface of the ceramic honeycomb structure to centerless grinding in an in-feed mode by bringing a rotationally driving grinding wheel into contact with the outer peripheral surface of the ceramic honeycomb structure rotationally supported by an adjusting wheel, a blade, and a press roller.

A method for processing a ceramic honeycomb structure, the method comprising subjecting an outer peripheral surface of the ceramic honeycomb structure to centerless grinding in an in-feed mode by bringing a rotationally driving grinding wheel into contact with the outer peripheral surface of the ceramic honeycomb structure rotationally supported by an adjusting wheel, a blade, and a press roller.

Polishing uniformity of a surface to be polished of a substrate is improved by appropriately according with a state of the surface to be polished during polishing. A substrate processing apparatus includes a table 100 for supporting a substrate WF, a pad holder 226 for holding a polishing pad 222 for polishing the substrate WF supported by the table 100, an elevating mechanism for elevating the pad holder 226 with respect to the substrate WF, a swing mechanism for swinging the pad holder 226 in a radial direction of the substrate WF, supporting members 300A and 300B for supporting the polishing pad 222 swung to outside the table 100 by the swing mechanism, and driving mechanisms 310 and 320 for adjusting at least one of a height and a distance to the substrate WF of the supporting member 300 while polishing the substrate WF.

A rectangular substrate is prepared by providing a starting rectangular substrate having front and back surfaces and four side surfaces as ground, and pressing a rotary polishing pad perpendicularly against one side surface under a constant pressure, and relatively moving the rotary polishing pad and the substrate parallel to the side surface, for thereby polishing the side surface of the substrate. In the imprint lithography, the rectangular substrate is capable of controlling compression and pattern shape at a high accuracy and thus transferring a complex pattern of fine feature size to a recipient.