A method for forming semiconductor devices includes: grinding a backside of a semiconductor wafer with a grinding wheel during a first time interval, wherein the grinding wheel is forward moved during the first time interval, wherein a plurality of semiconductor devices are formed on the semiconductor wafer; and polishing the backside of the semiconductor wafer with the grinding wheel in a second time interval, wherein the grinding wheel is backward moved during the second time interval.

A wafer processing method includes the following steps: forming, on a back side of a wafer including a device layer, a mask to be used in forming grooves in a substrate along streets from the back side of the wafer; applying plasma etching from the back side of the wafer through the mask to form the grooves in the substrate along the streets; ejecting high-pressure fluid against the back side of the wafer with the wafer mounted at its front side on a mounting surface to press the wafer at regions surrounded by the etched grooves; and bonding a tape to the front side of the wafer before performance of at least the pressing step.

A bonding device includes a flexible platen disposed between an upper platen assembly (9) and a transmission device and within a vacuum chamber (6). The flexible platen can expand to apply a downward pressure to the upper platen assembly (9) connected thereto. Under the effect of the pressure, the upper platen assembly (9) slowly moves downward until the upper platen assembly (9) itself and a lower platen assembly (7) respectively come into tight contact with objects to be bonded. After that, the flexible platen continues exerting the downward pressure on the upper platen assembly (9). In this way, the pressure applied by the upper platen assembly (9) to the objects to be bonded is uniform. Meanwhile, because of slow expansion of the flexible platen, the uniform pressure is applied slowly by the upper platen assembly (9).

Provided are a chemical mechanical polishing apparatus and a control method thereof. The chemical mechanical polishing apparatus includes a plurality of polishing platens provided with a polishing pad on an upper surface thereof, and a polishing platen transferring unit for transferring the plurality of polishing platens to different process positions according to a predetermined process sequence. Here, different processes are performed at different process positions.

A bonding apparatus includes a stage supporting a substrate, a first bonding head at a first side of the stage, the first bonding head to pick up a first chip and to bond the picked-up first chip onto the substrate, a second bonding head at a second side of the stage, the second bonding head to pick up a second chip and to bond the picked-up second chip onto the substrate, and a first image acquisition unit over a movement path of the stage to acquire an image of the stage.

A post CMP cleaning apparatus is provided. The post CMP cleaning apparatus includes a cleaning stage. The post CMP cleaning apparatus also includes a rotating platen disposed in the cleaning stage, and the rotating platen is configured to hold and rotate a semiconductor wafer. The post CMP cleaning apparatus further includes a vibrating device disposed over the rotating platen. The post CMP cleaning apparatus further includes a solution delivery module disposed near the vibrating device and configured to deliver a cleaning fluid to the semiconductor wafer. The vibrating device is configured to provide the cleaning fluid with a specific frequency which is at least greater than 100 MHz while the rotating platen is rotating the semiconductor wafer, so that particles on the semiconductor wafer are removed by the cleaning fluid.

A bonding system includes a surface modifying apparatus configured to modify a bonding surface of a first substrate and a bonding surface of a second substrate; a surface hydrophilizing apparatus configured to hydrophilize the modified bonding surface of the first substrate and the modified bonding surface of the second substrate; a bonding apparatus configured to perform bonding of the hydrophilized bonding surface of the first substrate and the hydrophilized bonding surface of the second substrate in a state that the bonding surfaces face each other; and a cleaning apparatus configured to clean, before the bonding is performed, a non-bonding surface of, between the first substrate and the second substrate, at least one which is maintained flat when the bonding is performed, the not-bonding surface being opposite to the bonding surface.

A method of an embodiment separates a bonded substrate including first and second substrates. The bonded substrate includes a carbon film on a first surface of the first substrate, a memory cell on the carbon film, a first connection terminal on the memory cell, a transistor on a first surface of the second substrate, and a second connection terminal on the transistor. In opposing direction of the first surfaces of the first and second substrates, a side of the first substrate on which the memory cell is located and a side of the second substrate on which the transistor is located are joined together, and the first and second connection terminals are mutually connected. The method includes removing the carbon film, and separating the bonded substrate into the first substrate with the first surface exposed and the second substrate on which the memory cell and the transistor are located.

A wafer bonding method includes placing a first wafer on a first bonding framework including a plurality of outlet holes around a periphery of the first bonding framework. A second wafer is placed on a second bonding framework that includes a plurality of inlet holes around a periphery of the second bonding framework. The first bonding framework is in overlapping relation to the second bonding framework such that a gap exist between the first wafer and the second wafer. A gas stream is circulated through the gap between the first wafer and the second wafer entering the gap through one or more of the plurality of inlet holes and exiting the gap through one or more of the plurality of outlet holes. The gas stream replaces any existing ambient moisture from the gap between the first wafer and the second wafer.

Provided is a method of manufacturing a glass sheet (G) having a disc shape including a cutout portion (Gb) in a peripheral edge portion (Ga), the method including etching the cutout portion (Gb).