Abstract: A chemical mechanical polishing machine includes a polishing head assembly including a polishing head body and a membrane disposed at a bottom of the polishing head body. The bottom surface of the membrane includes a hydrophobic area and a hydrophilic area.

Abstract: A vertical memory device includes a substrate, a channel on the substrate, extending in a vertical direction with respect to a top surface of the substrate, and including a protrusion at a lower portion of the channel, the protrusion extending in a parallel direction with respect to the top surface of the substrate, a semiconductor pattern connecting the protrusion and the substrate, and gate lines stacked and spaced apart from each other in the vertical direction, the gate lines on the protrusion and the semiconductor pattern and surrounding the channel.

Abstract: A vertical memory device includes a substrate, a channel on the substrate, extending in a vertical direction with respect to a top surface of the substrate, and including a protrusion at a lower portion of the channel, the protrusion extending in a parallel direction with respect to the top surface of the substrate, a semiconductor pattern connecting the protrusion and the substrate, and gate lines stacked and spaced apart from each other in the vertical direction, the gate lines on the protrusion and the semiconductor pattern and surrounding the channel.

Abstract: A nonvolatile memory device including a substrate which includes a cell array region and a connection region, an electrode structure formed on the cell array region and the connection region and including a plurality of laminated electrodes, a first recess formed in the electrode structure on the connection region and disposed between the cell array region and a second recess formed in the electrode structure on the connection region, and a plurality of vertical wirings formed on the plurality of electrodes exposed by the first recess.

Abstract: A chemical mechanical polishing machine includes a polishing head assembly including a polishing head body and a membrane disposed at a bottom of the polishing head body. The bottom surface of the membrane includes a hydrophobic area and a hydrophilic area.

Abstract: A chemical mechanical polishing machine includes a polishing head assembly including a polishing head body and a membrane disposed at a bottom of the polishing head body. The bottom surface of the membrane includes a hydrophobic area and a hydrophilic area.

Abstract: A method of manufacturing a vertical-cell-type semiconductor device may include stacking alternately first insulating layers and second insulating layers on a substrate, forming a channel hole through the first and second insulating layers, and forming dielectric layers. A channel layer and a gap fill pattern may be formed within the channel hole. The channel layer may cover a top surface of an uppermost first insulating layer. The top surface of the gap fill pattern is at the same level with the top surface of the channel layer. A first conductivity type impurities may be implanted into the channel layer to form a channel impurity region. A top surface of the gap fill pattern may be recessed. A contact pad on the recessed surface of the gap fill pattern may be formed. A ground selection gate electrode, cell gate electrodes, and string selection gate electrodes may be formed in interlayer spaces that be formed by removing the second insulating layers.

Abstract: According to example embodiments of inventive concepts, a non-volatile memory device includes a substrate including a second impurity region crossing a first impurity region, and channel regions extending in a vertical direction on the substrate. Gate electrodes may be separated from each other in a vertical direction and a horizontal direction along outer walls of the channel regions. A first insulating interlayer may be on the gate electrodes and the channel regions, where the first insulating interlayer defines a contact hole between at least one adjacent pair gate electrodes and a contact plug is formed in the contact hole to be electrically connected to the second impurity region. An etch stop layer pattern may be on the contact plug and the first insulating interlayer.

Abstract: Methods of manufacturing semiconductor devices include forming an integrated structure and a first stopping layer pattern in a first region. A first insulating interlayer and a second stopping layer are formed. A second preliminary insulating interlayer is formed by partially etching the second stopping layer and the first insulating interlayer in the first region. A first polishing is performed to remove a protruding portion. A second polishing is performed to expose the first and second stopping layer patterns.

Abstract: A chemical mechanical polishing machine includes a polishing head assembly including a polishing head body and a membrane disposed at a bottom of the polishing head body. The bottom surface of the membrane includes a hydrophobic area and a hydrophilic area.

Abstract: A first insulating interlayer is formed on a substrate including first and second regions. The first insulating interlayer has top surface, a height of which is greater in the first region than in the second region. A first planarization stop layer and a second insulating interlayer are formed. The second insulating interlayer is planarized until the first planarization stop layer is exposed. The first planarization stop layer and the first and second insulating interlayers in the second region are removed to expose the substrate. A lower mold structure including first insulation layer patterns, first sacrificial layer patterns and a second planarization stop layer pattern is formed. The first insulation layer patterns and the first sacrificial layer patterns are alternately and repeatedly formed on the substrate, and a second planarization stop layer pattern is formed on the first insulation layer pattern.

Abstract: A nonvolatile memory device including a substrate which includes a cell array region and a connection region, an electrode structure formed on the cell array region and the connection region and including a plurality of laminated electrodes, a first recess formed in the electrode structure on the connection region and disposed between the cell array region and a second recess formed in the electrode structure on the connection region, and a plurality of vertical wirings formed on the plurality of electrodes exposed by the first recess.

Abstract: According to example embodiments of inventive concepts, a non-volatile memory device includes a substrate including a second impurity region crossing a first impurity region, and channel regions extending in a vertical direction on the substrate. Gate electrodes may be separated from each other in a vertical direction and a horizontal direction along outer walls of the channel regions. A first insulating interlayer may be on the gate electrodes and the channel regions, where the first insulating interlayer defines a contact hole between at least one adjacent pair gate electrodes and a contact plug is formed in the contact hole to be electrically connected to the second impurity region. An etch stop layer pattern may be on the contact plug and the first insulating interlayer.

Abstract: A first insulating interlayer is formed on a substrate including first and second regions. The first insulating interlayer has top surface, a height of which is greater in the first region than in the second region. A first planarization stop layer and a second insulating interlayer are formed. The second insulating interlayer is planarized until the first planarization stop layer is exposed. The first planarization stop layer and the first and second insulating interlayers in the second region are removed to expose the substrate. A lower mold structure including first insulation layer patterns, first sacrificial layer patterns and a second planarization stop layer pattern is formed. The first insulation layer patterns and the first sacrificial layer patterns are alternately and repeatedly formed on the substrate, and a second planarization stop layer pattern is formed on the first insulation layer pattern.

Abstract: A method of manufacturing a semiconductor device includes forming a plurality of preliminary gate structures, forming a capping layer pattern on sidewalls of the plurality of preliminary gate structures, and forming a blocking layer on top surfaces of the plurality of preliminary gate structures and the capping layer pattern such that a void is formed therebetween. The method also includes removing the blocking layer and an upper portion of the capping layer pattern such that at least the upper sidewalls of the plurality of preliminary gate structures are exposed, and a lower portion of the capping layer pattern remains on lower sidewalls of the preliminary gate structures. The method further includes forming a conductive layer on at least the upper sidewalls of the plurality of preliminary gate structures, reacting the conductive layer with the preliminary gate structures, and forming an insulation layer having an air gap therein.

Abstract: Methods of manufacturing semiconductor devices include forming an integrated structure and a first stopping layer pattern in a first region. A first insulating interlayer and a second stopping layer are formed. A second preliminary insulating interlayer is formed by partially etching the second stopping layer and the first insulating interlayer in the first region. A first polishing is performed to remove a protruding portion. A second polishing is performed to expose the first and second stopping layer patterns.

Abstract: A method of manufacturing a semiconductor device includes forming a plurality of preliminary gate structures, forming a capping layer pattern on sidewalls of the plurality of preliminary gate structures, and forming a blocking layer on top surfaces of the plurality of preliminary gate structures and the capping layer pattern such that a void is formed therebetween. The method also includes removing the blocking layer and an upper portion of the capping layer pattern such that at least the upper sidewalls of the plurality of preliminary gate structures are exposed, and a lower portion of the capping layer pattern remains on lower sidewalls of the preliminary gate structures. The method further includes forming a conductive layer on at least the upper sidewalls of the plurality of preliminary gate structures, reacting the conductive layer with the preliminary gate structures, and forming an insulation layer having an air gap therein.

Abstract: A wafer polishing apparatus includes a polishing tape extending between two guide rollers, a first surface of the polishing tape contacting a surface of a wafer to be polished, a polishing head including a pusher pad, the pusher pad adapted to push the polishing tape against the surface of the wafer to be polished, a color image sensor adjacent to the polishing tape, the color image sensor being adapted to detect a color image of the polishing tape and to output a signal corresponding to the detected color image, and a controller connected to the color image sensor, the controller being adapted to receive the signal output from the color image sensor and to determine when a color of the color image detected by the color image sensor changes, a change in the color image indicating a polishing end point.

Abstract: A method of forming a semiconductor device includes: forming a pattern having trenches on a semiconductor substrate; forming a semiconductor layer on the semiconductor device that fills the trenches; planarizing the semiconductor layer using a first planarization process without exposing the pattern; performing an epitaxy growth process on the first planarized semiconductor layer to form a crystalline semiconductor layer; and planarizing the crystalline semiconductor layer until the pattern is exposed to form a crystalline semiconductor pattern.

Abstract: Spaced apart bonding surfaces are formed on a first substrate. A second substrate is bonded to the bonding surfaces of the first substrate and cleaved to leave respective semiconductor regions from the second substrate on respective ones of the spaced apart bonding surfaces of the first substrate. The bonding surfaces may include surfaces of at least one insulating region on the first substrate, and at least one active device may be formed in and/or on at least one of the semiconductor regions. A device isolation region may be formed adjacent the at least one of the semiconductor regions.