Abstract: A semiconductor device includes a first chip having a first chip body and a first bonding layer which is disposed on the first chip body and includes a first bonding pad; and a second chip bonded on the first bonding layer, and having a second chip body and a second bonding layer which is disposed under the second chip body and includes a second bonding pad bonded to the first bonding pad, wherein a side surface of the first bonding layer and a side surface of the second chip are retracted inward of a side surface of the first chip body.

Abstract: A semiconductor chip according to an embodiment of the present disclosure includes a chip region and a chip sealing region disposed in a substrate, a circuit pattern structure disposed in the chip region, a chip guard structure disposed in the chip sealing region and surrounding the chip region, a voltage supply line disposed over the circuit pattern structure in the chip region and supplying a predetermined voltage to the circuit pattern structure, and an upper guard line disposed over the chip guard structure in the chip sealing region and electrically connected to the voltage supply line.

Abstract: A method of manufacturing a semiconductor device including the array of conductive patterns is presented. The semiconductor device may include first conductive patterns disposed over an insulating layer over a semiconductor substrate, a second conductive pattern disposed to extend lengthwise to the side of the first conductive patterns, and third conductive patterns connected to the first conductive patterns and the second conductive pattern. The third conductive patterns may be storage nodes of a capacitor.

Abstract: In a method of manufacturing a semiconductor device a substrate having a cell region and a peripheral region is prepared. A first cell-periphery structure including a conductive layer is formed over a surface of the substrate. In the cell region, a cell bit line trench is formed by patterning the first cell-periphery structure. A second cell-periphery structure including a second conductive layer is formed over the surface of the substrate. The second cell-periphery structure forms a cell bit line structure filling the cell bit line trench in the cell region, and is disposed over the first cell-periphery structure in the peripheral region. A periphery gate structure is formed by patterning the first and second cell-periphery structures in the peripheral region.

Abstract: A semiconductor wafer according to an embodiment includes a monitoring pattern structure disposed over a substrate, a cover pattern layer covering portions of the monitoring pattern structure over the substrate, and contact patterns disposed over the cover pattern layer to extend over the cover pattern layer.

Abstract: In an embodiment, a semiconductor wafer includes an alignment key structure disposed over a substrate, a contact pattern layer disposed on the alignment key structure to extend upward of the alignment key structure, and an insulating layer in contact with the alignment key structure and the contact pattern layer over the substrate.

Abstract: A semiconductor wafer includes at least one chip region disposed in a substrate, a first chip guard disposed over the substrate in a chip sealing region positioned outside the at least one chip region, a second chip guard disposed over the substrate in a scribe lane region positioned outside the chip sealing region, and a test circuit pattern disposed in the scribe lane region and including a ground line electrically connected to a ground well in the substrate. The second chip guard includes a ground wiring layer electrically connected to the ground line of the test circuit pattern.

Abstract: A phase change memory device includes a semiconductor substrate having an impurity region and an interlayer dielectric applying a tensile stress formed on the semiconductor substrate and having contact holes exposing the impurity region. Switching elements are formed in the contact holes; and sidewall spacers interposed between the switching elements and the interlayer dielectric and formed as a dielectric layer applying a compressive stress.

Abstract: A phase change memory device capable of increasing a sensing margin and a method for manufacturing the same. The phase change memory device includes a semiconductor substrate formed with a device isolation structure which defines active regions; first conductivity type impurity regions formed in surfaces of the active regions and having the shape of a line; a second conductivity type well formed in the semiconductor substrate at a position lower than the device isolation structure; a second conductivity type ion-implantation layer formed in the semiconductor substrate at a boundary between a lower end of the device isolation structure and the semiconductor substrate; a plurality of vertical PN diodes formed on the first conductivity type impurity regions; and phase change memory cells formed on the vertical PN diodes.

Abstract: A phase change RAM device includes a semiconductor substrate having a phase change cell area and a voltage application area; a first oxide layer, a nitride layer and a second oxide layer sequentially formed on the semiconductor substrate; a first plug formed in the first oxide layer, the nitride layer and the second oxide layer of the phase change cell area; a second plug formed in the first oxide layer and the nitride layer of the voltage application area; a conductive line formed in the second oxide layer; a third oxide layer formed on the second oxide layer; a lower electrode shaped like a plug, the lower electrode being formed so as to directly make contact with the first plug; and a phase change layer and an upper electrode sequentially formed on the lower electrode in a pattern form.

Abstract: A phase change memory device for preventing thermal cross-talk includes lower electrodes respectively formed in a plurality of phase change cell regions of a semiconductor substrate. A first insulation layer is formed on the semiconductor substrate including to the lower electrodes having holes for exposing the respective lower electrodes. Heaters are formed on the surfaces of the respective holes to contact the lower electrodes. A second insulation layer is formed to fill the holes in which the heaters are formed. A mask pattern is then formed on the first and second insulation layers, including the heaters, to have openings that expose portions of the respective heaters having a constant pitch. A phase change layer is formed on the mask pattern including the exposed portions of the heaters and the first and second insulation layers and subsequently, upper electrodes are formed on the phase change layer.

Abstract: A phase change memory device includes a silicon substrate having a bar-type active region and an N-type impurity region formed in a surface of the active region. A first insulation layer is formed on the silicon substrate, and the first insulation layer includes a plurality of first contact holes and second contact holes. PN diodes are formed in the first contact holes. Heat sinks are formed in the first contact holes on the PN diodes, and contact plugs fill the second contact holes. A second insulation layer having third contact holes is formed on the first insulation layer. Heaters fill the third contact holes. A stack pattern of a phase change layer and a top electrode is formed to contact the heaters. The heat sink quickly cools heat transferred from the heater to the phase change layer.

Abstract: A phase change memory device includes heaters which are formed in their respective memory cells and vertically positioned stack patterns having phase change layers and top electrodes which are formed to come into contact with the heaters. The heaters have horizontal cross-sectional bent shapes which can have any number of shapes such as a shape similar to that of a boomerang. The horizontal cross-sectional bent shapes of the to heaters are for minimizing the contact area between the heaters and the phase change layer so that programming currents can be reduced or minimized.

Abstract: A phase change memory device includes a semiconductor substrate having a plurality of phase change cell regions; a lower electrode formed in each of the phase change cell regions on the semiconductor substrate; an insulation layer formed on the semiconductor substrate to cover the lower electrode and defined with a contact hole which exposes the lower electrode; a heater formed in the contact hole; a conductive pattern formed on the insulation layer to be spaced apart from the heater; a phase change layer formed on the heater, the conductive pattern, and portions of the insulation layer between the heater and the conductive pattern; and an upper electrode formed on the phase change layer. This phase change memory device allows the phase change layer to be stably formed and prevents the phase change layer from lifting.

Abstract: A phase change memory device resistant to stack pattern collapse is presented. The phase change memory device includes a silicon substrate, switching elements, heaters, stack patterns, bit lines and word lines. The silicon substrate has a plurality of active areas. The switching elements are connected to the active areas. The heaters are connected to the switching elements. The stack patterns are connected to the heaters. The bit lines are connected to the stack patterns. The word lines are connected to the active areas of the silicon substrate.

Abstract: A phase change memory device includes a silicon substrate including a plurality of active regions which extend in a first direction and are arranged at regular intervals in a second direction perpendicular to the first direction. Switching elements are formed in each active region of the silicon substrate and are spaced apart from one another. Phase change patterns are formed in the second direction and have the shape of lines in such that the phase change patterns connect side surfaces of pairs of switching elements which are placed adjacent to each other in a direction diagonal to the first direction.

Abstract: A phase change memory device resistant to stack pattern collapse is presented. The phase change memory device includes a silicon substrate, switching elements, heaters, stack patterns, bit lines and word lines. The silicon substrate has a plurality of active areas. The switching elements are connected to the active areas. The heaters are connected to the switching elements. The stack patterns are connected to the heaters. The bit lines are connected to the stack patterns. The word lines are connected to the active areas of the silicon substrate.

Abstract: A method for manufacturing a phase change memory device that prevents or minimizes adverse performance characteristics associated with inadequate overlap between top electrode contacts and top electrodes. The method prevents or minimizes unwanted chemical changes and etch losses of the phase change material when building the top electrode. The method includes forming spacers on sidewalls of remaining portions of the insulation layer and the hard masks so that subsequent etching of the conductive layer and the phase change material layer uses the spacers and the hard masks as an etch mask to form top electrodes and a phase change layer. Accordingly, the method promises to provide a way of achieving a high level of integration for the resultant phase change memory devices.

Abstract: A phase change memory device includes a silicon substrate including a plurality of active regions which extend in a first direction and are arranged at regular intervals in a second direction perpendicular to the first direction. Switching elements are formed in each active region of the silicon substrate and are spaced apart from one another. Phase change patterns are formed in the second direction and have the shape of lines in such that the phase change patterns connect side surfaces of pairs of switching elements which are placed adjacent to each other in a direction diagonal to the first direction.

Abstract: A phase change memory device for preventing thermal cross-talk includes lower electrodes respectively formed in a plurality of phase change cell regions of a semiconductor substrate. A first insulation layer is formed on the semiconductor substrate including to the lower electrodes having holes for exposing the respective lower electrodes. Heaters are formed on the surfaces of the respective holes to contact the lower electrodes. A second insulation layer is formed to fill the holes in which the heaters are formed. A mask pattern is then formed on the first and second insulation layers, including the heaters, to have openings that expose portions of the respective heaters having a constant pitch. A phase change layer is formed on the mask pattern including the exposed portions of the heaters and the first and second insulation layers and subsequently, upper electrodes are formed on the phase change layer.