Abstract: A method of manufacturing a semiconductor device including forming a gate oxide layer, a first conductive layer, a capacitor dielectric layer, and a second conductive layer on a semiconductor substrate. The method also includes patterning the first and second conductive layers, the gate oxide layer, and the field oxide layer so as to form a gate pattern and a capacitor pattern; selectively wet-etching the first and second conductive layer so as to project out an outward part of the capacitor dielectric layer; implanting ions into the semiconductor substrate using the gate pattern and the protruding portion of the capacitor dielectric layer as an implantation mask; and removing the protruding portion of the capacitor dielectric layer so that the patterned capacitor dielectric layer has the same width as the gate electrode and the first capacitor electrode.

Abstract: A method of fabricating a CMOS image sensor can minimize a dark current by avoiding a dry etch process of a photodiode surface. The method can also reduce a contact resistance and variation of the contact resistance of a read-out circuit unit within a unit pixel. The method includes steps of forming an insulating layer on a semiconductor substrate divided into a photodiode area and a transistor area, removing the insulating layer on a gate electrode forming area, forming a gate insulating layer, forming a conductive layer, forming a gate electrode by planarizing the conductive layer, selectively removing the insulating layer to expose the semiconductor substrate, forming a lightly doped impurity region in the exposed semiconductor substrate, forming a spacer on a sidewall of the gate electrode, completely removing the insulating layer, and forming a heavily doped impurity region on the transistor area of the semiconductor substrate.

Abstract: A method of forming a metal line in a semiconductor device including forming an inter-metal dielectric (IMD) layer on the semiconductor substrate including the predetermined pattern, planarizing the IMD layer through a first CMP process, and patterning a via hole on the planarized substrate. The method further includes depositing a barrier metal layer in the via hole, filling a refractory metal in an upper part of the barrier metal layer, planarizing the substrate filled with the refractory metal by performing a second CMP process, forming a refractory metal oxide layer by oxidizing a residual refractory metal region created by the second CMP process, and forming a refractory metal plug by removing the refractory metal oxide layer through a third CMP process.

Abstract: A method of manufacturing a semiconductor. A first epitaxial layer is formed on a gate nitride layer, and a protection nitride layer is formed on the first epitaxial and gate nitride layers. A first gate insulation layer is formed on a drain silicide, a gate oxide layer is formed on a portion of the first epitaxial layer exposed by a trench. A second epitaxial layer is formed on the first layer. Polysilicon fills the trench to form a gate electrode. Ion-implanting impurities on the second epitaxial layer forms a source region. A second gate insulation layer is formed on the gate electrode and the gate oxide layer, a source silicide is formed on the second gate insulation layer, and an interlayer insulation layer is formed on the second epitaxial layer, source region and source silicide. Source, gate and drain contact holes expose the source silicide, gate electrode and drain silicide.

Abstract: A method of forming a pad and a fuse in a semiconductor device. A copper layer located in both a fuse region and a pad region is formed in a dielectric layer. A first insulating layer is formed on the dielectric layer to cover the copper layer and selectively etched to expose the copper layer in the fuse region. An aluminum fuse is formed on the first insulating layer in the fuse region and connected to the exposed copper layer. A second insulating layer is formed on both the aluminum fuse and the first insulating layer and selectively etched together with the first insulating layer to expose the underlying copper layer in the pad region. An aluminum pad is formed on the second insulating layer in the pad region and connected to the exposed copper layer in the pad region. At least one third insulating layer is formed on both the aluminum pad and the second insulating layer and selectively etched to expose the aluminum pad only.

Abstract: A CMOS image sensor includes a first conductive type semiconductor substrate having an active region and a device isolation region, a device isolation film formed in the device isolation region of the semiconductor substrate, a second conductive type diffusion region formed in the active region of the semiconductor substrate, and an ion implantation prevention layer formed in the vicinity of the device isolation film, including a boundary portion between the device isolation film and the second conductive type diffusion region.

Abstract: The present invention relates to a method of forming damascene pattern in a semiconductor device, and the method includes forming an insulating layer on a bottom wiring, forming via holes exposing a part of the bottom wiring by removing the insulating layer selectively, filling insides of the via holes to a prescribed thickness, forming an anti-reflection layer on the via holes and the insulating layer, forming a mask pattern for trench etching on the insulating layer on which the anti-reflection layer is formed, and forming a damascene pattern using the mask pattern for trench etching. CD uniformity is improved by minimizing change of the critical dimension of the damascene pattern, thereby increasing reliability of the semiconductor device.

Abstract: A method of fabricating a fin field effect transistor is disclosed. An example method forms a thermal oxide layer as a hard mask for etching a silicon fin on an SOI substrate, transcribes a fin pattern, forms a fin FET body by etching using the fin pattern as an etch mask, and restores a sidewall damaged by the etching remove a sacrificial silicon oxide layer. The example method also deposits a high-K dielectric as a gate dielectric, deposits a metal layer, planarizes the metal layer to a height of a hard oxide, forms a nitride layer on the planarized metal layer, and patterns the nitride layer using a hard mask for forming a pattern to form a nitride layer pattern. Additionally, the example method forms a metal gate using the nitride layer pattern, removes a remaining hard oxide mask, and grows a sidewall oxide layer on the metal gate.

Abstract: A dry etching method includes loading a wafer on a lower electrode having at least two cooling paths. Cooling fluids having different temperatures are supplied to each of the cooling paths of the lower electrode so that the multiple cooling paths are at different temperatures from one another. The wafer is etched during cooling.

Abstract: A method of forming a metal line in a semiconductor device including forming a first insulation layer and a first etch stop layer on a conductive layer, and forming a first photosensitive layer pattern on the first etch stop layer; forming a first opening by etching the first etch stop layer; forming a second insulation layer and a second etch stop layer on the first insulation layer and the first etch stop layer, and forming a second photosensitive layer pattern on the second etch stop layer; forming a second opening by etching the second etch stop layer; simultaneously forming an inter-connection groove and a via hole by etching the first insulation layer and the second insulation layer using the second etch stop layer and the first etch stop layer as a mask; and forming a metal line by filling the inter-connection groove and the via hole with conductive materials.

Abstract: A semiconductor device includes a pair of first source/drain regions disposed on a silicon substrate. A first silicon epitaxial layer pattern defines a gate forming region that exposes the silicon substrate between the pair of first source/drain regions. A first gate insulation layer is disposed on the silicon substrate in the gate forming region. A second gate insulation layer is disposed on a sidewall of the first silicon epitaxial layer pattern. A second silicon epitaxial layer pattern is disposed in the gate forming region and on the first silicon epitaxial layer pattern. A pair of second source/drain regions is disposed on the second silicon epitaxial layer pattern. A third gate insulation layer exposes the second silicon epitaxial layer pattern in the gate forming region and covers the pair of second source/drain regions. A gate is disposed on the second silicon epitaxial layer pattern in the gate forming region.

Abstract: A method of forming a metal line in a semiconductor device using a fluorine doped silica glass (FSG) insulation layer. The method includes forming a lower metal layer on a insulation layer on a semiconductor substrate, forming a metal oxide layer on a sidewall of the lower metal layer, forming a barrier insulation layer covering the lower metal layer and metal oxide layer, forming an FSG insulation layer on the barrier insulation layer, forming a via contact that penetrates the FSG insulation layer so as to connect to the lower metal layer, and forming an upper metal layer electrically connected to the via contact.

Abstract: A method of manufacturing a high voltage semiconductor device including forming a P-type region implanted with P-type impurities and an N-type region implanted with N-type impurities in a silicon substrate. The method further includes forming a silicon nitride layer pattern and a pad oxide layer pattern to expose a surface of the silicon substrate, forming a trench by etching the exposed silicon substrate using the silicon nitride layer pattern as an etch mask, forming a trench oxide layer pattern in the trench by removing the silicon nitride layer pattern and the pad oxide layer pattern, and simultaneously forming a deep P-well and a deep N-well by driving P-type impurities in the P-type region and N-type impurities in the N-type region into the silicon substrate, while forming a gate oxide layer on a silicon substrate including the trench oxide layer pattern.

Abstract: A non-volatile memory including a semiconductor substrate, and a SONOS electrode on the semiconductor substrate, where the SONOS electrode has a channel area defined underneath. The memory also includes a first layer in contact with a side of the SONOS electrode, a second layer in contact with another side of the SONOS electrode, a pass electrode in contact with the first layer, a recall electrode in contact with the second layer, and a pair of doped regions in the semiconductor substrate. The pair of doped regions are formed where the SONOS, pass, and recall electrodes are not formed. The memory further includes a pair of extension channels in the semiconductor substrate under the pass and recall electrodes, where the pair of extension channels extend from the doped regions toward the channel area.

Abstract: In a method for fabricating a semiconductor device including a PIP capacitor and a MOS transistor, an isolator film is formed on a semiconductor substrate and then etched to expose an active region of the substrate. An epitaxial film is then formed by performing a selective epitaxial silicon growth process on the active region. A first polysilicon film, a dielectric film and a second polysilicon film are then sequentially formed. Next, an upper electrode is created by patterning the second polysilicon film. After a lower electrode and a gate electrode are formed by patterning the first polysilicon film, a source and a drain of a source/drain region are formed into the epitaxial film. Subsequently, after an interlayer insulation film is created on a resultant structure, contact holes are formed thereinto and contacts connected to the upper electrode, the lower electrode, the gate electrode and the source/drain region are formed.

Abstract: Non-volatile memory device, and method for fabricating the same are disclosed. By forming floating gate trenches in memory regions and filling the trenches with floating gate material, a step height of a with the floating gate/ONO/control gate structure is reduced to the level of a gate in a logic block, and the upper gate structures do not cause a topology imbalance. By forming a tunnel insulating film in the floating gate trenches, edges of the floating gate are in contact with the tunnel insulating film and included in an effective charge area of the device. By reducing the step height of the nonvolatile memory device and including edges of the floating gate in the effective charge area, the completed device can effectively perform its regular operations, such as erasure, programming, and reading.

Abstract: A MOS transistor including a gate insulation layer and a gate electrode layer on a channel region of a semiconductor substrate. A gate spacer layer is formed on a sidewall of the electrode layer and the insulation layer. The transistor includes a deep extended source/drain region, a first source/drain region that is deeper than the extended source/drain region, and a second source/drain region that is shallower than the extended source/drain region.

Abstract: A method of manufacturing a semiconductor device is disclosed wherein a tungsten single atomic layer is deposited in a contact or via hole of a silicon substrate. A tungsten nitride (WN) layer is formed by plasma processing the tungsten single atomic layer using an atomic layer deposition process, which is repeated to form the tungsten nitride layer having a desired thickness as the barrier metal. A tungsten layer is then deposited on the semiconductor substrate to fill the contact hole. The tungsten nitride layer and the tungsten layer are in-situ deposited in a same reaction chamber for tungsten process. Accordingly, the step coverage of the tungsten nitride layer, is improved, thus reducing the contact defects of the fine contact hole, which has a high aspect ratio.

Abstract: A formation method of metal wiring of a semiconductor device is disclosed. According to one example, an example method may include forming a metal wire on a pre metal dielectric (“PMD”) on a semiconductor substrate; patterning and sintering the metal wire; forming an insulating layer on the metal wire and the PMD; and forming a via hole in the insulating layer. The example method may further include forming a barrier metal layer made of multiple metal layers on inner wall of the via hole and upper surface of the insulating layer using physical vapor deposition and chemical vapor deposition; filling up inside the via hole by forming a metallic material on the metal layer; and forming a metallic material via by chemical mechanical polishing of the metallic material and the barrier metal layer until the insulating layer is exposed.

Abstract: The present invention relates to a flash memory and a method for manufacturing the same, capable of minimizing resistance of the common source line in the flash memory cell manufacturing process. In the memory cell manufacturing method according to the embodiment of the present invention, trench lines are continuously formed on a semiconductor substrate, and gate oxide film lines are formed on the semiconductor substrate except at the trench lines. Sequentially, gate lines vertical with the trench lines are formed on the trench lines and the gate oxide film lines, and the dielectric material of the trench line and the gate dielectric film between adjacent gate lines is removed, and a conductive film of Ti/TiN or Co/Ti/TiN is deposited on the common source region, and then a silicide is formed on the common source region by means of annealing.