Abstract: A method of manufacturing a flash memory device includes forming a first polysilicon layer over a semiconductor substrate to form a floating gate. A tunnel dielectric layer is formed over the first polysilicon layer. A second polysilicon layer and a tungsten silicide layer are formed over the tunnel dielectric film to firm a control gate, the tungsten silicide layer having excess silicon. An upper portion of the tungsten silicide layer is oxidized to move the excess silicon away from an interface between the second polysilicon layer and the tungsten silicide.

Abstract: A non-volatile memory device has a gate dielectric film formed between a floating gate and a control gate. The gate dielectric film is formed by forming an oxide film and a ZrO2/Al2O3/ZrO2 (ZAZ) film. Accordingly, the reliability of non-volatile memory devices can be improved while securing a high coupling ratio.

Abstract: A method of forming an isolation layer of a semiconductor device is disclosed. In the method according to one aspect, a semiconductor substrate having a trench formed therein is provided. A first insulating layer is formed over an entire surface of the semiconductor substrate including a surface of the trench. A passivation layer, preferably silicon, including oxygen is formed on a surface of the first insulating layer. A second insulating layer is formed on the passivation layer formed within the trench.

Abstract: A method of forming metal lines of a semiconductor device, comprising providing a semiconductor substrate in which a plurality of gates and junctions formed between the gates are included in a cell area and a peripheral area; forming an insulating layer over the semiconductor substrate including the gates; forming an etch protection layer over the insulating layer; etching he etch protection layer and the insulating layer, and gap-filling conductive material to form contact plugs contacting the junctions of the cell area; and, forming first metal lines contacting the contact plugs and forming second metal lines contacting the junctions of the peripheral area by etching the etch protection layer and the insulating layer.

Abstract: This invention relates to a method of fabricating a semiconductor device. A P well for a cell junction may be formed by performing an ion implantation process employing a zero tilt condition. Stress caused by collision between a dopant and a Si lattice within a semiconductor substrate may be minimized and, therefore stress remaining within the semiconductor substrate may be minimized. Accordingly, Number Of Program (NOP) fail by disturbance caused by stress remaining within a channel junction may be reduced. Further, a broad doping profile may be formed at the interface of trenches by using BF2 as the dopant when the P well is formed. A fluorine getter layer may be formed on an oxide film of the trench sidewalls and may be used as a boron diffusion barrier. Although a Spin On Dielectric (SOD) insulating layer may be used as an isolation layer, loss of boron (B) may be prevented.

Abstract: The present invention relates to a method of forming an isolation layer of a semiconductor memory device. After a trench is formed by etching a semiconductor substrate, a liner insulating film is formed from a DCS-HTO material having a similar wet etch rate to that of a PSZ film that gap fills an isolation layer, and the trench is gap filled with the PSZ film. Accordingly, in a subsequent etch process for EFH control of the isolation layer, residues do not remain on sidewalls of a conductive film for a floating gate, thereby improving electrical properties of devices.

Abstract: A method of manufacturing a flash memory device includes etching portions of a tunnel oxide layer, a first polysilicon layer, a hard mask layer and a semiconductor substrate all of which are laminated over a semiconductor substrate to form trenches. The trenches are filled with an insulating layer thereby forming isolation layers. A portion of top surfaces of the isolation layers is removed, thereby controlling an effective field height (EFH) of the isolation layers while partially exposing sides of the first polysilicon layer. An oxide layer for spacers is formed on the surface of each isolation layer including the exposed first polysilicon layer by using DCS as a source gas. An etch process is performed so that the oxide layer remains only on the sides of the first polysilicon layer, thereby forming spacers. The isolation layers between the spacers are etched to a thickness. The spacers are removed. A dielectric layer and a second polysilicon layer are formed on the surface of each isolation layer.

Abstract: A method of manufacturing a semiconductor device includes the step of performing an ion implantation process for implanting an impurity ion into a semiconductor substrate, and performing annealing in a state where temperature of respective portions of an annealing chamber are set differently in order to activate the impurity ion.

Abstract: A non-volatile memory device has a gate dielectric film formed between a floating gate and a control gate. The gate dielectric film is formed by forming an oxide film and a ZrO2/Al2O3/ZrO2 (ZAZ) film. Accordingly, the reliability of non-volatile memory devices can be improved while securing a high coupling ratio.

Abstract: A non-volatile memory device has a gate dielectric film formed between a floating gate and a control gate. The gate dielectric film is formed by forming an oxide film and a ZrO2/Al2O3/ZrO2 (ZAZ) film. Accordingly, the reliability of non-volatile memory devices can be improved while securing a high coupling ratio.

Abstract: A non-volatile memory device has a gate dielectric film formed between a floating gate and a control gate. The gate dielectric film is formed by forming an oxide film and a ZrO2/Al2O3/ZrO2 (ZAZ) film. Accordingly, the reliability of non-volatile memory devices can be improved while securing a high coupling ratio.

Abstract: A semiconductor device which can reduce contact resistance, is disclosed. A semiconductor device according to the present invention includes a lower conductor pattern and an upper conductor pattern. The lower conductor pattern is in contact with the upper conductor pattern. The lower conductor pattern includes a first doped polysilicon layer, a first tungsten silicide layer and a cap layer formed sequentially. Here, the cap layer is formed to a doped polysilicon layer containing a small amount of tungsten and has stoichiometrical equivalent ratio x of Si higher than the first tungsten silicide layer. The upper conductor pattern includes a second doped polysilicon layer and a second tungsten layer formed sequentially. The contact of lower conductor pattern and the upper conductor pattern is substantially formed between the cap layer and the second doped polysilicon layer. Preferably, stoichiometrical equivalent ratio x of Si for the first tungsten silicide layer is 2.3 to 2.

Abstract: A method of manufacturing a device separation film in a semiconductor device is disclosed. In a process technology in which a trench is formed in a silicon substrate, silicon is grown at the bottom of the trench by SEG method in order to lower the aspect ratio and the trench is then filled with an insulating material so that voids are not generated. In order for silicon to be normally grown, a thermal oxide film formed at the bottom of the trench must be removed without removing the oxide film from the sides of the trench. The disclosed method reduces the speed of forming a thermal oxide film at the bottom of the trench, by plasma process using CF4 and O2 gas after forming the trench. Thereby facilitating the removal of the thermal oxide film at the bottom of the trench while minimizing loss of the thermal oxide film at the sidewall of the trench.

Abstract: A method of manufacturing a device separation film in a semiconductor device is disclosed. In a process technology in which a trench is formed in a silicon substrate, silicon is grown at the bottom of the trench by SEG method in order to lower the aspect ratio and the trench is then filled with an insulating material so that voids are not generated. In order for silicon to be normally grown, a thermal oxide film formed at the bottom of the trench must be removed without removing the oxide film from the sides of the trench. The disclosed method reduces the speed of forming a thermal oxide film at the bottom of the trench, by plasma process using CF4 and O2 gas after forming the trench. Thereby facilitating the removal of the thermal oxide film at the bottom of the trench while minimizing loss of the thermal oxide film at the sidewall of the trench.