Abstract: A reading method of a non-volatile memory device that includes a plurality memory cells that each include one floating gate and two control gates disposed adjacent to the floating gate on two alternate sides of the floating gate, respectively, and two adjacent memory cells share one control gate, the reading method comprising applying a read voltage to control gates of a selected memory cell, applying a second pass voltage to alternate control gates of the memory cells different from the control gates of the selected memory cells starting from the control gates next to the selected memory cell, and applying a first pass voltage that is lower than the second pass voltage to alternate the control gates of the memory cells different from the control gates of the selected memory cells starting from the control gates secondly next to the selected memory cell.

Abstract: A reading method of a non-volatile memory device that includes a plurality memory cells that each include one floating gate and two control gates disposed adjacent to the floating gate on two alternate sides of the floating gate, respectively, and two adjacent memory cells share one control gate, the reading method comprising applying a read voltage to control gates of a selected memory cell, applying a second pass voltage to alternate control gates of the memory cells different from the control gates of the selected memory cells starting from the control gates next to the selected memory cell, and applying a first pass voltage that is lower than the second pass voltage to alternate the control gates of the memory cells different from the control gates of the selected memory cells starting from the control gates secondly next to the selected memory cell.

Abstract: A method of manufacturing semiconductor devices includes providing a semiconductor substrate including first active areas and isolation areas alternately arranged to be parallel to each other and second active areas connecting the first active areas to each other. A tunnel insulating layer, a charge storage layer, and an isolation mask are formed on the semiconductor substrate. The isolation mask, the charge storage layer, the tunnel insulating layer, and the semiconductor substrate are etched to form a trench on the isolation area. An isolation structure is formed on the trench. A dielectric layer, a conductive layer for a control gate, and a hard mask are sequentially formed on a structure that includes the isolation structure. The hard mask, the conductive layer for the control gate, the dielectric layer, and the charge storage layer are patterned to form drain select lines, word lines and source select lines intersecting the first active area.

Abstract: The present invention relates to a method of manufacturing a flash memory device. According to the method of manufacturing the flash memory device, a gate line is formed to have a structure in which a tunnel oxide film, a polysilicon layer for floating gate, dielectric films and a polysilicon layer for a control gate are stacked, etch damages are compensated for by means of an oxidization process, and a metal layer formed on the polysilicon layer for control gate is formed by means of a damascene process. Accordingly, it is possible to sufficiently compensate for etch damages, prevent generation of abnormal oxidization in a metal layer, and improve the reliability of a process and electrical characteristics of a device accordingly.

Abstract: A method of fabricating a flash memory device is disclosed wherein, electrode spacers are formed on sides of self-aligned floating gates having a negative slope. Thus, upon etching of a stack gate after an interlayer dielectric film and a control gate are formed, a stringer of a control gate, which is formed by the negative slope of the self-aligned floating gates, can be prevented. Furthermore, because an isotropic etch process is used to remove element isolation films between the floating gates, the element isolation films do not remain on the sides of the floating gates. It is thus possible to prevent loss of the coupling ratio. Accordingly, failure of devices can be reduced and decreasing the program speed can be prevented.

Abstract: Disclosed is a method for fabricating a semiconductor device with a dual gate dielectric structure. The method includes the steps of: sequentially forming a first oxide layer, a nitride layer and a second oxide layer on a substrate provided with a cell region for the NVDRAM and a peripheral circuit region for a logic circuit; forming a mask on the cell region; performing a first wet etching process by using the mask as an etch barrier to remove the second oxide layer formed in the peripheral circuit region; performing a second wet etching process by using the second oxide layer remaining in the cell region as an etch barrier to remove the nitride layer formed in the peripheral circuit region; forming a third oxide layer on the first oxide layer remaining in the peripheral circuit region; and forming a gate electrode on the second oxide layer and the third oxide layer.

Abstract: Disclosed is a method of manufacturing a semiconductor device, which prevents a contact resistance due to a native oxide film from being increased. Semiconductor substrate on which a lower structure having a junction region is formed is prepared. Interlayer dielectric film is formed over a whole surface of semiconductor substrate. Contact hole exposing the junction region is formed by etching interlayer dielectric film. Dry-cleaning and wet-cleaning for a substrate surface exposed by the contact hole are sequentially performed. Washed contact surface is preliminarily treated under reducing gas atmosphere to remove a native oxide film formed on contact surface. Impurity is additionally doped to a surface of the junction region in-situ so that impurity damages on preliminary-treated contact surface are compensated for. Conductive film is deposited on the contact hole and the interlayer dielectric film in-situ.

Abstract: Disclosed is a method for fabricating a semiconductor device with a dual gate dielectric structure. The method includes the steps of: sequentially forming a first oxide layer, a nitride layer and a second oxide layer on a substrate provided with a cell region for the NVDRAM and a peripheral circuit region for a logic circuit; forming a mask on the cell region; performing a first wet etching process by using the mask as an etch barrier to remove the second oxide layer formed in the peripheral circuit region; performing a second wet etching process by using the second oxide layer remaining in the cell region as an etch barrier to remove the nitride layer formed in the peripheral circuit region; forming a third oxide layer on the first oxide layer remaining in the peripheral circuit region; and forming a gate electrode on the second oxide layer and the third oxide layer.

Abstract: Disclosed is a method of manufacturing a semiconductor device. The method comprises the steps of: preparing a silicon substrate having a predetermined lower structure including a gate and a bonding area; forming an interlayer dielectric film on the top side of the substrate; forming a photosensitive film pattern, which exposes an area for providing contact, on the interlayer dielectric film; forming a contact hole exposing a bonding area of the substrate by etching the exposed part of the interlayer dielectric film; removing the photosensitive film pattern; performing a dry cleaning on the exposed bonding area of the substrate so that CF based polymer formed in the etching step is removed; and performing a nitrogen-hydrogen plasma processing on the surface of the exposed bonding area of the substrate so that oxygen polymer and remaining CF-based polymer are removed. Therefore, since hydrogen plasma processing is performed after contact etching, ohmic contact characteristics can be secured.

Abstract: Disclosed is a method of manufacturing a semiconductor device. The method comprises the steps of: preparing a silicon substrate having a predetermined lower structure including a gate and a bonding area; forming an interlayer dielectric film on the top side of the substrate; forming a photosensitive film pattern, which exposes an area for providing contact, on the interlayer dielectric film; forming a contact hole exposing a bonding area of the substrate by etching the exposed part of the interlayer dielectric film; removing the photosensitive film pattern; performing a dry cleaning on the exposed bonding area of the substrate so that CF based polymer formed in the etching step is removed; and performing a nitrogen-hydrogen plasma processing on the surface of the exposed bonding area of the substrate so that oxygen polymer and remaining CF-based polymer are removed. Therefore, since hydrogen plasma processing is performed after contact etching, ohmic contact characteristics can be secured.

Abstract: Disclosed is a method of manufacturing a semiconductor device, which prevents a contact resistance due to a native oxide film from being increased. Semiconductor substrate on which a lower structure having a junction region is formed is prepared. Interlayer dielectric film is formed over a whole surface of semiconductor substrate. Contact hole exposing the junction region is formed by etching interlayer dielectric film. Dry-cleaning and wet-cleaning for a substrate surface exposed by the contact hole are sequentially performed. Washed contact surface is preliminarily treated under reducing gas atmosphere to remove a native oxide film formed on contact surface. Impurity is additionally doped to a surface of the junction region in-situ so that impurity damages on preliminary-treated contact surface are compensated for. Conductive film is deposited on the contact hole and the interlayer dielectric film in-situ.

Abstract: Methods for forming thin films of semiconductor devices, and more specifically, methods for forming thin films of semiconductor devices, wherein the semiconductor substrate is subjected to a thin film formation process in a thin film formation apparatus containing a chamber, a susceptor vertically movable in the chamber and a heater disposed within the susceptor, the method comprising a preheating process for stabilizing the internal temperature of the chamber by vertically moving the susceptor a predetermined number of times prior to the thin film formation process.

Abstract: Methods for forming thin films of semiconductor devices, and more specifically, methods for forming thin films of semiconductor devices, wherein the semiconductor substrate is subjected to a thin film formation process in a thin film formation apparatus containing a chamber, a susceptor vertically movable in the chamber and a heater disposed within the susceptor, the method comprising a preheating process for stabilizing the internal temperature of the chamber by vertically moving the susceptor a predetermined number of times prior to the thin film formation process.

Abstract: A method of manufacturing a semiconductor device having the steps of forming an insulating layer on a silicon substrate, forming a contact hole on the insulating layer, forming a selective silicon layer in the contact hole, and forming a selective conductive plug on the selective silicon layer.

Abstract: A method of manufacturing a semiconductor device having the steps of forming an insulating layer on a silicon substrate, forming a contact hole on the insulating layer, forming a selective silicon layer in the contact hole, and forming a selective conductive plug on the selective silicon layer.