Abstract: A dishwasher including a washing chamber to perform dishwashing, a water collecting portion provided at a lower portion of the washing chamber to gather water used for washing, and a sensing module which is disposed in the water collecting portion and integrally includes a water sensing sensor to sense whether or not water is present and a temperature sensor to sense a temperature of water. Since the sensing module simultaneously serves as the water sensing sensor and the temperature sensor, it may be possible to more efficiently utilize an inner space of the water collecting portion.

Abstract: An active region and a trench region are formed on a semiconductor substrate. The trench region is filled with a dielectric material to form an isolation layer. Oxide and polysilicon layers are formed on the semiconductor substrate. A second polysilicon layer, a second oxide layer, and a first polysilicon layer are patterned to form a plurality of gate lines. Deep ion implantation in a deep portion of the active region is performed using a self-aligned source mask. The active region and the trench region are exposed through the self-aligned source mask by etching the isolation layer between the plurality of gate lines using the self-aligned source mask to form a common source region. Ions are implanted in the common source region using the self-aligned source mask.

Abstract: The present invention provides a non-volatile memory device and fabricating method thereof, by which a cell size can be lowered despite high degree of cell integration and by which the device fabrication is facilitated. The present invention includes at least two trench isolation layers arranged in a device isolation area of a semiconductor substrate, each having a first depth, a first conductive type well arranged between the at least two trench isolation layers to have a second depth smaller than the first depth, a second conductive type source region and a second conductive type drain region arranged in a prescribed upper part of the first conductive type well to be separated from each other by a channel region in-between, an ONO layer on the channel region of the semiconductor substrate, the ONO layer comprising a lower oxide layer, a nitride layer, and an upper oxide layer, and a wordline conductor layer on the ONO layer.

Abstract: A method of manufacturing a NAND flash memory device, including the steps of forming gates over a semiconductor substrate; forming a junction region over the semiconductor substrate between the gates; forming a buffer oxide film on the gates and the semiconductor substrate; stripping the buffer oxide film at one side of the gates; forming a nitride film spacers over the sidewalls of the gates; forming a self-aligned contact process (SAC) nitride film and an insulating film over the entire structure; etching regions of the insulating film and the SAC nitride film to form a contact through which the junction region is exposed; and forming a conductive film to bury the contact, thereby forming a contact plug.

Abstract: An active region and a trench region are formed on a semiconductor substrate. The trench region is filled with a dielectric material to form an isolation layer. Oxide and polysilicon layers are formed on the semiconductor substrate. A second polysilicon layer, a second oxide layer, and a first polysilicon layer are patterned to form a plurality of gate lines. Deep ion implantation in a deep portion of the active region is performed using a self-aligned source mask. The active region and the trench region are exposed through the self-aligned source mask by etching the isolation layer between the plurality of gate lines using the self-aligned source mask to form a common source region. Ions are implanted in the common source region using the self-aligned source mask.

Abstract: The present invention relates to a method of manufacturing a nonvolatile memory cell. The present invention uses tungsten (W) as an upper layer of a control gate electrode in order to integrate the memory cell and performs an ion implantation process for forming a source region and a drain region before a selective oxidization process that is performed to prevent abnormal oxidization of tungsten (W). Therefore, the present invention can reduce a RC delay time of word lines depending on integration of the memory cell and also secure a given distance between a silicon substrate and a tunnel oxide film. As a result, the present invention can solve a data retention problem of the flash memory.

Abstract: The present invention provides a non-volatile memory device and fabricating method thereof, by which a cell size can be lowered despite high degree of cell integration and by which the device fabrication is facilitated. The present invention includes at least two trench isolation layers arranged in a device isolation area of a semiconductor substrate, each having a first depth, a first conductive type well arranged between the at least two trench isolation layers to have a second depth smaller than the first depth, a second conductive type source region and a second conductive type drain region arranged in a prescribed upper part of the first conductive type well to be separated from each other by a channel region in-between, an ONO layer on the channel region of the semiconductor substrate, the ONO layer comprising a lower oxide layer, a nitride layer, and an upper oxide layer, and a wordline conductor layer on the ONO layer.

Abstract: The present invention provides a method of fabricating a flash memory device, in which floating gates in neighbor cells are separated from each other without using photolithography, which enhances electrical characteristics of the device, and which facilitates a cell size reduction. The present invention includes forming a mask defining a trench forming area on a semiconductor substrate, forming a trench in the semiconductor layer by removing a portion of the semiconductor layer using the mask, forming a device isolation layer filling up the trench to maintain an effective isolation layer thickness exceeding a predefined thickness, removing the mask, forming a conductor layer over the substrate including the device isolation layer, planarizing the conductor layer and the device isolation layer to lie in a same plane, and forming an insulating layer over the substrate including the conductor patterns.

Abstract: The present invention provides a method of fabricating a non-volatile memory device, in which trench isolation can be achieved using an insulating layer that needs no separate removal process.

Abstract: The present invention provides a non-volatile memory device and fabricating method thereof, in which a height of a floating gate conductor layer pattern is sustained without lowering a degree of integration and by which a coupling ratio is raised. The present invention includes a trench type device isolation layer defining an active area within a semiconductor substrate, a recess in an upper part of the device isolation layer to have a prescribed depth, a tunnel oxide layer on the active area of the semiconductor substrate, a floating gate conductor layer pattern on the tunnel oxide layer, a conductive floating spacer layer provided to a sidewall of the floating gate conductor layer pattern and a sidewall of the recess, a gate-to-gate insulating layer on the floating fate conductor layer pattern and the conductive floating spacer layer, and a control gate conductor layer on the gate-to-gate insulating layer.

Abstract: The present invention provides a trench isolation method in a flash memory device, by which stability and reliability of the device are enhanced in a manner of forming a pad oxide layer thick in the vicinity of an edge of a trench isolation layer.

Abstract: The present invention provides a device isolation method of a semiconductor memory device and flash memory device fabricating method using the same, which can prevent a bridge occurrence between cells. The present invention includes forming a nitride layer pattern defining a trench forming area on a semiconductor substrate, forming a spacer on a sidewall of the nitride layer pattern, forming a trench in the semiconductor layer by removing a portion of the semiconductor layer using the nitride layer pattern and the spacer as an etch mask, forming a device isolation layer filling up the trench, removing the nitride layer pattern and the spacer to complete the device isolation layer, forming a conductor layer over the substrate including the device isolation layer, planarizing the conductor layer and the device isolation layer to lie in a same plane, and forming an insulating layer over the substrate.

Abstract: A high voltage semiconductor device and fabricating method thereof, enable a high breakdown voltage to be provided from a surface area without forming a dual spacer layer. The semiconductor device includes a semiconductor substrate having source/drain regions separated from each other by a channel region in-between, a gate insulating layer pattern on the channel region, a gate conductor layer pattern on the gate insulating layer, a sidewall insulating layer provided on a sidewall of the gate conductor layer pattern, a salicide suppress layer pattern covering partial, but not entire, surfaces of the source/drain regions, and covering the sidewall insulating layer, and the gate conductor layer pattern, and a metal salicide layer on remaining portions surfaces of the source/drain regions that are not covered with the salicide suppress layer pattern.

Abstract: The present invention provides a method of fabricating a flash memory device, by which a coupling ratio is raised in a manner of shortening an interval between floating gates using a spacer and by which a bridge generation is avoided between control and floating gates.

Abstract: A method of manufacturing a flash memory cell. The method includes controlling a wall sacrificial oxidization process, a wall oxidization process and a cleaning process of a trench insulating film that are performed before/after a process of forming the trench insulating film for burying a trench to etch the trench insulating film to a desired space. Therefore, it is possible to secure the coupling ratio of a floating gate by maximum and implement a device of a smaller size.

Abstract: In order to provide a method for preventing the channel length from being shortened as well as reducing the SAS resistance, the semiconductor device according to the present invention is manufactured by continuously forming linear trench lines on a semiconductor substrate, forming gate oxide lines on the semiconductor substrate between the trench lines, forming gate lines on the trench lines and the gate oxide lines, the gate lines being substantially perpendicular to the trench lines, etching the gate oxide lines and trench lines positioned between the gate lines, forming self aligned sources (SASs) by implanting impurity ions into the etched region, forming spacers on sidewalls of the gate lines, and implanting the impurity ions in the SAS region using the spacers as a mask.

Abstract: A method for fabricating the semiconductor device includes forming linear field oxide regions on a semiconductor substrate; forming gate oxide lines on the semiconductor substrate between the field oxide regions; and forming gate lines on the field oxide regions and the gate oxide lines, the gate lines being substantially perpendicular to the field oxide regions, wherein forming the gate lines also includes forming recesses in the semiconductor substrate between the gate lines, the recesses exposing portions of the semiconductor substrate.

Abstract: Provided is related to a method of forming a semiconductor device comprises steps of: providing a semiconductor substrate having a low voltage region and a high voltage region; forming a pad oxide layer and a pad nitride layer in sequence on the semiconductor substrate; removing the pad nitride layer and the pad oxide layer on the semiconductor substrate of the high voltage region, wherein a surface of the semiconductor substrate of the high voltage region is exposed and recessed; forming a sacrificial oxide layer on the surface of the semiconductor substrate of the high voltage region; removing the sacrificial layer; forming a first gate oxide layer on the surface of the semiconductor substrate of the high voltage region; removing the pad oxide layer and the pad nitride layer left on the semiconductor substrate of the low voltage region, wherein a surface of the semiconductor substrate of the low voltage region is exposed and recessed; and forming a second gate oxide layer on the first gate oxide layer and t

Abstract: Disclosed is a method for manufacturing a flash memory device. In a process of forming a flash memory cell and a select transistor through a process of forming a polysilicon layer for a floating gate, a process of forming a dielectric layer and a process of forming a polysilicon layer for a control gate, the dielectric layer is formed and the dielectric layer in a region where a select transistor will be formed is then removed, thereby forming a select gate line in which the polysilicon layer for the floating gate and the polysilicon layer for the control gate are electrically connected.