Abstract: An improved bipolar junction transistor and a method for manufacturing the same are provided. The bipolar junction transistor includes: a buried layer and a high concentration N-type collector region in a P-type semiconductor substrate; a low concentration P-type base region in the semiconductor substrate above the buried layer; a first high concentration P-type base region along an edge of the low concentration P-type base region; a second high concentration P-type base region at a center of the low concentration P-type base region; a high concentration N-type emitter region between the first and second high concentration base regions; and insulating layer spacers between the high concentration base regions and the high concentration emitter regions. In the bipolar junction transistor, the emitter-base distance can be reduced using a trench and an insulating layer spacer. This may improve base voltage and high-speed response characteristics.

Abstract: Disclosed are a CMOS image sensor and a manufacturing method thereof.

Abstract: Disclosed are a mask of a semiconductor device and a method for forming a pattern thereof, which is capable of correcting a line width bias between a long line width and a short line width when a mask of a semiconductor transistor is formed. The mask may include a plurality of rectangular light shielding patterns formed on a mask disc on which gate line and contact holes are formed; and a connection pattern composed of a plurality of division patterns for selectively connecting the plurality of rectangular light shielding patterns one another. The plurality of rectangular light shielding patterns overlap with the contact hole mask and are formed on both sides of the connection pattern. The connection pattern is divided into 3 to 7 division patterns.

Abstract: A semiconductor device and a method for fabricating the same may improve the isolation characteristics without deterioration of the junction diode characteristics and an increase in a threshold voltage of a MOS transistor. The device includes a semiconductor substrate; an STI layer in a predetermined portion of the semiconductor substrate, dividing the semiconductor substrate into an active region and a field region; and a field channel stop ion implantation layer in the semiconductor substrate under the STI layer.

Abstract: A method and computer program for simulating a semiconductor integrated circuit is disclosed, in which a voltage coefficient of resistance according to a variation of width or length of a resistor device of the integrated circuit may be accurately applied to a model in a manner of including the length and width in variables for measuring the resistance of the resistor device and by which efficiency of a circuit design is considerably enhanced. The method generally includes the steps of measuring a plurality of resistances of a plurality resistors having different length (L) and width (W) from each other while varying a voltage applied to the resistors respectively, calculating a voltage coefficient resist (VCR) of the resistors using the measured resistances, the VCR expressed as a linear function of voltage, and calculating resistance of a certain resistor device having a specific length and width using the VCR.

Abstract: A CMOS image sensor and method of manufacturing the same are provided. In one embodiment, the CMOS image sensor includes: an interlayer dielectric layer formed on a semiconductor substrate including a plurality of photodiodes and transistors; a plurality of color filter isolation layers formed on the interlayer dielectric layer; a color filter layer comprising a first color filter, a second color filter, and a third color filter formed on the interlayer dielectric layer, wherein a portion of the first color filter and a portion of the second color filter are formed on one of the plurality of color filter isolation layers, and wherein a portion of the second color filter and a portion of the third color filter are formed on another of the plurality of color filter isolation layers; and microlenses formed on the color filter layer.

Abstract: A CMOS image sensor and a method for fabricating the same are disclosed, in which transfer characteristics are improved. The method includes forming a photodiode region and a second conductive type ion region on a surface of a first conductive type substrate by implanting a second conductive type impurity ion into an entire surface of the substrate where a transistor is to be formed, forming a second conductive type lightly doped ion region in the substrate corresponding to the photodiode region by lightly implanting a second conductive type impurity ion only in an area where the photodiode region is opened, and diffusing the second conductive type lightly doped ion region into the second conductive type ion region by a thermal process.

Abstract: A first electrode layer having protrusions and depressions on its surface are formed on a lower insulating layer on a semiconductor substrate, and a sacrificial layer is formed on the first electrode layer with a material that is reflowable when heated. After reflowing the sacrificial layer by heat treatment, the reflowed sacrificial layer and first electrode layer are etched so that the protrusions of the first electrode layer are curved, and a dielectric layer and a second electrode layer are sequentially formed on the first electrode layer. When manufactured using the above method, a thin film capacitor may have higher capacitance without increasing the area of the electrode.

Abstract: A method for manufacturing a semiconductor device is provided. The method includes the steps of forming an interlayer insulating layer on a semiconductor substrate, selectively patterning the interlayer insulating layer to form a contact hole, depositing a first metal on an inner surface of the contact hole, submerging the semiconductor substrate on which the first metal is deposited into an electrochemical plating (ECP) solution bath in which a second metal is dissolved, dissolving the first metal in the ECP solution bath, plating the first and second metals dissolved in the ECP solution bath at the same time to gap-fill an alloy of the first and second metals in the contact hole, and removing the alloy using the interlayer insulating layer as an end point in a CMP process to form an alloy interconnection.

Abstract: Disclosed are a gate structure in a trench region of a semiconductor device and method for manufacturing the same. The semiconductor device includes a pair of drift regions formed in a semiconductor substrate; a trench region formed between the pair of drift regions; an oxide layer spacer on sidewalls of the trench region; a gate formed in the trench region; and a source and a drain formed in the pair of the drift regions, respectively.

Abstract: A CMOS image sensor and a method for fabricating the same are disclosed, in which the fabrication costs are reduced by reducing the number of photolithographic processes and yield is improved by obviating an alignment problem between color filter layers and microlenses. In one embodiment, the CMOS image sensor includes a sub layer provided with a unit pixel (e.g., a photodiode and various transistors), a planarization layer on the sub layer, and microlens-color filter structures formed on the planarization layer at constant intervals.

Abstract: A method for fabricating an STI gap fill oxide layer in a semiconductor device is provided. The method can include: forming a shallow trench for forming an STI on a semiconductor substrate; forming an STI liner oxide layer in the shallow trench for the STI; depositing an APCVD oxide layer at an upper portion of the STI liner oxide layer for an oxide layer gap fill in the shallow trench of the STI; d) performing a densifying annealing process to densify the APCVD oxide layer; and depositing an HDP-CVD oxide layer at an upper portion of the APCVD oxide layer so that the STI shallow trench is completely gap-filled.

Abstract: A method for manufacturing structures of a CMOS image sensor. The method comprises the steps of depositing a gate insulating layer and a conductive layer on a semiconductor substrate; depositing an ion implantation barrier layer on the conductive layer; patterning the deposited gate insulating layer, conductive layer and ion implantation barrier layer to form a patterned, composite gate insulating layer, gate electrode and ion implantation barrier structure; forming a second photosensitive layer pattern to define a photodiode region; and implanting low-concentration dopant ions into the substrate using the second photosensitive layer pattern as an ion implantation mask to form a low-concentration dopant region within the photodiode region.

Abstract: A FinFET and a fabrication method thereof. The FinFET device includes an SOI substrate realized through a substrate, a buried oxide layer formed on the substrate, and a silicon epitaxial layer formed on predetermined areas of the buried oxide layer. A gate oxide layer is formed on the silicon epitaxial layer, and a gate electrode is formed on the gate oxide layer. A field insulator is formed on exposed areas of the buried oxide layer to thereby separate adjacent silicon epitaxial layers. Side surfaces of the silicon epitaxial layer are flattened through heat treatment. The fabrication method for a FinFET device includes forming the gate oxidation layer and the gate electrode on the SOI substrate; forming the mask pattern on the gate electrode; forming the trench by etching using the mask pattern as a mask; performing heat treatment to flatten the side surfaces of the silicon epitaxial layer; and forming the field insulator in the trench.

Abstract: A flash memory device incorporating: a semiconductor substrate having an active region and a field region defined therein; a device isolation layer formed in the field region of the substrate; a floating gate having an edge portion overlapping the device isolation layer, the overlapped portion being etched back a depth about equal to a height of a protruding portion of the device isolation layer, the floating gate having a tunneling oxide layer interposed in the active region of the semiconductor substrate; and a gate insulation layer and a control gate sequentially formed on the floating gate.

Abstract: A method for fabricating a CMOS image sensor includes: forming a gate electrode on a pixel region of the semiconductor substrate and, at the same time, forming a polysilicon pattern on a middle resistor region; forming a first lightly doped n-type diffusion region on the photodiode region; forming a second lightly doped n-type diffusion region on the transistor region; consecutively forming first and second insulating layers on the entire surface of the semiconductor substrate; removing a predetermined portion of the second insulation layer on the transistor region and the middle resistor region; forming a third insulation layer on the entire surface of the semiconductor substrate; forming sidewalls of the first insulating layer and the third insulating layer on the gate electrode and the polysilicon pattern by performing an etch-back process; and heavily doping n-type impurities in the transistor region and the polysilicon pattern.

Abstract: A CMOS image sensor includes a semiconductor substrate with a first conductive type including a photodiode region and a transistor region, a gate electrode formed on the transistor region of the substrate, a first impurity region with a second conductive type formed in a portion of the semiconductor substrate between the photodiode region and the gate electrode, and a second impurity region with the second conductive type formed in the photodiode region of the semiconductor substrate.

Abstract: A sputtering apparatus for forming a low-resistance uniform metal silicide layer without additional heat treatment and a metal silicide layer forming method using the same are provided. The sputtering apparatus includes a sputtering chamber; a gas introduction port formed at an upper location of a lateral wall of the sputtering chamber; a gas exhaust port formed at a bottom wall of the sputtering chamber; a target located in an upper region of the sputtering chamber; a power source to supply the target with high-frequency electric power; a stage located in a bottom region of the sputtering chamber to heat the semiconductor substrate; and a sieve provided between the target and the semiconductor substrate to improve straightness of charged metal particles.

Abstract: A semiconductor device includes an inter-metal dielectric (IMD) formed on a substrate and having at least one via hole, a via hole formed by filling the via hole with a first metal, a reductant layer formed on the via plug and the inter-metal dielectric to a predetermined thickness, and a metal line layer formed by depositing a second metal on the reductant layer.

Abstract: Disclosed is a semiconductor transistor for enhancing performance of PMOS and NMOS transistors, particularly current driving performance, while reducing a narrow width effect. A narrow width MOS transistor includes: a channel of which width is W0 and length is L0; an active area including source and drain areas formed at both sides with the channel as a center; a gate insulating layer formed on the channel; a gate conductor formed on the gate insulating layer and intersecting the active area; a first additional active area of width is larger than that W0 of the channel as an active area added to the source area; and a second additional active area of width is larger than that W0 of the channel as an active area added to the drain area. When the structure of the transistor having the additional active areas is applied to NMOS and PMOS transistors, a driving current is represented as 107.27% and 103.31%, respectively. Accordingly, the driving currents of both PMOS and NMOS transistors are enhanced.