Abstract: A method of forming an isolation structure of a semiconductor device includes implanting dopants of a first type into a semiconductor substrate to form a doped region in the substrate. A mask layer is provided over the substrate and the doped region of the substrate. The mask layer is patterned to expose an isolation region of the substrate, the isolation region defining an active region, the isolation region and the active region being defined at least partly within the doped region. Dopants of a second type are implanted at an edge of the active region as defined by the isolation region. The isolation region of the semiconductor substrate is etched to form an isolation trench having a depth that extends below a depth of the doped region. Dopants of a third type are implanted on sidewalls of the trench in order to minimize the dopants of the second type provided on the sidewalls of the isolation trench from migrating away from the sidewalls.

Abstract: A method of forming a conductive stud is provided. The method includes providing a substrate which has an upper surface and an opening. The opening exposes a portion of a vertical memory device. A conductive layer is formed over the substrate to fill the opening. A chemical mechanical polishing is performed on the conductive layer to form a conductive stud having an upper surface substantially lower than the upper surface of the substrate.

Abstract: Substrate isolation trench (224) are formed in a semiconductor substrate (120). Dopant (e.g. boron) is implanted into the trench sidewalls by ion implantation to suppress the current leakage along the sidewalls. During the ion implantation, the transistor gate dielectric (520) faces the ion stream, but damage to the gate dielectric is annealed in subsequent thermal steps. In some embodiments, the dopant implantation is an angled implant. The implant is performed from the opposite sides of the wafer, and thus from the opposite sides of each active area. Each active area includes a region implanted from one side and a region implanted from the opposite side. The two regions overlap to facilitate threshold voltage adjustment.

Abstract: A method of fabricating a semiconductor device includes steps of forming at least one shallow-trench isolation region in a semiconductor substrate; forming a photoresist pattern for blocking a photodiode region; sequentially implanting dopant ions and boron ions into the at least one shallow-trench isolation region; and activating the implanted ions. Since germanium ions are implanted before implanting P-type ions in a channel-stop ion implantation process, the lattice structure of the surface of a shallow-trench isolation region is maintained, to thereby allow a deeper penetration of the implanted P-type ions (boron ions), and to prevent the P-type ions from being outwardly diffused according to an increased lattice scattering phenomenon generated upon a thermal process.

Abstract: A method of manufacturing a semiconductor device includes providing a semiconductor substrate having first and second main surfaces opposite to each other. The method also includes providing in the semiconductor substrate one or more trenches, first mesas and second mesas. The method also includes oxidizing sidewalls and bottoms of each trench; depositing a doped oxide into each trench and on the tops of the first and second mesas; and thermally oxidizing the semiconductor substrate at a temperature sufficient enough to cause the deposited oxide to flow so that the silicon in each of the first mesas is completely converted to silicon dioxide while the silicon in each of the second mesas is only partially converted to silicon dioxide and so that each of the trenches is filled with oxide.

Abstract: In a semiconductor device having a dual isolation structure, and a method of fabricating the same, an epitaxial layer is formed on the entire surface of the semiconductor device. A device region including the semiconductor device and the epitaxial layer is defined by a device isolation layer. The device isolation layer has a dual structure that includes a diffused isolation layer and a trench isolation layer. The diffused isolation layer is formed in the semiconductor substrate, and surrounds the base and the bottom sidewall of the device region, and the trench isolation layer surrounds the upper sidewall of the device region by vertically penetrating the epitaxial layer.

Abstract: A method (200) of forming an isolation structure is presented, in which a hard mask layer (304, 308) is formed (204, 206) over the isolation and active regions (305, 303) of a semiconductor body (306), and a dopant is selectively provided to a portion of the active region (303) proximate the isolation region (305) to create a threshold voltage compensation region (318). After the compensation region (318) is created, the hard mask layer (304, 308) is patterned (218) to create a patterned hard mask. The patterned hard mask is then used in forming (222) a trench (323) in the isolation region (305) near the compensation region (318), and the trench (323) is then filled (224) with a dielectric material (338).

Abstract: The a trench semiconductor device such as a power MOSFET the high electric field at the corner of the trench is diminished by increasing the thickness of the gate oxide layer at the bottom of the trench. Several processes for manufacturing such devices are described. In one group of processes a directional deposition of silicon oxide is performed after the trench has been etched, yielding a thick oxide layer at the bottom of the trench. Any oxide which deposits on the walls of the trench is removed before a thin gate oxide layer is grown on the walls. The trench is then filled with polysilicon in or more stages. In a variation of the process a small amount of photoresist is deposited on the oxide at the bottom of the trench before the walls of the trench are etched. Alternatively, polysilicon can be deposited in the trench and etched back until only a portion remains at the bottom of the trench. The polysilicon is then oxidized and the trench is refilled with polysilicon.

Abstract: A semiconductor device and a method of manufacturing the same is disclosed. A trench is formed in an active region of a semiconductor substrate. A doped layer is formed on the inner walls of the trench. The trench is filled up with a first semiconductor layer. A gate insulating layer is formed on the first semiconductor layer and the substrate. Two gate electrodes are formed on the gate insulating layer such that the trench is located in between two gate electrodes. First and second impurity regions are formed in the substrate on both sides of each of the gate electrodes. Since the doped layer is locally formed in the trench area, the source and drain regions are completely separated from the heavily doped layer to weaken the electric field of PN junction, thereby improving refresh and preventing punchthrough between the source and drain.

Abstract: In general, the present invention discloses at least one trench isolation region formed in a semiconductor substrate to electrically and/or optically isolate at least one active region from another active region. The at least one trench isolation region comprises a bottom portion and first and second trench sidewalls. At least one trench sidewall is adjacent a doped region. The at least one sidewall adjacent a doped region has a higher impurity dopant concentration than impurity doped regions surrounding the at least one trench isolation region.

Abstract: A semiconductor memory device includes a semiconductor substrate having a trench therein. First and second gate patterns are formed on a surface of the substrate adjacent the trench, a respective one of which is on a respective opposing side of the trench. A split source/drain region is formed in the substrate between the first gate pattern and the second gate pattern such that the split source/drain region is divided by the trench. The split source/drain region includes a first source/drain subregion between the first gate pattern and the trench and a second source/drain subregion between the second gate pattern and the trench and spaced apart from the first source/drain subregion. A connecting region is formed in the substrate that extends around the trench from the first source/drain subregion to the second source/drain subregion. Related methods are also discussed.

Abstract: A semiconductor device and a method of manufacturing the same is disclosed. A trench is formed in an active region of a semiconductor substrate. A doped layer is formed on the inner walls of the trench. The trench is filled up with a first semiconductor layer. A gate insulating layer is formed on the first semiconductor layer and the substrate. Two gate electrodes are formed on the gate insulating layer such that the trench is located in between two gate electrodes. First and second impurity regions are formed in the substrate on both sides of each of the gate electrodes. Since the doped layer is locally formed in the trench area, the source and drain regions are completely separated from the heavily doped layer to weaken the electric field of PN junction, thereby improving refresh and preventing punchthrough between the source and drain.

Abstract: A method for forming a buried diffusion layer with reducing topography in a surface of a semiconductor substrate is provided. A patterned first dielectric layer is formed on a semiconductor substrate for being used as a first hard mask. A thermal oxidation process is performed to form field oxides on the exposed potions of the semiconductor substrate. The patterned first dielectric layer is then removed. A second patterned dielectric layer is formed on the field oxides and the semiconductor substrate for being used as a second hard mask. An isotropic etching process is performed to etch the exposed portions of the field oxides and the semiconductor substrate. The patterned second dielectric layer and the underlying field oxides are removed to form a plurality of trenches on the surface of the semiconductor substrate. A buried diffusion layer is formed along surroundings of the trenches in the semiconductor substrate.

Abstract: The a trench semiconductor device such as a power MOSFET the high electric field at the corner of the trench is diminished by increasing the thickness of the gate oxide layer at the bottom of the trench. Several processes for manufacturing such devices are described. In one group of processes a directional deposition of silicon oxide is performed after the trench has been etched, yielding a thick oxide layer at the bottom of the trench. Any oxide which deposits on the walls of the trench is removed before a thin gate oxide layer is grown on the walls. The trench is then filled with polysilicon in or more stages. In a variation of the process a small amount of photoresist is deposited on the oxide at the bottom of the trench before the walls of the trench are etched. Alternatively, polysilicon can be deposited in the trench and etched back until only a portion remains at the bottom of the trench. The polysilicon is then oxidized and the trench is refilled with polysilicon.

Abstract: A process for forming isolation and active regions, wherein the patterning of an oxidation-barrier active stack is performed separately in the PMOS and NMOS regions. After the active stack is in place, two masking steps are used: one exposes the isolation areas on the NMOS side, for stack etch, channel-stop implant, and silicon recess etch (optional); the other masking step is exactly complementary, and performs the analogous operations on the PMOS side. After these two steps are performed (in either order), an additional nitride layer can optionally be deposited and etched to cover the sidewall of the active stack. Field oxide is then formed, and processing then proceeds in conventional fashion.

Abstract: Provided are a semiconductor device and a method for its manufacture. In one example, the method includes forming an isolation structure having a first refraction index over a sensor embedded in a substrate. A first layer having a second refraction index that is different from the first refraction index is formed over the isolation structure. The first layer is removed from at least a portion of the isolation structure. A second layer having a third refraction index is formed over the isolation structure after the first layer is removed. The third refraction index is substantially similar to the first refraction index.

Abstract: A phototransistor of a CMOS image sensor suitable for decreasing the size of layout, and a method for fabricating the phototransistor are disclosed, in which the phototransistor includes a first conductive type semiconductor substrate; an STI layer on the first conductive type semiconductor substrate, to define an active area and a device isolation area in the first conductive type semiconductor substrate; a second conductive type well in the first conductive type semiconductor substrate; a gate line on the first conductive type semiconductor substrate; an ohmic contact layer in the second conductive type well, wherein the ohmic contact layer is overlapped with the gate line in state of interposing the STI layer therebetween; and a contact to connect the gate line with the ohmic contact layer through the STI layer.

Abstract: A method of manufacturing a semiconductor device includes providing a substrate having first and second main surfaces. The substrate has a heavily doped region of a first conductivity at the second main surface and has a lightly doped region of the first conductivity at the first main surface. The method includes providing trenches and mesas in the substrate, implanting, at an angle, a dopant of the first conductivity into a sidewall of a mesa and implanting, at an angle, a dopant of a second conductivity into the mesa at another sidewall. The method includes oxidizing the sidewalls and bottoms of each trench and tops of the mesas to create a top oxide layer, etching back the top oxide layer to expose a portion of the mesa, depositing an oxide layer to cover the etched back top layer and mesa and planarizing the top surface of the device.

Abstract: The surface area of the walls of a trench formed in a substrate is increased. A barrier layer is formed on the walls of the trench such that the barrier layer is thinner near the corners of the trench and is thicker between the corners of the trench. A dopant is introduced into the substrate through the barrier layer to form higher doped regions in the substrate near the corners of the trench and lesser doped regions between the corners of the trench. The barrier layer is removed, and the walls of the trench are etched in a manner that etches the lesser doped regions of the substrate at a higher rate than the higher doped regions of the substrate to widen and lengthen the trench and to form rounded corners at the intersections of the walls of the trench.

Abstract: A trench capacitor comprises a semiconductor substrate, a trench, formed in the semiconductor substrate, having upper and lower portions, a first doped polysilicon layer filled in the lower portion through a first dielectric film and doped with a first impurity having a first conductivity type, at least a second doped polysilicon layer filled in the upper portion through a second dielectric film and doped with a second impurity different from the first impurity, the second impurity having the first conductivity type, and a buried strap layer provided on the second doped polysilicon layer and composed of the first doped polysilicon layer.