Abstract: Disclosed is a dynamic random access memory (DRAM) comprising a transistor having channel holes formed in the channel region thereof and cell gate structures formed in the channel holes. At least three layered impurity regions are formed in a semiconductor substrate between the channel holes and the at least three layered impurity regions form a source region for the transistor.

Abstract: A method of manufacturing a semiconductor device includes forming conductive structures on a substrate. Each of the conductive structures has a line shape that extends along a first direction parallel to the substrate. Insulating spacers are formed on upper sidewalls of the conductive structures. An insulating interlayer is formed that covers the conductive structures. A portion of the insulating interlayer between the conductive structures is etched to form a contact hole. An upper portion of the contact hole is larger than a lower portion thereof. The upper portion of the contact hole has a first width along the first direction and a second width along a second direction parallel to the substrate and substantially perpendicular to the first direction. The first width is substantially larger than the second width. The contact hole is filled with a conductive material to form a contact plug.

Abstract: A semiconductor memory device according to embodiments of the invention includes storage nodes and resistors. A method of manufacturing the semiconductor memory device according to some embodiments of the invention includes forming an interlayer insulation layer on a semiconductor substrate including a memory cell array area and a core/perimeter area; forming a first etch stop layer thereon; forming a plurality of contact plugs arranged linearly in at least one direction on the memory cell array area; forming a first conductive layer on the resultant structure; forming a second etch stop layer thereon; etching the second etch stop layer and the first conductive layer and forming landing pads and resistors arranged non-linearly in at least one direction; and forming storage nodes on the entire outer lateral surfaces of which are exposed, on the landing pads.

Abstract: A method of manufacturing a semiconductor device includes forming conductive structures on a substrate. Each of the conductive structures has a line shape that extends along a first direction parallel to the substrate. Insulating spacers are formed on upper sidewalls of the conductive structures. An insulating interlayer is formed that covers the conductive structures. A portion of the insulating interlayer between the conductive structures is etched to form a contact hole. An upper portion of the contact hole is larger than a lower portion thereof. The upper portion of the contact hole has a first width along the first direction and a second width along a second direction parallel to the substrate and substantially perpendicular to the first direction. The first width is substantially larger than the second width. The contact hole is filled with a conductive material to form a contact plug.

Abstract: Semiconductor devices including an isolation layer on a semiconductor substrate are provided. The isolation layer defines an active region of the semiconductor substrate. The device further includes an upper gate electrode crossing over the active region and extending to the isolation layer and lower active gate electrode. The lower active gate electrode includes a first active gate electrode extending from the upper gate electrode to the active region and a second active gate electrode below the first active gate electrode and having a greater width than a width of the first active gate electrode. The device further includes a lower field gate electrode that extends from the upper gate electrode to the isolation layer and has a bottom surface that is at a lower level than a bottom surface of the active gate electrode such that the sidewalls of the active region are covered below the lower active gate electrode. Related methods of fabricating semiconductor devices are also provided herein.

Abstract: A semiconductor device with an increased effective channel length and a method of manufacturing the same. The device includes a semiconductor substrate, a gate insulating layer disposed on the semiconductor substrate, a gate electrode structure disposed on a predetermined portion of the gate insulating layer, an insulating layer for preventing short channel disposed on the surface of the resultant structure where the gate electrode structure is disposed, and a source region and a drain region disposed in the semiconductor substrate on either side of the gate electrode structure. Both the source region and the drain region are spaced apart from the gate electrode structure by the thickness of the insulating layer. The channel length of a MOS transistor can be thereby increased.

Abstract: A semiconductor device including storage nodes and a method of manufacturing the same: The method includes forming an insulating layer and an etch stop layer on a semiconductor substrate; forming storage node contact bodies to be electrically connected to the semiconductor substrate by penetrating the insulating layer and the etch stop layer; forming landing pads on the etch stop layer to be electrically connected to the storage node contact bodies, respectively; and forming storage nodes on the landing pads, respectively, the storage nodes of which outward sidewalls are completely exposed and which are arranged at an angle to each other.

Abstract: Disclosed are methods for forming FinFETs using a first hard mask pattern to define active regions and a second hard mask to protect portions of the insulating regions between active regions. The resulting field insulating structure has three distinct regions distinguished by the vertical offset from a reference plane defined by the surface of the active regions. These three regions will include a lower surface found in the recessed openings resulting from the damascene etch, an intermediate surface and an upper surface on the remaining portions of the lateral field insulating regions. The general correspondence between the reference plane and the intermediate surface will tend to suppress or eliminate residual gate electrode materials from this region during formation of the gate electrodes, thereby improving the electrical isolation between adjacent active regions and improving the performance of the resulting semiconductor devices.

Abstract: A self-aligned inner gate recess channel in a semiconductor substrate includes a recess trench formed in an active region of the substrate, a gate dielectric layer formed on a bottom portion of the recess trench, recess inner sidewall spacers formed on sidewalls of the recess trench, a gate formed in the recess trench so that an upper portion of the gate protrudes above an upper surface of the substrate, wherein a thickness of the recess inner sidewall spacers causes a center portion of the gate to have a smaller width than the protruding upper portion and a lower portion of the gate, a gate mask formed on the gate layer, gate sidewall spacers formed on the protruding upper portion of gate and the gate mask, and a source/drain region formed in the active region of the substrate adjacent the gate sidewall spacers.

Abstract: A coupling capacitor and a semiconductor memory device using the same are provided. In an embodiment, each memory cell of the semiconductor memory device includes a coupling capacitor so that a storage capacitor can store at least 2 bits of data. The coupling capacitor has a capacitance having a predetermined ratio with respect to the capacitance of the storage capacitor. For this, the coupling capacitor is formed by substantially the same fabrication process as the storage capacitor. The predetermined ratio is obtained by choosing an appropriate number of individual capacitors, each with the same capacitance of the storage capacitor, to comprise the coupling capacitor. Also, the coupling capacitor is disposed on an interlayer insulating layer that buries a bit line in a cell region and a sense amplifier in a sense amplifier region.

Abstract: Disclosed is a method of forming a self-aligned contact structure using a sacrificial mask layer. The method includes forming a plurality of parallel interconnection patterns on a semiconductor substrate. Each of the interconnection patterns has an interconnection and a mask pattern, which are sequentially stacked. Interlayer insulating layer patterns are formed to fill gap regions between the interconnection patterns. The mask patterns are partially etched to form recessed mask patterns that define grooves between the interlayer insulating layer patterns. Then, sacrificial mask patterns filling the grooves are formed. A predetermined region of the interlayer insulating layer patterns is etched using the sacrificial mask patterns as etching masks to form a self-aligned contact hole that exposes a predetermined region of the semiconductor substrate. A spacer is formed of a sidewall of the self-aligned contact hole, and a plug surrounded by the spacer is formed in the self-aligned contact hole.

Abstract: A semiconductor device including storage nodes and a method of manufacturing the same: The method includes forming an insulating layer and an etch stop layer on a semiconductor substrate; forming storage node contact bodies to be electrically connected to the semiconductor substrate by penetrating the insulating layer and the etch stop layer; forming landing pads on the etch stop layer to be electrically connected to the storage node contact bodies, respectively; and forming storage nodes on the landing pads, respectively, the storage nodes of which outward sidewalls are completely exposed and which are arranged at an angle to each other.

Abstract: A method of fabricating a gate of a fin type transistor includes forming hard masks to define active regions of a substrate. A shallow trench isolation method is performed to form a first device separation layer, and then an etch-back process is performed such that the active regions protrude. Sidewall protection layers are formed on sidewalls of the active region, and a second device separation layer is formed thereon, thereby obtaining a device isolation region. The sidewall protection layers include an insulation material with an etch selectivity with respect to an insulation material composing the device isolation region. The device isolation region is selectively etched to form recesses for a fin type active region. Dry etching and wet etching are performed on the silicon nitride to remove the hard masks and the sidewall protection layers, respectively. Gates are formed to fill the recesses.

Abstract: A method of manufacturing a semiconductor device which can prevent leakage current caused by gate electrodes intersecting element isolation layers in a major axis of an active region, and which further has vertical channels to provide a sufficient overlap margin, and a semiconductor device manufactured using the above method. The device includes gate electrodes formed on element isolation layers that are disposed between active regions and have top surfaces that are higher than the top surfaces of the active regions. Since the gate electrodes are formed on the element isolation layers, leakage current in a semiconductor substrate is prevented. In addition, the gate electrodes are formed using a striped shape mask pattern, thereby obtaining a sufficient overlap margin compared to a contact shape or bar shape pattern.

Abstract: In one embodiment, a semiconductor device includes a plurality of fin-shaped active regions defined by a trench formed in a substrate with a predetermined depth; an isolation layer formed inside the trench and comprising a first insulating material; and a plurality of word lines formed on the isolation layer inside the trench and covering a sidewall of the active region inside the trench. A separation layer is formed between two neighboring word lines to separate the two neighboring word lines of the plurality of word lines inside the trench with a predetermined distance. The separation layer comprises a second insulating material having an etch selectivity with respect to the first insulating material.

Abstract: A recessed gate structure in a semiconductor device includes a gate electrode partially buried in a substrate, a blocking member formed in the buried portion of the gate electrode, and a gate insulation layer formed between the gate electrode and the substrate. The blocking member may effectively prevent a void or a seam in the buried portion of the gate electrode from contacting the gate insulation layer adjacent to a channel region in subsequent manufacturing processes. Thus, the semiconductor device may have a regular threshold voltage and a leakage current passing through the void or the seam may efficiently decrease.

Abstract: A self-aligned inner gate recess channel in a semiconductor substrate includes a recess trench formed in an active region of the substrate, a gate dielectric layer formed on a bottom portion of the recess trench, recess inner sidewall spacers formed on sidewalls of the recess trench, a gate formed in the recess trench so that an upper portion of the gate protrudes above an upper surface of the substrate, wherein a thickness of the recess inner sidewall spacers causes a center portion of the gate to have a smaller width than the protruding upper portion and a lower portion of the gate, a gate mask formed on the gate layer, gate sidewall spacers formed on the protruding upper portion of gate and the gate mask, and a source/drain region formed in the active region of the substrate adjacent the gate sidewall spacers.

Abstract: A semiconductor memory device according to embodiments of the invention includes storage nodes and resistors. A method of manufacturing the semiconductor memory device according to some embodiments of the invention includes forming an interlayer insulation layer on a semiconductor substrate including a memory cell array area and a core/perimeter area; forming a first etch stop layer thereon; forming a plurality of contact plugs arranged linearly in at least one direction on the memory cell array area; forming a first conductive layer on the resultant structure; forming a second etch stop layer thereon; etching the second etch stop layer and the first conductive layer and forming landing pads and resistors arranged non-linearly in at least one direction; and forming storage nodes on the entire outer lateral surfaces of which are exposed, on the landing pads.

Abstract: A self-aligned buried contact (BC) pair includes a substrate having diffusion regions; an oxide layer exposing a pair of diffusion regions formed on the substrate; bit lines formed between adjacent diffusion regions and on the oxide layer, each of the bit lines having bit line sidewall spacers formed on sidewalls thereof; a first interlayer dielectric (ILD) layer formed over the bit lines and the oxide layer; a pair of BC pads formed between adjacent bit lines and within the first ILD layer, each BC pad being aligned with one of the pair of exposed diffusion regions in the substrate; and a pair of capacitors, each of the pair of BC pads having one of the pair of capacitors formed thereon, wherein a pair of the bit line sidewall spacers is adjacent to each of the BC pads and the pair of bit line sidewall spacers has an asymmetrical shape.

Abstract: A semiconductor memory device according to embodiments of the invention includes storage nodes and resistors. A method of manufacturing the semiconductor memory device according to some embodiments of the invention includes forming an interlayer insulation layer on a semiconductor substrate including a memory cell array area and a core/perimeter area; forming a first etch stop layer thereon; forming a plurality of contact plugs arranged linearly in at least one direction on the memory cell array area; forming a first conductive layer on the resultant structure; forming a second etch stop layer thereon; etching the second etch stop layer and the first conductive layer and forming landing pads and resistors arranged non-linearly in at least one direction; and forming storage nodes on the entire outer lateral surfaces of which are exposed, on the landing pads.