Abstract: A variable resistance memory device includes first electrodes, dielectric layer patterns vertically projecting from the first electrodes, variable resistance layer patterns surrounding side surfaces of the dielectric layer patterns and connected with the first electrodes, and second electrodes formed over the dielectric layer patterns and connected with the variable resistance layer patterns.

Abstract: A variable resistive memory device includes a bit line, a word line, first electrodes and second electrodes, which are respectively arrayed in different directions, wherein a unit cell including a variable resistive material layer interposed between the first electrode and the second electrode is located at every intersection between the first electrode and the second electrode.

Abstract: A variable resistance memory device includes active regions defined by an isolation layer in a semiconductor substrate, trenches in the semiconductor substrate, which extend in a direction crossing the active regions, junction regions formed in the active regions on both sides of the trenches, and variable resistance patterns interposed between the word lines and the junction regions.

Abstract: A resistive memory device includes a lower electrode formed on a substrate, a resistive layer formed on the lower electrode, and an upper electrode on the resistive layer, wherein a lower portion of the upper electrode is narrower than an upper portion of the upper electrode.

Abstract: A variable resistance memory device includes a semiconductor substrate having an active area defined by an isolation layer extending in one direction, a gate line extending in another direction crossing the isolation layer through the isolation layer and the active area, a protective layer located over the gate line, a contact plug positioned in a partially removed space of the active area between the protective layers, and a variable resistance pattern coupled to a part of the contact plug.

Abstract: A method for fabricating a resistance variable memory device, includes: providing a substrate having first contacts and second contacts, where the second contacts do not overlap the first contacts; forming a line pattern over the substrate, the line pattern overlapping a first line and including a stacked structure of a first electrode, a resistor, and a second electrode; forming a first contact hole to expose the second contact; forming an insulating spacer on a sidewall of the first contact hole; forming a third contact to fill the first contact hole having the insulating spacer formed therein; and forming a third electrode over the third contact such that the third electrode overlaps a second line extending in a second direction and is cut open over the first contact, where the first and second contacts are alternately arranged on the second line.

Abstract: A semiconductor device includes a semiconductor substrate having an active region which includes a gate forming zone and an isolation region; an isolation layer formed in the isolation region of the semiconductor substrate to expose side surfaces of a portion of the active region including the gate forming zone, such that the portion of the active region including the gate forming zone constitutes a fin pattern; a silicon epitaxial layer formed on the active region including the fin pattern; and a gate formed to cover the fin pattern on which the silicon epitaxial layer is formed.

Abstract: A memory device includes a memory unit including a plurality of first conductive lines and a plurality of second conductive lines that cross the first conductive lines, and a driving unit module coupled with the plurality of the first conductive lines through respective ones of a plurality of contacts and coupled with and the plurality of the second conductive lines through respective ones of the plurality of contacts, wherein as the first conductive lines become farther from the driving unit module along a direction that the second conductive lines extend, the respective contacts of the first conductive lines have lower resistance values.

Abstract: A resistive memory device includes a lower electrode formed on a substrate, a resistive layer formed on the lower electrode, and an upper electrode on the resistive layer, wherein a lower portion of the upper electrode is narrower than an upper portion of the upper electrode.

Abstract: A resistive memory device includes a plurality of resistive units, each resistive unit including: a lower electrode formed over a substrate; a resistive layer formed over the lower electrode; and an upper electrode formed over the resistive layer, wherein edge parts of the lower and upper electrodes, which come in contact with the resistive layer, is formed with a rounding shape.

Abstract: A method of fabricating a non-volatile memory device, A tunnel insulating layer, a floating gate, and a pad nitride layer is formed on a semiconductor substrate. A isolation region of the semiconductor substrate is formed by etching to a predetermined depth, and a liner insulating layer is formed on an entire surface of the resulting trench for device isolation. A filling insulation layer is formed on the liner insulating layer to fill the trench and a first etching process is performed on the filling insulation layer and the liner insulating layer. The surface of semiconductor is recessed by performing a second etching process on the filling insulation layer. A capping layer is formed on an entire surface of the result formed by the second etching process. The device isolation layer of a concave shape is formed by performing an etching process on the capping layer.

Abstract: A method for manufacturing a semiconductor device using a salicide process, which includes forming a gate dielectric layer over a silicon substrate including a PMOS region and an NMOS region; forming a first silicon pattern in the NMOS region and a second silicon pattern in the PMOS region; forming a first metal layer that is in contact with the first silicon pattern and the exposed first portion of the silicon substrate; and forming a first gate, a first junction, a second gate, and a second junction by performing a heat treatment to silicify the respective first and second silicon patterns and the silicon substrate.

Abstract: A semiconductor device includes a semiconductor substrate having an active region which includes a gate forming zone and an isolation region; an isolation layer formed in the isolation region of the semiconductor substrate to expose side surfaces of a portion of the active region including the gate forming zone, such that the portion of the active region including the gate forming zone constitutes a fin pattern; a silicon epitaxial layer formed on the active region including the fin pattern; and a gate formed to cover the fin pattern on which the silicon epitaxial layer is formed.

Abstract: A method for manufacturing a fin transistor includes forming a trench by etching a semiconductor substrate. A flowable insulation layer is filled in the trench to form a field insulation layer defining an active region. The portion of the flowable insulation layer coming into contact with a gate forming region is etched so as to protrude the gate forming region in the active region. A protective layer over the semiconductor substrate is formed to fill the portion of the etched flowable insulation layer. The portion of the protective layer formed over the active region is removed to expose the active region of the semiconductor substrate. The exposed active region of the semiconductor substrate is cleaned. The protective layer remaining on the portion of the etched flowable insulation layer is removed. Gates are formed over the protruded gate forming regions in the active region.

Abstract: A semiconductor device includes a semiconductor substrate having an active region including a channel portion. An isolation layer is formed in the semiconductor substrate to define the active region, and a gate is formed over the channel portion in the active region. The active region of the semiconductor substrate is etched to such that the entire active region is below an upper surface of the isolation layer. A U-shaped groove is formed in the channel portion of the active region, except the edges in a direction of the channel width thereof, in order to increase the channel width. In the semiconductor device, there is an increase in channel length and channel width leading to a reduction in leakage current and on increase in operation current.

Abstract: An isolation structure of a semiconductor device is formed by forming a hard mask layer on a semiconductor substrate having active and field regions to expose the field region. A trench is defined by etching the exposed field region of the semiconductor substrate using the hard mask as an etch mask. An SOG layer is formed in the trench partially filling the trench. An amorphous aluminum oxide layer is formed on the resultant substrate including the SOG layer. An HDP layer is formed on the amorphous aluminum oxide layer to completely fill the trench. The HDP layer and the amorphous aluminum oxide layer are subjected to CMP to expose the hard mask. The hard mask and portions of the amorphous aluminum oxide layer that are formed on the HDP layer are removed. The amorphous aluminum oxide layer is crystallized.

Abstract: A fin transistor is formed by forming a hard mask layer on a substrate having an active region and a field region. The hard mask layer is etched to expose the field region. A trench is formed by etching the exposed field region. The trench is filled with an SOG layer. The hard mask layer is removed to expose the active region. An epi-silicon layer is formed on the exposed active region. The SOG layer is then partially etched from the upper end of the trench, thus filling a lower portion of the trench. A HDP oxide layer is deposited on the etched SOG layer filling the trench, thereby forming a field oxide layer composed of the SOG layer and the HDP oxide. The HDP oxide layer in the field oxide layer is etched to expose both side surfaces of the epi-silicon layer. A gate is then formed on the epi-silicon layer of which both side surfaces are exposed and the field oxide layer.

Abstract: A semiconductor device includes a semiconductor substrate having an active region which includes a gate forming zone and an isolation region; an isolation layer formed in the isolation region of the semiconductor substrate to expose side surfaces of a portion of the active region including the gate forming zone, such that the portion of the active region including the gate forming zone constitutes a fin pattern; a silicon epitaxial layer formed on the active region including the fin pattern; and a gate formed to cover the fin pattern on which the silicon epitaxial layer is formed.

Abstract: A method of fabricating a non-volatile memory device includes forming a tunneling layer and a conductive layer on a semiconductor substrate, and patterning the conductive layer, the tunneling layer, and the semiconductor substrate to form a conductive pattern, a tunneling pattern, and a trench in the semiconductor substrate. The method also includes filling the trench with a insulating material, and exposing a partial sidewall of the conductive pattern. The method further includes recessing the exposed partial sidewall of the conductive pattern in an inward direction to form a floating gate. The floating gate includes a base portion and a protruding portion having a width smaller than that of the base portion. The method also includes etching the insulating layer to form an isolation layer that exposes the base portion of the floating gate.

Abstract: A method for manufacturing a semiconductor device using a salicide process, which includes forming a gate dielectric layer over a silicon substrate including a PMOS region and an NMOS region; forming a first silicon pattern in the NMOS region and a second silicon pattern in the PMOS region; forming a first metal layer that is in contact with the first silicon pattern and the exposed first portion of the silicon substrate; and forming a first gate, a first junction, a second gate, and a second junction by performing a heat treatment to silicify the respective first and second silicon patterns and the silicon substrate.