Abstract: A semiconductor device includes a plurality of channel structures on a semiconductor substrate. A bit line groove having opposing sidewalls is defined between sidewalls of adjacent ones of the plurality of channel structures.

Abstract: A method of manufacturing a semiconductor device includes: forming a trench for forming buried type wires by etching a substrate; forming first and second oxidation layers on a bottom of the trench and a wall of the trench, respectively; removing a part of the first oxidation layer and the entire second oxidation layer; and forming the buried type wires on the wall of the trench by performing a silicide process on the wall of the trench from which the second oxidation layer is removed. As a result, the buried type wires are insulated from each other.

Abstract: A method of forming a buried gate electrode prevents voids from being formed in a silicide layer of the gate electrode. The method begins by forming a trench in a semiconductor substrate, forming a conformal gate oxide layer on the semiconductor in which the trench has been formed, forming a first gate electrode layer on the gate oxide layer, forming a silicon layer on the first gate electrode layer to fill the trench. Then, a portion of the first gate electrode layer is removed to form a recess which exposed a portion of a lateral surface of the silicon layer. A metal layer is then formed on the semiconductor substrate including on the silicon layer. Next, the semiconductor substrate is annealed while the lateral surface of the silicon layer is exposed to form a metal silicide layer on the silicon layer.

Abstract: In one embodiment, the non-volatile memory device includes a well of a first conductivity type formed in a substrate, and a first plurality of memory cell transistors connected in series to a bit line formed in the well. A buffer is formed in the substrate outside the well and is connected to the bit line. At least one de-coupling transistor is configured to de-couple the buffer from the bit line; and the de-coupling transistor is formed in the well.

Abstract: A method of forming a buried interconnection includes removing a semiconductor substrate to form a groove in the semiconductor substrate. A metal layer is formed on inner walls of the groove using an electroless deposition technique. A silicidation process is applied to the substrate having the metal layer, thereby forming a metal silicide layer on the inner walls of the groove.

Abstract: Provided is a micro stage comprising: a body having a vertically perforated through-hole passing through a central portion thereof; a bobbin including a tip portion with an electron emission tip embedded in the center thereof, and passing through the through-hole of the body to be moved in the through-hole along a first axis perpendicular to a vertical direction; a first piezoelectric element disposed on the body and lengthened when a voltage is applied thereto to push the bobbin in one direction along the first axis; a second piezoelectric element disposed on the body and lengthened when a voltage is applied thereto to push the bobbin in the other direction along the first axis; and an upper cover that is coupled to an upper portion of the body and has a through-hole, through which the bobbin passes and communicates with the through-hole of the body, wherein the bobbin can be positioned as desired along the first axis by adjusting the voltages applied to the first piezoelectric element and the second piezoel

Abstract: In one embodiment, the non-volatile memory device includes a well of a first conductivity type formed in a substrate, and a first plurality of memory cell transistors connected in series to a bit line formed in the well. A buffer is formed in the substrate outside the well and is connected to the bit line. At least one de-coupling transistor is configured to de-couple the buffer from the bit line, and the de-coupling transistor is formed in the well.

Abstract: A flash memory device and a method of testing the flash memory device are provided. The flash memory device may include a memory cell array including a plurality of bit lines, a control unit configured to output estimated data and an input/output buffer unit including a plurality of page buffers. Each of the plurality of page buffers corresponds to one of the plurality of bit lines in the memory cell array and is configured to read test data programmed in at least a first page of a memory cell array, compare the read-out test data with the estimated data to determine whether the corresponding bit line is in a pass or failure state and output a test result signal. A voltage of the test result signal is maintained when test data of a second page of the memory cell array is read if the corresponding bit line in the first page is in a failure state.

Abstract: Provided are a transistor and a method of manufacturing the transistor, and more particularly, a vacuum channel transistor emitting thermal cathode electrons and a method of manufacturing the vacuum channel transistor. The vacuum channel transistor includes: a motherboard; a micro heater member having a thin-film structure formed on the motherboard; a cathode member having a thin-film structure spaced apart from a center part of the micro heater member by a first interval and formed on the micro heater member; a gate member formed on both outer walls of upper parts of the cathode member; and an anode member spaced apart from the cathode member by a second interval through spacers disposed on the gate member, wherein a vacuum electron passing area is interposed between the cathode member and the anode member by the second interval.

Abstract: Provided is a wafer-scale microcolumn array using a low temperature co-fired ceramic (LTCC) substrate. The microcolumn array includes a LTCC substrate having wirings and wafer-scale beam deflector arrays, which are attached to at least one side of the LTCC substrate and has an array of deflection devices deflecting electron beams. The wafer-scale microcolumn array using the LTCC substrate makes it possible to significantly increase the throughput of semiconductor wafers, simplify its manufacturing process, and lower its production cost.

Abstract: A metal organic precursor represented by a formula of R1-CpML is provided onto a substrate having a conductive pattern including silicon. Here, R1 is an alkyl group substituent of Cp, R1 including methyl, ethyl, propyl, pentamethyl, pentaethyl, diethyl, dimethyl or dipropyl, Cp is cyclopentadienyl, M includes nickel (Ni), cobalt (Co), titanium (Ti), platinum (Pt) zirconium (Zr) or ruthenium (Ru), and L is at least one ligand, the at least one ligand including a carbonyl. A deposition process is performed using the metal organic precursor to form a preliminary metal silicide layer and a metal layer on the substrate. The preliminary metal silicidation layer is formed on the conductive pattern. The preliminary metal silicide layer is transformed into a metal silicide layer.

Abstract: Example embodiments are directed to an over-voltage protection circuit and method thereof. The over-voltage protection circuit may include a voltage converter, a voltage comparator, a delay unit, and/or a switching unit. The voltage converter may be configured to generate first voltage and second voltages from a supply voltage. The voltage comparator may be configured to compare the first voltage with the second voltage and to generate a control signal according to the comparison result. The switching unit may be configured to determine whether to apply the supply voltage to a chip in response to the control signal. The delay unit may be configured to delay transmission of the control signal to the switching unit by a delay time.

Abstract: A plurality of spaced-apart conductor structures is formed on a semiconductor substrate, each of the conductor structures including a conductive layer. Insulating spacers are formed on sidewalls of the conductor structures. An interlayer-insulating film that fills gaps between adjacent ones of the insulating spacers is formed. Portions of the interlayer-insulating layer are removed to expose upper surfaces of the conductive layers. Respective epilayers are grown on the respective exposed upper surfaces of the conductive layers and respective metal silicide layers are formed from the respective epilayers.

Abstract: Disclosed are a vacuum channel transistor including a planar cathode layer formed of a material having a low work function or a planar cathode layer including a heat resistant layer formed of a material having a low work function, and a manufacturing method of the same. In the vacuum channel transistor, electrons can be emitted even when a low voltage is applied to a gate layer, a voltage of an anode layer has a small influence on electron emission of a cathode layer, and instability of emission current is obviated. Accordingly, high efficiency and a long lifespan can be achieved, and thus operational stability is secured.

Abstract: A method of forming a metal wiring layer of a semiconductor device produces metal wiring that is free of defects. The method includes forming an insulating layer pattern defining a recess on a substrate, forming a conformal first barrier metal layer on the insulating layer pattern, and forming a second barrier metal layer on the first barrier metal layer in such a way that the second barrier metal layer will facilitate the growing of metal from the bottom of the recess such that the metal can fill a bottom part of the recess completely and thus, form damascene wiring. An etch stop layer pattern is formed after the damascene wiring is formed so as to fill the portion of the recess which is not occupied by the damascene wiring.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate and a doped conductive layer formed over the semiconductor substrate. A diffusion barrier layer is formed over the doped conductive layer. The diffusion barrier layer may be formed from an amorphous semiconductor material. An ohmic contact layer is formed over the diffusion barrier layer. A metal barrier layer is formed over the ohmic contact layer. A metal layer is formed over the metal barrier layer.

Abstract: A method of forming a metal wiring layer of a semiconductor device produces metal wiring that is free of defects. The method includes forming an insulating layer pattern defining a recess on a substrate, forming a conformal first barrier metal layer on the insulating layer pattern, and forming a second barrier metal layer on the first barrier metal layer in such a way that the second barrier metal layer will facilitate the growing of metal from the bottom of the recess such that the metal can fill a bottom part of the recess completely and thus, form damascene wiring. An etch stop layer pattern is formed after the damascene wiring is formed so as to fill the portion of the recess which is not occupied by the damascene wiring.

Abstract: Provided is a method for producing a cloned dog by enucleating an oocyte of a dog to produce an enucleated oocyte, transferring a somatic cell of the dog into the enucleated oocyte, carrying out electrofusion under optimized conditions to produce a nuclear transfer embryo, and transferring the nuclear transfer embryo into its surrogate mother. The method has the effect of producing a cloned dog with high efficiency, and thus can contribute to the development of studies in veterinary medicine, anthropology and medical science, such as the propagation of superior species, xenotransplantation and diseased animal models. In addition, the present invention has the effect of exactly researching production properties of the cloned dog by producing a female cloned dog for the first time, rather than the conventional male cloned dog.

Abstract: In one embodiment, a semiconductor device comprises a semiconductor substrate and a doped conductive layer formed over the semiconductor substrate. A diffusion barrier layer is formed over the doped conductive layer. The diffusion barrier layer comprises an amorphous semiconductor material. After forming the diffusion barrier layer, a heat treatment process may be additionally performed thereon. An ohmic contact layer is formed over the diffusion barrier layer. A metal barrier layer is formed over the ohmic contact layer. A metal layer is formed over the metal barrier layer.

Abstract: A micro column electron beam apparatus having a reduced number of interconnections is provided. The micro column electron beam apparatus includes: a low temperature co-fired ceramic (LTCC) substrate; a plurality of deflector electrodes attached to a predetermined top portion of the LTCC substrate; a pad electrode placed at a top edge of the LTCC substrate and transmitting an external signal to the deflector electrodes; and a connection unit placed in the LTCC substrate and electrically connecting the deflector electrode and the pad electrode.