Abstract: A bubble-jet type ink-jet printhead, and a manufacturing method thereof are provided, wherein, the printhead includes a substrate integrally having an ink supply manifold, an ink chamber, and an ink channel, a nozzle plate having a nozzle, a heater consisting of resistive heating elements, and an electrode for applying current to the heater. In particular, the ink chamber is formed in a substantially hemispherical shape on a surface of the substrate, a manifold is formed from its bottom side toward the ink chamber, and the ink channel linking the manifold and the ink chamber is formed at the bottom of the ink chamber. Thus, this simplifies the manufacturing process and facilitates high integration and high volume production. Furthermore, a doughnut-shaped bubble is formed to eject ink in the printhead, thereby preventing a back flow of ink as well as formation of satellite droplets that may degrade image resolution.

Abstract: A memory device including a single transistor having functions of RAM and ROM and methods for operating and manufacturing the same are provided. The memory device includes a single transistor formed on a substrate. The transistor may be a memory transistor having a gate with a nonvolatile memory element, or the nonvolatile memory element is provided between the transistor and the substrate.

Abstract: A method and apparatus for emission lithography using a patterned emitter wherein, in the apparatus for emission lithography, a pyroelectric emitter or a ferroelectric emitter is patterned using a mask and it is then heated. Upon heating, electrons are not emitted from that part of the emitter covered by the mask, but are emitted from the exposed part of the emitter not covered by the mask so that the shape of the emitter pattern is projected onto the substrate. To prevent dispersion of emitted electron beams, which are desired to be parallel, the electron beams are controlled using a magnet, a direct current magnetic field generator or a deflection system, thereby achieving an exact one-to-one projection or an exact x-to-one projection of the desired pattern etched on the substrate.

Abstract: A wafer space supporting apparatus is installed on a support chuck to relieve physical stress caused by thermal expansion or contraction of an object to be fabricated and adjusts itself to support the object to compensate for thermal expansion and contraction as well as minimize hard defects generated. The wafer space supporting apparatus includes a plurality of sliding pockets sunken into the supporting surface of the chuck, and sliding pads respectively floating-coupled in the sliding pockets such that they are spaced apart from the supporting surface so that they may adapt to expansions and contractions of an object to be fabricated, thereby preventing or minimizing any hard defects or physical stress.

Abstract: A method of forming a trench device isolation structure, wherein, after forming a trench in a predetermined area of a semiconductor substrate, a lower isolation pattern, an upper liner pattern, and an upper isolation pattern are sequentially formed to fill the trench. A lower device isolation layer is formed on an entire surface of the semiconductor substrate, and then etched to form the lower isolation pattern so that a top surface of the lower isolation pattern is lower than a top surface of the semiconductor substrate. An upper liner layer and an upper device isolation layer are formed on the entire surface of the semiconductor substrate including the lower isolation pattern, and then etched to form the upper liner pattern. As a result, the upper liner pattern covers the top surface of the lower isolation pattern and surrounds the bottom and the sidewall of the upper isolation pattern.

Abstract: The present invention provides a semiconductor device having a metal suicide layer and a method for forming the metal silicide layer, the semiconductor device having a metal silicide-semiconductor contact structure, wherein the semiconductor device includes a substrate, an insulation layer with an opening, in which a metal silicide layer is formed using a native metal silicide with a first phase and a second phase, upon which a conductive layer is formed. The second phase has a first stoichiometrical composition ratio different from a second stoichiometrical composition ratio of the first phase. A reaction between the metal silicide layer of the first phase and the silicon results in the metal silicide layer of the second phase having high phase stability and low resistance.

Abstract: An apparatus and method for obtaining data for diagnosing the condition of a living body without harming living tissue using an ultrahigh frequency (UHF) signal includes a signal transmitter, a signal receiver, and a signal processor. Signal transmitter generates a UHF signal and radiates the UHF signal at a first of two acupuncture points of a living body. The signal receiver receives a UHF signal emitted from a second acupuncture point, detects and outputs the magnitude of the received UHF signal.

Abstract: A DRAM device in which a portion of bit lines has enlarged width portions at a portion of a peripheral/core area to be connected with upper layered circuit wiring through metal contacts, includes spacers formed of a layer of material having an etch selectivity with respect to a bit line interlayer insulating layer deposited after said bit lines are formed, and disposed on sides of an upper surface of each said enlarged width portion to protect sides of said enlarged width portions; an interlayer insulating layer and at least a portion of an etch stop layer disposed between said bit lines and transistors of a substrate; and metal contact pads formed along with bit line contact plugs to pass through said interlayer insulating layer and said etch stop layer.

Abstract: A method for fabricating a MEMS device having a fixing part fixed to a substrate, a connecting part, a driving part, a driving electrode, and contact parts, includes patterning the driving electrode on the substrate; forming an insulation layer on the substrate; patterning the insulation layer and etching a fixing region and a contact region of the insulation layer; forming a metal layer over the substrate; planarizing the metal layer until the insulation layer is exposed; forming a sacrificial layer on the substrate; patterning the sacrificial layer to form an opening exposing a portion of the insulation layer and the metal layer in the fixing region; forming a MEMS structure layer on the sacrificial layer to partially fill the opening, thereby forming sidewalls therein; and selectively removing a portion of the sacrificial layer by etching so that a portion of the sacrificial layer remains in the fixing region.

Abstract: A self-aligned contact structure in a semiconductor device and methods for making such contact structure wherein the semiconductor device has a semiconductor substrate having active regions, an interlayer insulating layer covering the semiconductor substrate excluding at least a portion of each active region, at least two parallel interconnections on the interlayer insulating layer, at least one active region being relatively disposed between the at least two parallel interconnections, each interconnection having sidewalls, bottom and a width (x), a mask pattern having a top portion (z) and a bottom portion (y) formed on each interconnection, and a conductive layer pattern penetrating at least a portion of the interlayer insulating layer between the mask pattern and being electrically connected to at least one active region, wherein: x≦y≦z and x<z.

Abstract: An apparatus and method for measuring blood pressure using linearly varying air pressure, including a compression unit; an air pump that injects air into the compression unit; a pressure sensor that senses and outputs the air pressure of the compression unit; an ADC that converts and outputs the result of the sensing as a pressure signal; a controller that calculates a current pressure value of the compression unit from the pressure signal and a linear pressure of the compression unit that is linearly dropped corresponding to the current pressure value and generates the first control signal in response to the current pressure value and a second control signal from the result of a comparison of the current pressure value and the linear pressure; a DAC that converts and outputs the second control signal as an exhaust control signal; and a proportional control valve that exhausts air from the compression unit.

Abstract: A MOS transistor having a T-shaped gate electrode and a method for fabricating the same are provided, wherein the MOS transistor includes a T-shaped gate electrode on a semiconductor substrate; an L-shaped lower spacer disposed at both sides of the gate electrode to cover a top surface of the semiconductor substrate; and low-, mid-, and high-concentration impurity regions formed in the semiconductor substrate of both sides of the gate electrode. The high-concentration impurity region is disposed in the semiconductor substrate next to the lower spacer and the mid-concentration impurity region is disposed between the high- and low-concentration impurity regions. A MOS transistor according to the present invention provides a decrease in a capacitance, a decrease in a channel length, and an increase in a cross-sectional area of the gate electrode. At the same time, the mid-concentration impurity region provides a decrease in a source/drain resistance Rsd.

Abstract: A method and apparatus for noninvasively monitoring hemoglobin concentration and oxygen saturation, wherein the method includes selecting at least two wavelengths from a region of wavelengths in which an extinction coefficient for water is smaller that for hemoglobin, the at least two wavelengths including at least two isobestic wavelengths; sequentially radiating incident light beams having the selected wavelengths onto a predetermined site of a body which includes a blood vessel; receiving, at another site of the body, light beams sequentially transmitted through the predetermined site and converting the received light beams into electrical signals; calculating the light attenuation variation caused by pulses of blood for the respective wavelengths from the electrical signals; obtaining at least one ratio of the light attenuation variation between the selected wavelengths; and calculating the hemoglobin concentration CHb in blood using the calculated at least one ratio of the light attenuation variation bet

Abstract: An apparatus for cleaning a semiconductor wafer and method for cleaning a wafer using the same wherein, the apparatus includes a chamber on which a wafer is mounted, a revolving chuck mounted in the chamber for supporting and fixing the wafer, a nozzle for spraying cleaning solution onto the wafer, a cover for covering an upper part of the chamber, a heating lamp fixed on an upper part of the cover for heating the wafer or the cleaning solution, a cooling water conduit surrounding the cover, and an antipollution plate mounted on a lower part of the heating lamp in the cover for preventing the heating lamp from being polluted by the cleaning solution. According to an embodiment of the present invention, the cleaning solution, preferably of ozone water, hydrogen water, or electrolytic-ionized water, is heated for a short time and used to clean the wafer.

Abstract: A Scalable Two-Transistor Memory (STTM) cell array having a 4F2 unit cell area, where F is the minimum feature size. The data lines and the bit lines alternate and are adjacent to each other along the Y-axis direction, and the word lines are laid out along the X-axis direction. Each STTM cell consists of a floating gate MOS sensing transistor at the surface of a semiconductor substrate, with a vertical double sidewall gate multiple tunnel junction barrier programming MOS transistor on top of the sensing transistor. A data line connects all source regions of the programming transistors and a bit line connects all the source/drain regions of the sensing transistors in a column direction. A word line connects all double sidewall gate regions of programming transistors in a row direction. This invention also deals with a column addressing circuit as well as the driving method for the circuit.

Abstract: A method for forming void-free, low contact-resistance damascene interconnects during a manufacturing process of an integrated circuit having both narrow and deep openings and wide and shallow openings on a same substrate features a two-step copper (Cu) deposition process, with a high-temperature rapid annealing process being conducted after the first deposition. After forming in a top surface a narrow and deep opening and a wide and shallow opening, a first copper (Cu) layer is deposited on a seed layer using a small-grained Cu material to completely fill the narrow and deep opening. After annealing the first Cu layer to reduce stress on the resulting structure, a second layer of large-grained Cu material is deposited on the annealed first Cu layer to fill the remainder of the openings. The resulting assembly, which requires no additional annealing, is then planarized to the original surface.

Abstract: A method of forming a self-aligned contact pad for use in a semiconductor device, including: forming a gate having a gate mask formed thereon on a semiconductor substrate, the semiconductor substrate including an active region and a non-active region, forming a spacer on both sidewalls of the gate and the gate mask, forming an interlayer insulating layer over the entire surface of the semiconductor substrate, the interlayer insulating layer including an opening formed on the active region of the semiconductor substrate, forming a conductive material layer over the entire surface of the semiconductor substrate to cover the interlayer insulating layer, etching-back the conductive material layer until the interlayer insulating layer is exposed, and performing a multi-step CMP process to form contact pads in the opening of the interlayer insulating layer, such that the contact pads are electrically insulated from each other.

Abstract: A spin-on glass (SOG) composition and a method of forming a silicon oxide layer utilizing the SOG composition are disclosed. The method includes coating on a semiconductor substrate having a surface discontinuity, an SOG composition containing perhydropolysilazane having a compound of the formula —(SiH2NH)n— wherein n represents a positive integer, a weight average molecular weight within the range of about 4,000 to 8,000, and a molecular weight dispersion within the range of about 3.0 to 4.0, to form a planar SOG layer. The SOG layer is converted to a silicon oxide layer with a planar surface by curing the SOG layer. Also disclosed is a semiconductor device made by the method.

Abstract: The present invention discloses a semiconductor memory device having a multiple tunnel junction pattern and a method of forming the same. The semiconductor memory device includes a unit cell composed of planar transistor and vertical transistors. The planar transistor includes first and second conductive regions formed at predetermined regions of a semiconductor substrate and a storage node stacked on a channel region therebetween. The vertical transistor includes a storage node, a multiple tunnel junction pattern stacked thereon, a data line stacked thereon, and a word line for covering both sidewalls of the storage node and the multiple tunnel junction pattern. Width of the multiple tunnel junction pattern is narrower than the storage node and data lines. Semiconductor layers and tunnel oxide layers are alternately and repeatedly stacked and anisotropically etched to form the multiple tunnel junction pattern of narrow width while forming the data line and the storage node.

Abstract: A method of forming a shallow trench isolation type semiconductor device comprises forming an etch protecting layer pattern to define at least one active region on a substrate, forming at least one trench by etching the substrate partially by using the etch protecting layer pattern as an etch mask, forming a thermal-oxide film on an inner wall of the trench, filling the trench having the thermal-oxide film with a CVD silicon oxide layer to form an isolation layer, removing the etch protecting layer pattern from the substrate over which the isolation layer is formed, removing the thermal-oxide film formed on a top end of the inner wall of the trench to a depth of 100 to 350 Å, preferably 200 Å from the upper surface of the substrate, and forming a gate oxide film on the substrate from which the active region and the top end are exposed.