Abstract: A semiconductor device may include a plurality of wiring structures spaced apart from each other, a protection pattern including a metal nitride on each of the wiring structures, a spacer on a sidewall of the protection pattern, and an insulating interlayer structure containing the wiring structures and having an air gap between the wiring structures.

Abstract: A method of fabricating a semiconductor device, the method including forming at least one interconnection structure that includes a metal interconnection and a first insulating pattern sequentially stacked on a substrate; forming barrier patterns covering sidewalls of the interconnection structure; forming second insulating patterns at sides of the interconnection structure, the second insulating patterns being spaced apart from the interconnection structure with the barrier patterns interposed therebetween; forming a via hole in the first insulating pattern by etching a portion of the first insulating pattern, the via hole exposing a top surface of the metal interconnection and sidewalls of the barrier patterns; and forming a via in the via hole.

Abstract: In a method of manufacturing a semiconductor device, a first insulating interlayer and a sacrificial layer is sequentially formed on a substrate. The sacrificial layer is partially removed to form a first opening exposing an upper surface of the first insulating interlayer. An insulating liner including silicon oxide is conformally formed on the exposed upper surface of the first insulating interlayer and a sidewall of the first opening. At least a portion of the insulating liner on the upper surface of the first insulating interlayer and a portion of the first insulating interlayer thereunder are removed to form a second opening connected to the first opening. A self-forming barrier (SFB) pattern is formed on a sidewall of the second opening and the insulating liner. A wiring structure is formed to fill the first and second openings. After the sacrificial layer is removed, a second insulating interlayer is formed.

Abstract: A method for correctly identifying at least one source, in particular at least one nuclide, enclosed in a human body and/or a container, is provided, the method comprising the following steps: detecting and measuring the at least one source by means of a gamma spectroscopic device; identifying, in a first estimation step, the at least one source by means of a standard nuclide identification procedure for evaluating a measured first spectrum of the at least one source; applying a second estimation step on the basis of the result of the first estimation step, wherein the result of the first estimation step is used for acquiring a plurality of second spectra of the at least one source found by the standard nuclide identification procedure for a plurality of absorption scenarios and for a plurality of scattering scenarios; and comparing the measured first spectrum with a scatter and absorber spectrum obtained from the plurality of second spectra generated in the second estimation step.

Abstract: A method of fabricating a semiconductor device, the method including forming at least one interconnection structure that includes a metal interconnection and a first insulating pattern sequentially stacked on a substrate; forming barrier patterns covering sidewalls of the interconnection structure; forming second insulating patterns at sides of the interconnection structure, the second insulating patterns being spaced apart from the interconnection structure with the barrier patterns interposed therebetween; forming a via hole in the first insulating pattern by etching a portion of the first insulating pattern, the via hole exposing a top surface of the metal interconnection and sidewalls of the barrier patterns; and forming a via in the via hole.

Abstract: A method of forming interconnects for semiconductor devices includes forming a lower insulating layer and a lower interconnect on a semiconductor substrate, forming an insulating pattern layer on the lower interconnect through self-assembly, forming an interlayer insulating layer and a trench mask on the insulating pattern layer, forming a preparatory via hole allowing the insulating pattern layer to be exposed by removing a portion of the interlayer insulating layer, forming a trench by etching the interlayer insulating layer using the trench mask, forming a via hole allowing the lower interconnect to be exposed by selectively etching the insulating pattern layer within the preparatory via hole, and filling the trench and the via hole with an conductive material.

Abstract: A semiconductor device may include a plurality of wiring structures spaced apart from each other, a protection pattern including a metal nitride on each of the wiring structures, a spacer on a sidewall of the protection pattern, and an insulating interlayer structure containing the wiring structures and having an air gap between the wiring structures.

Abstract: A detachable liquid crystal display device includes a liquid crystal module and a cradle. The liquid crystal module includes a liquid crystal panel, an optical sheet provided on a rear surface of the liquid crystal panel, an interface disposed on a rear surface of the liquid crystal panel, a power receiver disposed on the rear surface of the liquid crystal panel, a memory card and a timing controller for receiving second image data from external devices and permitting the first image data stored in the memory card to be displayed in the liquid crystal panel. The cradle includes a lamp emitting light, an inverter for supplying alternating current to the lamp, a connector for receiving third image data from external equipment, and an interface converter for applying the third image data to the interface of the liquid crystal module.

Abstract: Provided are a display device and a method for driving the same. The display device includes: a plurality of display modules; a plurality of display module drivers for respectively driving the display modules; a data divider receiving data signals for displaying an image on the display device and separating the received data signals into output data signals corresponding to each respective display module driver; and a timing control signal generator for generating a timing control signal to be supplied commonly to the display module drivers.

Abstract: The present invention provides a modified starch, preparation method and use of the same, also provides a drilling fluid comprising the modified starch which contains bi-substituted starch structural units and tri-substituted starch structural units, wherein, the tri-substituted starch structural units are represented by the following formula (1), the bi-substituted starch structural units are the structural units represented by the following formula (2) and/or the structural units represented by the following formula (3), and the total content of the bi-substituted starch structural units and tri-substituted starch structural units accounts for 20 wt % or more of the modified starch, preferably 20-30 wt %, the weight-average molecular weight of the etherified starch is 50,000-600,000, preferably 80,000-580,000, wherein, R1, R2, and R3 are C1-C5 alkylene respectively, and M1, M2, and M3 are H, alkali metal element, or alkaline earth metal element respectively.

Abstract: A method for correctly identifying at least one source, in particular at least one nuclide, enclosed in a human body and/or a container, is provided, the method comprising the following steps: detecting and measuring the at least one source by means of a gamma spectroscopic device; identifying, in a first estimation step, the at least one source by means of a standard nuclide identification procedure for evaluating a measured first spectrum of the at least one source; applying a second estimation step on the basis of the result of the first estimation step, wherein the result of the first estimation step is used for acquiring a plurality of second spectra of the at least one source found by the standard nuclide identification procedure for a plurality of absorption scenarios and for a plurality of scattering scenarios; and comparing the measured first spectrum with a scatter and absorber spectrum obtained from the plurality of second spectra generated in the second estimation step.

Abstract: A detachable liquid crystal display device includes a liquid crystal module and a cradle. The liquid crystal module includes a liquid crystal panel, an optical sheet provided on a rear surface of the liquid crystal panel, an interface disposed on a rear surface of the liquid crystal panel, a power receiver disposed on the rear surface of the liquid crystal panel, a memory card and a timing controller for receiving second image data from external devices and permitting the first image data stored in the memory card to be displayed in the liquid crystal panel. The cradle includes a lamp emitting light, an inverter for supplying alternating current to the lamp, a connector for receiving third image data from external equipment, and an interface converter for applying the third image data to the interface of the liquid crystal module.

Abstract: The present invention provides a method of inducing stress in a semiconductor device substrate by applying an ion implantation to a gate region before a source/drain annealing process. The source/drain region may then be annealed along with the gate which will cause the gate to expand in certain areas due to said ion implantation. As a result, stress caused by said expansion of the gate is transferred to the channel region in the semiconductor substrate.

Abstract: An expandable multi-module display device cuts block data corresponding to an identification code of the expandable multi-module display device itself, and transmits the data-cut result to a specific flat panel display corresponding to the expandable multi-module display device itself, such that it displays a total image. The expandable multi-module display device includes a multi-panel including a plurality of flat panel displays, several multi-driving boards installed in the flat panel displays, respectively, and a data bus line connected to each of the multi-driving boards. The expandable multi-module display device cuts data corresponding to an identification code of the multi-module display device itself, and provides a specific flat panel display with the cut data corresponding to the multi-driving board itself, and bypasses the remaining data other than the cut data to the multi-driving boards of the remaining flat panel displays other than the specific flat panel display.

Abstract: The present invention discloses a method for implementing fast multicast and a system thereof. The system comprises multicast protocol, forwarding plane and fast multicast control plane, and the fast multicast control plane further comprises management module and agent module.

Abstract: An apparatus for driving an LCD device includes an image display unit having liquid crystal cells in respective regions defined by a plurality of gate and data lines; an over-driving apparatus to detect a signal of a moving image based on a source data and to detect modulated data based on the detected signal, the modulated data changes a response speed of a liquid crystal based on the detected signal; a gate driver to supply scan signals to the gate lines; a data driver to convert the modulated data into analog video signals and to supply the analog video signals to the data lines; and a timing controller to align the modulated data and to generate data control signal and gate control signal, the timing controller outputs the aligned data and the data control signal to the data driver and outputs the gate control signal to the gate driver.

Abstract: A resistive type touch panel includes a first substrate aligned to be facing a second substrate. The first substrate includes a first conductive layer and the second substrate includes a second conductive layer. A plurality of spacers each having a polygonal column shape are disposed between the first and second substrates in predetermined positions. The geometry and center-to-center spacing of the spacers minimizes detection of a distributed activation force applied to one of the first and second substrate while still providing sensitivity to detect concentrated application of an activation force to one of the first and second substrates.

Abstract: A guideway illumination system (100) comprises a first member (16) and a second member (18) each having at least one light source (20) and at least one of the first member (16) and the second member (18) receiving a power source (22). The first member (16) has a closed end (16a) and a connecting end (16b) and the second member has two connecting ends (18a 18b). At least one intermediate member (24) has at least one light source (20) and a male connecting end (24a) and a female connecting end (24b). At least one flexible joining member (26) is also provided, the flexible joining member being capable of bending at least 90° and being joinable to any of the first and second end members and the intermediate members.

Abstract: The present invention provides a method of inducing stress in a semiconductor device substrate by applying an ion implantation to a gate region before a source/drain annealing process. The source/drain region may then be annealed along with the gate which will cause the gate to expand in certain areas due to said ion implantation. As a result, stress caused by said expansion of the gate is transferred to the channel region in the semiconductor substrate.

Abstract: A method for linearizing a radiation detector is provided, the method including measuring a pulse height spectrum of a predetermined radiation source, identifying at least one spectrum template for the predetermined radiation source, and determining a linearization function by comparing the measured pulse height spectrum with the at least one identified spectrum template. The at least one spectrum template is a predefined synthesized energy spectrum for the predetermined radiation source and for the corresponding radiation detector. Further, a detector for measuring one or more types of radiation is provided, the detector being adapted for transforming the measured pulse height spectrum in an energy-calibrated spectrum, the transformation including a linearization step, where a linearization function used with the linearization step is determined according to the inventive method.