Abstract: A fin field effect transistor includes a fin protruding from a semiconductor substrate, a gate insulating layer formed so as to cover upper and lateral surfaces of the fin, and a gate electrode formed across the fin so as to cover the gate insulating layer. An upper edge of the fin is rounded so that an electric field concentratedly applied to the upper edge of the fin through the gate electrode is dispersed. A thickness of a portion of the gate insulating layer formed on an upper surface of the fin is greater than a thickness of a portion of the gate insulating layer formed on a lateral surface of the fin, in order to reduce an electric field applied through the gate electrode.

Abstract: A fin field effect transistor includes a fin protruding from a semiconductor substrate, a gate insulating layer formed so as to cover upper and lateral surfaces of the fin, and a gate electrode formed across the fin so as to cover the gate insulating layer. An upper edge of the fin is rounded so that an electric field concentratedly applied to the upper edge of the fin through the gate electrode is dispersed. A thickness of a portion of the gate insulating layer formed on an upper surface of the fin is greater than a thickness of a portion of the gate insulating layer formed on a lateral surface of the fin, in order to reduce an electric field applied through the gate electrode.

Abstract: A recessed channel array transistor may include a substrate, a gate oxide layer, a gate electrode and source/drain regions. The substrate may have an active region and an isolation region. A recess may be formed in the active region. The gate oxide layer may be formed on the recess and the substrate. The gate oxide layer may include a first portion on an intersection between a side end of the recess and a sidewall of the active region and a second portion on a side surface of the recess. The first portion may include a thickness greater than about 70% of a thickness of the second portion. The gate electrode may be formed on the gate oxide layer. The source/drain regions may be formed in the substrate. Thus, the recessed channel array transistor may have a decreased leakage current and an increased on-current.

Abstract: Methods of forming integrated circuit devices include forming an electrically conductive layer containing silicon on a substrate and forming a mask pattern on the electrically conductive layer. The electrically conductive layer is selectively etched to define a first sidewall thereon, using the mask pattern as an etching mask. The first sidewall of the electrically conductive layer may be exposed to a nitrogen plasma to thereby form a first silicon nitride layer on the first sidewall. The electrically conductive layer is then selectively etched again to expose a second sidewall thereon that is free of the first silicon nitride layer. The mask pattern may be used again as an etching mask during this second step of selectively etching the electrically conductive layer.

Abstract: A semiconductor device may include an isolation layer, gate electrodes, an insulating interlayer, an impurity region, a capping layer and a plug. The isolation layer may be formed in the substrate. The gate electrodes may be formed on the substrate. The insulating interlayer may be formed on the gate electrodes. The insulating interlayer may have a contact hole between the gate electrodes. The impurity region may be in the substrate exposed through the contact hole. The capping layer may be on the impurity region. The plug may be on the capping layer. Thus, the impurities may not be lost from the impurity region.

Abstract: Provided are methods of forming a low temperature deposition layer and methods of manufacturing a semiconductor device using the same. The method of manufacturing a semiconductor device comprises forming a mask layer exposing a gate pattern on a substrate on which the gate pattern is formed, forming a sacrifice layer on the mask layer and on a substrate not covered by the mask layer using a plasma ion immersion implantation and deposition (PIIID), and doping a substrate adjacent to both sidewalls of the gate pattern with an impurity.

Abstract: Disclosed is a light emitting diode (LED) device that comprises a crystal structure of a sapphire substrate-free gallium nitride (GaN) LED, wherein the crystal structure is mounted on a first surface of a sub-mount substrate in the form of a unit chip, and the first surface of the sub-mount substrate has a surface area greater than the surface area of a region in which the unit chip is bonded. Preforms for manufacturing the LED device and a method for manufacturing the LED device are also disclosed. The sapphire substrate, on which the crystal structure of the light emitting diode has grown, is processed into a unit chip before being removed. Thus, any crack in the crystal structure of the light emitting diode that may occur during the removal of the sapphire substrate can be prevented. Therefore, a thin light emitting diode device can be manufactured in a mass production system.

Abstract: In plasma ion doping operations, a wafer is positioned on a susceptor within a reaction chamber and an ion doping source gas is plasmalyzed in an upper part of the reaction chamber above a major surface of the wafer while supplying a control gas into the reaction chamber in a lower part of the reaction chamber opposite the major surface of the wafer to thereby dope ions into the major surface of the wafer. The ion doping source gas may comprise at least one halide gas, and the control gas may comprise at least one depositing gas, such as a silane gas. In further embodiments, a diluent gas, such as an inert gas, may be supplied to the reaction chamber while supplying the ion doping source gas and the control gas. Related plasma ion doping apparatus are described.

Abstract: A plasma doping method includes providing a substrate including a layer to be doped inside a chamber, and supplying first and second source gases to the layer to achieve a desired doping concentration. The first source gas includes a component configured to increase a thickness of the layer, and the second gas includes a component configured to reduce a thickness of the layer.

Abstract: In a cleaning apparatus and a method of cleaning a chamber used in manufacturing a semiconductor device, a first plasma may be provided into a chamber to remove a first residue from an inner wall of the chamber where the first residue is attached. A second plasma may then be provided into the chamber to remove a second residue formed by the first plasma from an inside of the chamber where the second residue remains. The second residue formed by the first plasma used to clean the chamber may not pollute a semiconductor substrate located in the chamber.

Abstract: A radio frequency identification (RFID) system includes a reader capable of reading data of each RFID device without data collision when a number of contactless smart cards and RFID tags within a radio frequency field and an RFID tag.