Abstract: A High electron mobility transistor (HEMT) includes a source electrode, a gate electrode, a drain electrode, a channel forming layer in which a two-dimensional electron gas (2DEG) channel is induced, and a channel supplying layer for inducing the 2DEG channel in the channel forming layer. The source electrode and the drain electrode are located on the channel supplying layer. A channel increase layer is between the channel supplying layer and the source and drain electrodes. A thickness of the channel supplying layer is less than about 15 nm.

Abstract: A power device includes a switching device having a control terminal and an output terminal; and a driving circuit configured to provide a driving voltage to the control terminal such that a voltage between the control terminal and the output terminal remains less than or equal to a critical voltage. A rise time required for the driving voltage to reach a target level is determined according to current-voltage characteristics of the switching device. And, when the voltage between the control terminal and the output terminal exceeds the critical voltage, leakage current is generated between the control terminal and the output terminal.

Abstract: High electron mobility transistors (HEMTs) including lightly doped drain (LDD) regions and methods of manufacturing the same. A HEMT includes a source, a drain, a gate, a channel supplying layer for forming at least a 2-dimensional electron gas (2DEG) channel, and a channel formation layer in which at least the 2DEG channel is formed. The channel supplying layer includes a plurality of semiconductor layers having different polarizabilities. A portion of the channel supplying layer is recessed. One of the plurality of semiconductor layers, which is positioned below an uppermost layer is an etching buffer layer, as well as a channel supplying layer.

Abstract: Provided is a semiconductor device that may include a switching device having a negative threshold voltage, and a driving unit between a power terminal and a ground terminal and providing a driving voltage for driving the switching device. The switching device may be connected to a virtual ground node having a virtual ground voltage that is greater than a ground voltage supplied from the ground terminal and may be turned on when a difference between the driving voltage and the virtual ground voltage is greater than the negative threshold voltage.

Abstract: High electron mobility transistors (HEMT) exhibiting dual depletion and methods of manufacturing the same. The HEMT includes a source electrode, a gate electrode and a drain electrode disposed on a plurality of semiconductor layers having different polarities. A dual depletion region exists between the source electrode and the drain electrode. The plurality of semiconductor layers includes an upper material layer, an intermediate material layer and a lower material layer, and a polarity of the intermediate material layer is different from polarities of the upper material layer and the lower material layer.

Abstract: A method of manufacturing a High Electron Mobility Transistor (HEMT) may include forming first and second material layers having different lattice constants on a substrate, forming a source, a drain, and a gate on the second material layer, and changing the second material layer between the gate and the drain into a different material layer, or changing a thickness of the second material layer, or forming a p-type semiconductor layer on the second material layer. The change in the second material layer may occur in an entire region of the second material layer between the gate and the drain, or only in a partial region of the second material layer adjacent to the gate. The p-type semiconductor layer may be formed on an entire top surface of the second material layer between the gate and the drain, or only on a partial region of the top surface adjacent to the gate.

Abstract: A phase change memory device includes a switching device and a storage node connected to the switching device. The storage node includes a bottom stack, a phase change layer disposed on the bottom stack and a top stack disposed on the phase change layer. The phase change layer includes a unit for increasing a path of current flowing through the phase change layer and reducing a volume of a phase change memory region. The area of a surface of the unit disposed opposite to the bottom stack is greater than or equal to the area of a surface of the bottom stack in contact with the phase change layer.

Abstract: Power electronic devices including 2-dimensional electron gas (2DEG) channels and methods of manufacturing the same. A power electronic device includes lower and upper material layers for forming a 2DEG channel, and a gate contacting an upper surface of the upper material layer. A region below the gate of the 2DEG channel is an off region where the density of a 2DEG is reduced or zero. The entire upper material layer may be continuous and may have a uniform thickness. A region of the upper material layer under the gate contains an impurity for reducing or eliminating a lattice constant difference between the lower and upper material layers.

Abstract: A phase change memory device includes a switching device and a storage node connected to the switching device. The storage node includes a bottom stack, a phase change layer disposed on the bottom stack and a top stack disposed on the phase change layer. The phase change layer includes a unit for increasing a path of current flowing through the phase change layer and reducing a volume of a phase change memory region. The area of a surface of the unit disposed opposite to the bottom stack is greater than or equal to the area of a surface of the bottom stack in contact with the phase change layer.

Abstract: Field effect semiconductor devices and methods of manufacturing the same are provided, the field effect semiconductor devices include a second semiconductor layer on a first surface of a first semiconductor layer, a first and a second third semiconductor layer respectively on two sides of the second semiconductor layer, a source and a drain respectively on the first and second third semiconductor layer, and a gate electrode on a second surface of the first semiconductor layer.

Abstract: An ion generator of an ion implanter, the ion generator includes: an arc chamber provided with a slit for ion extraction and forming an equipotential surface with a first voltage; a filament installed inside of the arc chamber, heated to a predetermined temperature and generating electrons; magnetic field devices provided outside of the arc chamber and supplied with a current from a current source and generating a magnetic field in the arc chamber; a gas discharge device injecting a predetermined gas into the arc chamber; and an electrode positioned opposite to the slit and supplied with a second voltage having a high voltage than the first voltage from a voltage source and generating a magnetic field in the arc chamber.

Abstract: An electron cyclotron resonance equipment generates plasma by application of a processing gas and microwave energy into a vacuum chamber having a wafer therein in an environment of reduced pressure. The equipment includes a horn antenna assembly mounted onto an uppermost end of the vacuum chamber for radiating the microwave energy supplied from a high-frequency generator into the vacuum chamber. The horn antenna enables extension and retraction in a lengthwise direction to change a flare angle of the horn antenna. The equipment is provided with a fixed antenna and a plurality of mobile antennas to configure a horn antenna assembly, thereby enabling control of the flare angle in the horn antenna as a result of displacement of the mobile antennas. Thus, the uniformity in radiation of the microwave energy within plasma chamber can be controlled with efficiency.

Abstract: A storage node, phase change memory device having a storage node, a method of fabricating the phase change memory device and a method of operating the phase change memory device are provided. The phase change memory device includes a switching device and a storage node connecting to the switching device. The storage node includes a bottom electrode, a phase change layer formed on the bottom electrode, a material layer formed on the phase change layer and a top electrode formed on the phase change layer around the material layer.

Abstract: A phase change memory device includes a switching device and a storage node connected to the switching device. The storage node includes a bottom stack, a phase change layer disposed on the bottom stack and a top stack disposed on the phase change layer. The phase change layer includes a unit for increasing a path of current flowing through the phase change layer and reducing a volume of a phase change memory region. The area of a surface of the unit disposed opposite to the bottom stack is greater than or equal to the area of a surface of the bottom stack in contact with the phase change layer.

Abstract: An ion generator of an ion implanter, the ion generator includes: an arc chamber provided with a slit for ion extraction and forming an equipotential surface with a first voltage; a filament installed inside of the arc chamber, heated to a predetermined temperature and generating electrons; magnetic field devices provided outside of the arc chamber and supplied with a current from a current source and generating a magnetic field in the arc chamber; a gas discharge device injecting a predetermined gas into the arc chamber; and an electrode positioned opposite to the slit and supplied with a second voltage having a high voltage than the first voltage from a voltage source and generating a magnetic field in the arc chamber.

Abstract: In a method of doping ions into an object, such as a substrate, using plasma, a doping gas may be provided between first and second electrodes in a chamber. An electric field may be formed between the first and the second electrodes to excite the doping gas to a plasma state. The electric field may be formed by applying a first power having a first positive electric potential and a second power having a second positive electric potential, the second positive electric potential being higher than the first positive electric potential. The electric field may be reversed in direction by blocking the second power from being applied to the second electrode. Accumulated ions on the substrate may be effectively neutralized by introducing electrons toward the substrate so that arcing generation may be prevented.

Abstract: A method of doping ions into an object using plasma, including providing a doping gas between a first electrode and a second electrode, where an object is disposed between the first and the second electrodes, applying a first power to the first electrode and grounding the second electrode, exciting the doping gas to a plasma state, directing ions toward the object to be doped, applying a second power to the second electrode and grounding the first electrode, and counting a dose of the ions directed toward the second electrode, and an apparatus for performing the same.

Abstract: An elementary plasma source for generating plasma is provided. In the elementary plasma source, first and second magnets are shaped like a hollow cylinder, and the second magnet surrounds the first magnet, for forming a magnetic trap between the first and second magnets. A guide provides microwaves to a space between the first and second magnets.

Abstract: An electron cyclotron resonance equipment generates plasma by application of a processing gas and microwave energy into a vacuum chamber having a wafer therein in an environment of reduced pressure. The equipment includes a horn antenna assembly mounted onto an uppermost end of the vacuum chamber for radiating the microwave energy supplied from a high-frequency generator into the vacuum chamber. The horn antenna enables extension and retraction in a lengthwise direction to change a flare angle of the horn antenna. The equipment is provided with a fixed antenna and a plurality of mobile antennas to configure a horn antenna assembly, thereby enabling control of the flare angle in the horn antenna as a result of displacement of the mobile antennas. Thus, the uniformity in radiation of the microwave energy within plasma chamber can be controlled with efficiency.

Abstract: Disclosed is an apparatus for generating inductively-coupled plasma (ICP). The ICP generation apparatus includes a source region where an ICP antenna coil is mounted, the ICP antenna coil generating inductive electric fields for generating plasma and having a serially-connected concentric circle-type structure, the total number of windings of the ICP antenna coil being greater than 2, the ICP antenna coil having a structure in which at least one circular winging closest to the center of the concentric circle is wound in a direction opposite to that of the other windings; a sealed chamber in which a predetermined process is performed on a sample placed on a chuck therein through a reaction between plasma ions and reactive radicals; and a radio frequency (RF) power supply for providing RF electric power of a predetermined frequency to the ICP antenna coil in the source region.