Abstract: A drive unit for an electric bicycle, the drive unit including a motor configured to generate a rotary force to drive a wheel of the electric bicycle, and a reduction gear unit provided with a plurality of gears to decelerate a rotary force generated from the motor, wherein the motor is provided with a rotor which has an accommodation space formed at a center thereof and a stator installed to surround the rotor while being spaced apart from the rotor by a predetermined interval, and the reduction gear unit includes a first planet gear assembly disposed on an accommodation space inside the motor and connected to the rotor, and a second planet gear assembly disposed outside the motor and connected to the first planet gear assembly.

Abstract: In one embodiment, the semiconductor device includes at least one active fin protruding from a substrate, a first gate electrode crossing the active fin, and a first impurity region formed on the active fin at a first side of the first gate electrode. At least a portion of the first impurity region is formed in a first epitaxial layer portion on the active fin. A second impurity region is formed on the active fin at a second side of the first gate electrode. The second impurity region has at least a portion not formed in an epitaxial layer.

Abstract: Provided is a metal-oxide semiconductor (MOS) transistor containing a metal gate pattern. The semiconductor device includes a p-channel metal-oxide semiconductor (PMOS) transistor including a semiconductor substrate, a first insulating film formed on the semiconductor substrate, a first metal gate conductive film formed on the first insulating film, and a nitrogen diffusion blocking film formed between the first insulating film and the first metal gate conductive film, and an n-channel metal-oxide semiconductor (NMOS) transistor including the semiconductor substrate, a second insulating film formed on the semiconductor substrate, a second metal gate conductive film formed on the second insulating film, and a reaction blocking film formed of metal nitride and formed between the second insulating film and the second metal gate conductive film. According to the inventive concept, a reaction between a metal gate film and an insulating film may be minimized so as to result in a highly reliable MOS transistor.

Abstract: In a method of fabricating a semiconductor device by selectively forming a diffusion barrier layer, and a semiconductor device fabricated thereby, a conductive pattern and an insulating layer, which covers the conductive pattern, are formed on a semiconductor substrate. The insulating layer is patterned, thereby forming an opening for exposing at least a portion of the conductive pattern. Then, a diffusion barrier layer is formed on the semiconductor substrate having the opening, using a selective deposition technique. The diffusion barrier layer is formed to a thickness that is less on the exposed conductive pattern than the thickness of the diffusion barrier layer on the insulating layer exposed inside the opening. Then, the diffusion barrier layer is etched, thereby forming a recessed diffusion barrier layer. In this manner, metal atoms are prevented from being diffused from a metal plug filling the opening or a metal interconnect to the insulating layer.

Abstract: In a MIM capacitor, and method of fabricating the same, the MIM capacitor includes an interlayer insulating layer on a semiconductor substrate, a lower metal interconnection and a lower metal electrode in the interlayer insulating layer, an intermetal dielectric layer covering the lower metal interconnection, the lower metal electrode, and the interlayer insulating layer, a via hole exposing the lower metal interconnection, an upper metal interconnection groove crossing over the via hole, at least one capacitor trench region exposing the lower metal electrode, an upper metal interconnection filling the upper metal interconnection groove, the upper metal interconnection being electrically connected to the lower metal interconnection through the via hole, a dielectric layer covering inner surfaces of the at least one capacitor trench region, and an upper metal electrode surrounded by the dielectric layer to fill the at least one capacitor trench region.

Abstract: In a MIM capacitor, and method of fabricating the same, the MIM capacitor includes an interlayer insulating layer on a semiconductor substrate, a lower metal interconnection and a lower metal electrode in the interlayer insulating layer, an intermetal dielectric layer covering the lower metal interconnection, the lower metal electrode, and the interlayer insulating layer, a via hole exposing the lower metal interconnection, an upper metal interconnection groove crossing over the via hole, at least one capacitor trench region exposing the lower metal electrode, an upper metal interconnection filling the upper metal interconnection groove, the upper metal interconnection being electrically connected to the lower metal interconnection through the via hole, a dielectric layer covering inner surfaces of the at least one capacitor trench region, and an upper metal electrode surrounded by the dielectric layer to fill the at least one capacitor trench region.

Abstract: In a method of fabricating a semiconductor device by selectively forming a diffusion barrier layer, and a semiconductor device fabricated thereby, a conductive pattern and an insulating layer, which covers the conductive pattern, are formed on a semiconductor substrate. The insulating layer is patterned, thereby forming an opening for exposing at least a portion of the conductive pattern. Then, a diffusion barrier layer is formed on the semiconductor substrate having the opening, using a selective deposition technique. The diffusion barrier layer is formed to a thickness that is less on the exposed conductive pattern than the thickness of the diffusion barrier layer on the insulating layer exposed inside the opening. Then, the diffusion barrier layer is etched, thereby forming a recessed diffusion barrier layer. In this manner, metal atoms are prevented from being diffused from a metal plug filling the opening or a metal interconnect to the insulating layer.

Abstract: An inductor for a system-on-a-chip and a method for manufacturing the inductor are disclosed. The inductor comprises a conductive line formed by connecting a plurality of conductive patterns grown from a seed layer formed on a lower wiring. The method comprises using an electrolytic plating process or an electroless plating process to grow the plurality of adjacent conductive patterns from the seed layer until they become connected. The method also enables adjusting the height and width of the conductive line to desired levels.