Abstract: A duty cycle correction circuit is operated by maintaining a state of a duty cycle corrected signal, generating a first transition in the state of the duty cycle corrected signal responsive to an input signal, and generating a second transition in the state of the duty cycle corrected signal responsive to a delayed version of the input signal.

Abstract: Delay locked loop (DLL) circuits have a phase detector circuit that can detect a phase difference between an input clock signal and an output clock signal over a time period of 0T-2T. The delay applied to generate the output signal is adjusted based on the detected phase difference. A middle clock signal can be generated that has a phase that is between the input clock signal and the output clock signal. The phase detector circuit may be configured to detect the phase difference between the input clock signal and the output clock signal over the time period 0T-2T responsive to the middle clock signal.

Abstract: A charge trap flash memory device and method of making same are provided. The device includes: a tunnel insulating layer, a charge trap layer; a blocking insulating layer; and a gate electrode sequentially formed on a substrate. The charge trap layer includes: plural trap layers comprising a first material having a first band gap energy level; spaced apart nanodots, each nanodot being at least partially surrounded by at least one of the trap layers, wherein the nanodots comprise a second material having a second band gap energy level that is lower than the first band gap energy level; and an intermediate blocking layer comprising a third material having a third band gap energy level that is higher than the first band gap energy level, formed between at least two of the trap layers. This structure prevents loss of charges from the charge trap layer and improves charge storage capacity.

Abstract: In a DRAM device and a method of manufacturing the same, a multiple tunnel junction (MTJ) structure is provided, which includes conductive patterns and nonconductive patterns alternately stacked on each other. The nonconductive patterns have a band gap larger than a band gap of the conductive patterns. A gate insulation layer and a gate electrode are formed on a sidewall of the MTJ structure. A word line is connected with the MTJ structure, and a bit line is connected with one of top and bottom surfaces of the MTJ structure. A capacitor is connected with one of top and bottom surfaces of the MTJ structure that is not connected with the bit line. Current leakage in the DRAM device is reduced and a unit cells may be vertically stacked on the substrate, so a smaller surface area of the substrate is required for the DRAM device.

Abstract: Provided are a semiconductor device and a method of driving the semiconductor device. The semiconductor device includes an optical reaction transistor. The optical reaction transistor includes a semiconductor substrate, a tunnel insulation layer formed on the semiconductor substrate, an optical reaction layer formed on the tunnel insulation layer, a blocking insulation layer formed on the optical reaction layer, and a gate electrode formed on the blocking insulation layer.

Abstract: A nonvolatile memory device includes a semiconductor substrate. A charge storage insulating film containing metal silicide nanocrystals is on the substrate. A gate electrode is on the charge storage insulating film. Related methods of forming metal silicide nanocrystals, and methods of forming nonvolatile memory devices including metal silicide nanocrystals, are also disclosed.

Abstract: In a method of forming a silicon-rich nanocrystalline structure by an ALD process, a first gas including a first silicon compound is provided onto an object to form a silicon-rich chemisorption layer on the object. A second gas including oxygen is provided onto the silicon-rich chemisorption layer to form a silicon-rich insulation layer on the object. A third gas including a second silicon compound is provided onto the silicon-rich insulation layer to form a silicon nanocrystalline layer on the silicon-rich insulation layer. The first gas, the second gas and the third gas may be repeatedly provided to alternately form the silicon-rich nanocrystalline structure having a plurality of silicon-rich insulation layers and a plurality of silicon nanocrystalline layers on the object.

Abstract: In a method of forming a carbon nano-tube, an oxidized metal layer is formed on a substrate. An insulation layer having an opening is formed on the oxidized metal layer to expose a surface of the oxidized metal layer through the opening. The oxidized metal layer exposed through the opening is converted into a catalyst metal layer pattern for allowing a carbon nano-tube to grow from the catalyst metal layer pattern. The carbon nano-tube grows from the catalyst metal layer pattern to form a carbon nano-tube wire in the opening. Thus, the carbon nano-tube may not grow between the insulation layer pattern and the catalyst metal layer pattern.

Abstract: A method of forming a microelectronic device includes forming a groove structure having opposing sidewalls and a surface therebetween on a substrate to define a nano line arrangement region. The nano line arrangement region has a predetermined width and a predetermined length greater than the width. At least one nano line is formed in the nano line arrangement region extending substantially along the length thereof and coupled to the surface of the groove structure to define a nano line structure. Related devices are also discussed.

Abstract: A method of forming a nanoscale structure includes providing a substrate having a first layer thereon, the first layer having an opening that exposes a region of the substrate, and contacting the substrate with a catalytic material, wherein the exposed region of the substrate has a first property that attracts the catalytic material, and the first layer has a second property that repels the catalytic material.

Abstract: An integrated circuit capacitor includes first and second electrodes and at least one dielectric layer extending between the first and second electrodes. The first electrode includes at least one carbon nanotube. The capacitor further includes an electrically conductive catalyst material. This catalyst material may be selected from the group consisting of iron, nickel and cobalt and alloys thereof.

Abstract: Provided are a semiconductor device and a method of manufacturing the semiconductor device, for example, a semiconductor device using carbon nanotubes or nanowires as lower electrodes of a capacitor, and a method of manufacturing the semiconductor device. The semiconductor device may include a lower electrode including a plurality of tubes or wires on a semiconductor substrate, a dielectric layer on the surface of the lower electrode, and an upper electrode on the surface of the dielectric layer, wherein the plurality of tubes or wires radiate outwardly from each other centering on the lower portion of the plurality of tubes or wires. Thus, the off current of the capacitor may be increased by increasing the surface area of the lower electrodes of the capacitor.

Abstract: In a DRAM device and a method of manufacturing the same, a multiple tunnel junction (MTJ) structure is provided, which includes conductive patterns and nonconductive patterns alternately stacked on each other. The nonconductive patterns have a band gap larger than a band gap of the conductive patterns. A gate insulation layer and a gate electrode are formed on a sidewall of the MTJ structure. A word line is connected with the MTJ structure, and a bit line is connected with one of top and bottom surfaces of the MTJ structure. A capacitor is connected with one of top and bottom surfaces of the MTJ structure that is not connected with the bit line. Current leakage in the DRAM device is reduced and a unit cells may be vertically stacked on the substrate, so a smaller surface area of the substrate is required for the DRAM device.

Abstract: Single transistor floating body dynamic random access memory (DRAM) cells include a semiconductor substrate and a barrier layer on the semiconductor substrate and a recess channel transistor on the barrier layer. The recess channel transistor includes a source region of a first conductivity type, a drain region of the first conductivity type spaced apart from the source region and a floating body of a second conductivity type between the barrier layer and the source region and the drain region. The floating body includes a recess region between the source region and the drain region.

Abstract: Complementary metal oxide semiconductor (CMOS) static random access memory (SRAM) cells include at least a first inverter formed in a fin-shaped pattern of stacked semiconductor regions of opposite conductivity type. In some of these embodiments, the first inverter includes a first conductivity type (e.g., P-type or N-type) MOS load transistor electrically coupled in series with a second conductivity type (e.g., N-type of P-type) MOS driver transistor. The first inverter is arranged so that active regions of the first conductivity type MOS load transistor and the second conductivity type driver transistor are vertically stacked relative to each other within a first portion of a vertical dual-conductivity semiconductor fin structure. This fin structure is surrounded on at least three sides by a wraparound gate electrode, which is configured to modulate conductivity of both the active regions in response to a gate signal.

Abstract: A memory device includes an insulating layer formed over a substrate, a gate formed over the insulating layer, and charge storage elements disposed over the insulating layer. The charge storage elements are separated from each other and are electrically insulated, and each of the charge storage elements is capable of storing at least one charge. The charge storage elements can include fullerenes.

Abstract: An integrated circuit capacitor includes first and second electrodes and at least one dielectric layer extending between the first and second electrodes. The first electrode includes at least one carbon nanotube. The capacitor further includes an electrically conductive catalyst material. This catalyst material may be selected from the group consisting of iron, nickel and cobalt and alloys thereof.

Abstract: The present invention provides methods of forming uniform nanoparticle based monolayer films with a high particle density on the surface of a substrate comprising (a) forming a surface modifying layer on a substrate using a material comprising a first functional group that chemically binds to the substrate and a second functional group comprising a group capable of forming van der Waals forces, (b) applying to the surface modifying layer a solution comprising nanoparticles, and (c) curing the resultant structure formed at step (b) for a predetermined time to form a nanoparticle based monolayer film. The present invention further provides substrates and devices comprising the nanoparticle based monolayer films.

Abstract: Methods of fabricating a single transistor floating body dynamic random access memory (DRAM) cell include forming a barrier layer on a semiconductor substrate. A body layer is formed on the barrier layer. An isolation layer is formed defining a floating body region within the body layer. A recess region is formed in the floating body region. A gate electrode is formed in the recess region. Impurity ions of a first conductivity type are implanted into a portion of the floating body region on a first side of the recess region to define a source region and into a portion of the floating body on an opposite side of the recess region to define a drain region to provide a floating body.

Abstract: A semiconductor memory device may have a DRAM cell mode and a non-volatile memory cell mode without a capacitor, including multiple transistors arranged in an array and having floating bodies, word lines connected to gate electrodes of the transistors, bit lines at a first side of the gate electrodes connected to drains of the transistors, source lines at a second side of the gate electrodes, different from the first side, and connected to sources of the transistors on the semiconductor substrate, and charge storage regions between the gate electrodes and the floating bodies.