Abstract: Example embodiments of the present invention relate to a semiconductor device and methods of fabricating the same. Other example embodiments of the present invention relate to a fin-field effect transistor (Fin-FET) having a fin-type channel region and methods of fabricating the same. A Fin-FET having a gate all around (GAA) structure that may use an entire area around a fin as a channel region is provided. The Fin-FET having the GAA structure includes a semiconductor substrate having a body, a pair of support pillars and a fin. The pair of support pillars may protrude from the body. A fin may be spaced apart from the body and may have ends connected to and supported by the pair of support pillars. A gate electrode may surround at least a portion of the fin of the semiconductor substrate. The gate electrode may be insulated from the semiconductor substrate. A gate insulation layer may be interposed between the gate electrode and the fin of the semiconductor substrate.

Abstract: Example embodiments provide a capacitorless dynamic random access memory (DRAM), and methods of manufacturing and operating the same. The capacitorless DRAM according to example embodiments may include a semiconductor layer separated from a top surface of a substrate and that contains a source region, a drain region, and a channel region, a charge reserving layer formed on the channel region, and a gate formed on the substrate to contact the channel region and the charge reserving layer.

Abstract: Provided are a non-volatile memory device, which may have higher integration density, improved or optimal structure, and/or reduce or minimize interference between adjacent cells without using an SOI substrate, and a method of fabricating the non-volatile memory device. The non-volatile memory device may include: a semiconductor substrate comprising a body, and a pair of fins protruding from the body; a buried insulating layer filling between the pair of fins; a pair of floating gate electrodes on outer surfaces of the pair of fins to a height greater than that of the pair of fins; and a control gate electrode on the pair of floating gate electrodes.

Abstract: Off-axis projection optics that includes first and second mirrors positioned off-axis and sharing a confocal point that are arranged to reduce linear astigmatism. If a distance between an object plane and the first mirror is l1, an incident angle of light coming from the object plane to the first mirror is i1, a distance between the first mirror and the confocal point is l1?, a distance between the confocal point and the second mirror is l2, an incident angle of light coming from the first mirror to the second mirror is i2, and a distance between the second mirror and an image plane is l2?, the off-axis projection optics may satisfy the following equation: l 1 ? + l 1 l 1 ? tan ? ? i 1 = l 2 ? + l 2 l 2 ? tan ? ? i 2 .

Abstract: Memory devices and methods of manufacturing the same are provided. In a memory device, a memory-switch structure is formed between a first and second electrode. The memory-switch structure includes a memory resistor and a switch structure. The switch structure controls current supplied to the memory resistor. A memory region of the memory resistor and a switch region of the switch structure are different from each other.

Abstract: Example embodiments include nonvolatile memory devices that have good operation performance and may be made in a highly integrated structure, and methods of operating the same. Example embodiments of the nonvolatile memory devices include a substrate electrode, and a semiconductor channel layer on the substrate electrode, a floating gate electrode on the substrate electrode, wherein a portion of the floating gate electrode faces the semiconductor channel layer, a control gate electrode on the floating gate electrode, and wherein a distance between a portion of the floating gate electrode and the substrate electrode is smaller than a distance between the semiconductor channel layer and the substrate electrode wherein charge tunneling occurs.

Abstract: A ferroelectric capacitor comprises a first electrode comprising an alloy of Ir and Ru, a ferroelectric layer disposed on the first electrode, and a second electrode disposed on the ferroelectric layer. A ferroelectric memory comprises a substrate and a plurality of memory cells arranged on the substrate. Each memory cell comprises a first electrode comprising an alloy of Ir and Ru, a ferroelectric layer disposed on the first electrode, and a second electrode disposed on the ferroelectric layer.

Abstract: Provided are methods for fabricating semiconductor devices incorporating a fin-FET structure that provides body-bias control, exhibits some characteristic advantages associated with SOI structures, provides increased operating current and/or reduced contact resistance. The methods for fabricating semiconductor devices include forming insulating spacers on the sidewalls of a protruding portion of a first insulation film; forming a second trench by removing exposed regions of the semiconductor substrate using the insulating spacers as an etch mask, and thus forming fins in contact with and supported by the first insulation film. After forming the fins, a third insulation film is formed to fill the second trench and support the fins. A portion of the first insulation film is then removed to open a space between the fins in which additional structures including gate dielectrics, gate electrodes and additional contact, insulating and storage node structures may be formed.

Abstract: A field effect transistor having at least one Ge nanorod and a method of manufacturing the field effect transistor are provided. The field effect transistor may include a gate oxide layer formed on a silicon substrate, at least one nanorod embedded in the gate oxide layer having both ends thereof exposed, a source electrode and a drain electrode connected to opposite sides of the at least one Ge nanorod, and a gate electrode formed on the gate oxide layer between the source electrode and the drain electrode.

Abstract: A non-volatile memory device includes memory transistors disposed on a semiconductor substrate in a NAND string. A string select transistor is disposed at a first end of the NAND string, and a ground select transistor is disposed at a second end of the NAN string. Bit lines are electrically connected to the semiconductor substrate outside of the string select transistor and a gate electrode of the ground select transistor.

Abstract: A method of preparing a semiconductor film on a substrate is disclosed. The method includes arranging an insulating substrate in a deposition chamber and depositing a semiconductor film onto the insulating substrate using ion beam deposition, wherein a temperature of the insulating substrate during the depositing does not exceed 250° C. The method can produce a thin film transistor. The disclosed ion beam deposition method forms, at lower temperature and with low impurities, a film morphology with desired smoothness and grain size. Deposition of semiconductor films on low melting point substrates, such as plastic flexible substrates, is enables.

Abstract: Non-volatile memory devices and a method thereof are provided. A non-volatile memory device according to an example embodiment of the present invention may include a first transistor including a source, a drain, and a control gate, a first storage node coupled to the first transistor, the first storage node configured to store information in a first manner, a first diode having a first end connected to the source of the transistor, the first diode configured to rectify a flow of current from the source of the transistor and a second storage node connected to a second end of the first diode, the second storage node configured to store information in a second manner.

Abstract: A method of fabricating a non-volatile memory device according to example embodiments may include forming a semiconductor layer on a substrate. A plurality of lower charge storing layers may be formed on a bottom surface of the semiconductor layer. A plurality of lower control gate electrodes may be formed on the plurality of lower charge storing layers. A plurality of upper charge storing layers may be formed on a top surface of the semiconductor layer. A plurality of upper control gate electrodes may be formed on the plurality of upper charge storing layers, wherein the plurality of lower and upper control gate electrodes may be arranged alternately.

Abstract: Provided is a method for manufacturing a material layer capable of increasing the deposition rate of a noble metal layer on a ferroelectric layer, a method for manufacturing a ferroelectric capacitor using the same, a ferroelectric capacitor manufactured by the same method, and a semiconductor memory device having the ferroelectric capacitor and a manufacturing method thereof. According to a method for manufacturing the material layer, a ferroelectric layer is formed. The ferroelectric layer may be exposed to seed plasma, and a material layer including a source material of the seed plasma may be formed on a region of the ferroelectric layer exposed to the seed plasma.

Abstract: Provided are methods for fabricating semiconductor devices incorporating a fin-FET structure that provides body-bias control, exhibits some characteristic advantages associated with SOI structures, provides increased operating current and/or reduced contact resistance. The methods for fabricating semiconductor devices include forming insulating spacers on the sidewalls of a protruding portion of a first insulation film; forming a second trench by removing exposed regions of the semiconductor substrate using the insulating spacers as an etch mask, and thus forming fins in contact with and supported by the first insulation film. After forming the fins, a third insulation film is formed to fill the second trench and support the fins. A portion of the first insulation film is then removed to open a space between the fins in which additional structures including gate dielectrics, gate electrodes and additional contact, insulating and storage node structures may be formed.

Abstract: Non-volatile memory devices highly integrated using an oxide based compound semiconductor and methods of operating and fabricating the same are provided. A non-volatile memory device may include one or more oxide based compound semiconductor layers. A plurality of auxiliary gate electrodes may be arranged to be insulated from the one or more oxide based compound semiconductor layers. A plurality of control gate electrodes may be positioned between adjacent pairs of the plurality of auxiliary gate electrodes at a different level from the plurality of auxiliary gate electrodes. The plurality of control gate electrodes may be insulated from the one or more oxide based compound semiconductor layers. A plurality of charge storing layers may be interposed between the one or more oxide based compound semiconductor layers and the plurality of control gate electrodes.

Abstract: Provided are a nonvolatile memory device and a method of fabricating the same in which a channel length is effectively increased and high-integration may be possible. In the nonvolatile memory device, a semiconductor device may include an active region defined by a device isolation film. The active region may include at least one projecting portion. A pair of control gate electrodes may cover both side surfaces of the at least one projecting portion, and may be spaced apart from each other. A pair of charge storage layers may be between both side surfaces of the at least one projecting portion and the pair of control gate electrodes.

Abstract: Example embodiment non-volatile memory devices may be capable of increased integration and reliability and may provide example methods of operating non-volatile memory devices. Example embodiment non-volatile memory devices may include a first control gate electrode on a semiconductor substrate. A first charge storing layer may be between the semiconductor substrate and the first control gate electrode. A source region may be defined in the semiconductor substrate at one side of the first control gate electrode. A first auxiliary gate electrode may be at the other side of the first control gate electrode and may be recessed into the semiconductor substrate. A first drain region may be defined in the semiconductor substrate at one side of the first auxiliary gate electrode opposite to the first control gate electrode. A bit line may be connected to the first drain region.

Abstract: Example embodiments relate to a semiconductor device including a fin-type channel region and a method of fabricating the same. The semiconductor device includes a semiconductor substrate, a semiconductor pillar and a contact plug. The semiconductor substrate includes at least one pair of fins used (or functioning) as an active region. The semiconductor pillar may be interposed between portions of the fins to connect the fins. The contact plug may be disposed (or formed) on the semiconductor pillar and electrically connected to top surfaces of the fins.

Abstract: A nonvolatile memory device having lower bit line contact resistance and a method of fabricating the same is provided. In the nonvolatile memory device, a semiconductor substrate of a first conductivity type may include first and second fins. A common bit line electrode may connect one end of the first fin to one end of the second fin. A plurality of control gate electrodes may cover the first and second fins and expand across the top surface of each of the first and second fins. A first string selection gate electrode may be positioned between the common bit line electrode and the plurality of control gate electrodes. The first string selection gate electrode may cover the first and second fins and expand across the top surface of each of the first and second fins. A second string selection gate electrode may be positioned between the first string selection gate electrode and the plurality of control gate electrodes.