Abstract: A silicon-oxide-nitride-oxide-silicon (SONOS) memory device includes a memory type transistor including a gate with a SONOS structure on a semiconductor substrate. The gate is formed by sequentially stacking a tunneling oxide layer, a memory node structure including a trap site having nano-sized trap elements in which charges passing through the tunneling oxide layer are trapped, and a gate electrode. The nano-sized trap elements may be a crystal layer composed of nanocrystals that are separated from one another to trap the charges. The memory node structure may include additional memory node layers which are isolated from the nano-sized trap elements.

Abstract: In a thin film semiconductor device realized on a flexible substrate, an electronic device using the same, and a manufacturing method thereof, the thin film semiconductor device and an electronic device include a flexible substrate, a semiconductor chip, which is formed on the flexible substrate, and a protective cap, which seals the semiconductor chip. Durability of the thin film semiconductor device against stress due to bending of the substrate is improved by using the protective cap.

Abstract: A SONOS memory device, and a method of erasing data from the same, includes injecting charge carriers of a second sign into a trapping film, which traps charge carriers of a first sign to store data therein. The charge carriers of the second sign are generated by an electric field formed between one of a first and second electrodes contacting at least one bit line and a gate electrode contacting a word line. A blocking film may be provided between the gate electrode and the trapping film. The charge carriers of the second sign may be hot holes. This erasing improves erasing speed, thereby improving performance of the SONOS memory device.

Abstract: A SONOS memory device, and a method of erasing data from the same, includes injecting charge carriers of a second sign into a trapping film, which traps charge carriers of a first sign to store data therein. The charge carriers of the second sign are generated by an electric field formed between one of a first and second electrodes contacting at least one bit line and a gate electrode contacting a word line. A blocking film may be provided between the gate electrode and the trapping film. The charge carriers of the second sign may be hot holes. This erasing improves erasing speed, thereby improving performance of the SONOS memory device.

Abstract: In a thin film semiconductor device realized on a flexible substrate, an electronic device using the same, and a manufacturing method thereof, the thin film semiconductor device and an electronic device include a flexible substrate, a semiconductor chip, which is formed on the flexible substrate, and a protective cap, which seals the semiconductor chip. Durability of the thin film semiconductor device against stress due to bending of the substrate is improved by using the protective cap.

Abstract: A single electron transistor having a memory function and a fabrication method thereof are disclosed. In the single electron transistor, a first substrate and an insulation film are sequentially stacked, a second substrate is stacked on the insulation film and includes a source region, a channel region, and a drain region, a tunneling film is formed on the second substrate, at least two trap layers are formed on the tunneling film and are separated by an interval such that at least one quantum dot may be formed in a same interval in the channel region, and a gate electrode is formed to contact the at least two trap layers and the tunneling film between the at least two trap layers. Because the single electron transistor is simple and includes a single gate electrode, a fabricating process and an operational circuit thereof may be simplified, and power consumption may be reduced.

Abstract: A single electron transistor having a memory function and a fabrication method thereof are disclosed. In the single electron transistor, a first substrate and an insulation film are sequentially stacked, a second substrate is stacked on the insulation film and includes a source region, a channel region, and a drain region, a tunneling film is formed on the second substrate, at least two trap layers are formed on the tunneling film and are separated by an interval such that at least one quantum dot may be formed in a same interval in the channel region, and a gate electrode is formed to contact the at least two trap layers and the tunneling film between the at least two trap layers. Because the single electron transistor is simple and includes a single gate electrode, a fabricating process and an operational circuit thereof may be simplified, and power consumption may be reduced.

Abstract: A multi-bit non-volatile memory device and methods of operating and fabricating the same may be provided. The memory device may include a channel region formed in a semiconductor substrate, and a source and drain that form a Schottky contact with the channel region. Also, a central gate electrode may be located on a portion of the channel region, and first and second sidewall gate electrodes may be formed on the channel region along the outer sides of the central gate electrode. First and second storage nodes may be formed between the channel region and the sidewall gate electrodes.

Abstract: Provided are a complementary nonvolatile memory device, methods of operating and manufacturing the same, a logic device and semiconductor device having the same, and a reading circuit for the same. The complementary nonvolatile memory device includes a first nonvolatile memory and a second nonvolatile memory which are sequentially stacked and have a complementary relationship. The first and second nonvolatile memories are arranged so that upper surfaces thereof are contiguous.

Abstract: Provided is a memory device formed using quantum devices and a method for manufacturing the same. A memory device comprises a substrate; a source region and a drain region formed in the substrate so as to be separated from each other by a predetermined interval; a memory cell which is formed on the surface of the substrate to connect the source region and the drain region, and has a plurality of nano-sized quantum dots filled with material for storing electrons; and a control gate which is formed on the memory cell and controls the number of electrons stored in the memory cell. It is possible to embody a highly efficient and highly integrated memory device by providing a memory device having nano-sized quantum dots and a method for manufacturing the same.

Abstract: Provided is a memory device formed using quantum devices and a method for manufacturing the same. A memory device comprises a substrate; a source region and a drain region formed in the substrate so as to be separated from each other by a predetermined interval; a memory cell which is formed on the surface of the substrate to connect the source region and the drain region, and has a plurality of nano-sized quantum dots filled with material for storing electrons; and a control gate which is formed on the memory cell and controls the number of electrons stored in the memory cell. It is possible to embody a highly efficient and highly integrated memory device by providing a memory device having nano-sized quantum dots and a method for manufacturing the same.

Abstract: In a method for manufacturing a single electron memory device including a single electron storage element in a gate lamination pattern formed on a nano-scale channel region of a MOSFET, formation of the gate lamination pattern includes sequentially forming a lower layer and a single electron storage medium for storing a single electron tunneling through the lower layer on a substrate, forming an upper layer including a plurality of quantum dots on the single electron storage medium, forming a gate electrode layer on the upper layer to be in contact with the plurality of quantum dots, and patterning the lower layer, the single electron storage medium, the upper layer, and the gate electrode layer, in reverse order.

Abstract: A nonvolatile silicon/oxide/nitride/silicon/nitride/oxide/silicon (SONSNOS) structure memory device includes a first insulating layer and a second insulating layer stacked on a channel of a substrate, a first dielectric layer and a second dielectric layer formed on the first insulating layer and under the second insulating layer, respectively, and a group IV semiconductor layer, silicon quantum dots, or metal quantum dots interposed between the first dielectric layer and the second dielectric layer. The provided SONSNOS structure memory device improves a programming rate and the capacity of the memory.

Abstract: A nonvolatile semiconductor memory device includes a semiconductor substrate having a source region and a drain region, and a gate stack formed on the semiconductor substrate between and in contact with the source and drain regions. The gate stack includes, in sequential order from the substrate: a tunneling film; a first trapping material film doped with a first predetermined impurity, the first trapping material film having a higher dielectric constant than the nitride film (Si3N4); a first insulating film having a higher dielectric constant than a nitride film; and a gate electrode. Such a nonvolatile semiconductor memory device can effectively control the trap density according to the doping concentration, thereby increasing the write/erase speed of data at a low operating voltage.

Abstract: A SONOS memory device, and a method of erasing data from the same, includes injecting charge carriers of a second sign into a trapping film, which traps charge carriers of a first sign to store data therein. The charge carriers of the second sign are generated by an electric field formed between one of a first and second electrodes contacting at least one bit line and a gate electrode contacting a word line. A blocking film may be provided between the gate electrode and the trapping film. The charge carriers of the second sign may be hot holes. This erasing improves erasing speed, thereby improving performance of the SONOS memory device.

Abstract: A SONOS memory device, and a method of manufacturing the same, includes a substrate and a multifunctional device formed on the substrate. The multifunctional device performs both switching and data storing functions. The multifunctional device includes first and second impurities areas, a channel formed between the first and second impurities areas, and a stacked material formed on the channel for data storage. The stacked material for data storage is formed by sequentially stacking a tunneling oxide layer, a memory node layer in which data is stored, a blocking layer, and an electrode layer.

Abstract: A silicon-oxide-nitride-oxide-silicon (SONOS) memory device includes a memory type transistor including a gate with a SONOS structure on a semiconductor substrate. The gate is formed by sequentially stacking a tunneling oxide layer, a memory node structure including a trap site having nano-sized trap elements in which charges passing through the tunneling oxide layer are trapped, and a gate electrode. The nano-sized trap elements may be a crystal layer composed of nanocrystals that are separated from one another to trap the charges. The memory node structure may include additional memory node layers which are isolated from the nano-sized trap elements.

Abstract: A single electron transistor having a memory function and a fabrication method thereof are disclosed. In the single electron transistor, a first substrate and an insulation film are sequentially stacked, a second substrate is stacked on the insulation film and includes a source region, a channel region, and a drain region, a tunneling film is formed on the second substrate, at least two trap layers are formed on the tunneling film and are separated by an interval such that at least one quantum dot may be formed in a same interval in the channel region, and a gate electrode is formed to contact the at least two trap layers and the tunneling film between the at least two trap layers. Because the single electron transistor is simple and includes a single gate electrode, a fabricating process and an operational circuit thereof may be simplified, and power consumption may be reduced.

Abstract: In a thin film semiconductor device realized on a flexible substrate, an electronic device using the same, and a manufacturing method thereof, the thin film semiconductor device and an electronic device include a flexible substrate, a semiconductor chip, which is formed on the flexible substrate, and a protective cap, which seals the semiconductor chip. Durability of the thin film semiconductor device against stress due to bending of the substrate is improved by using the protective cap.

Abstract: A nonvolatile silicon/oxide/nitride/silicon/nitride/oxide/silicon (SONSNOS) structure memory device includes a first insulating layer and a second insulating layer stacked on a channel of a substrate, a first dielectric layer and a second dielectric layer formed on the first insulating layer and under the second insulating layer, respectively, and a group IV semiconductor layer, silicon quantum dots, or metal quantum dots interposed between the first dielectric layer and the second dielectric layer. The provided SONSNOS structure memory device improves a programming rate and the capacity of the memory.