Abstract: A multi-value single electron memory using a multi-quantum dot, in which the floating gates (FG) of a EEPROM or a flash memory are formed to act as two quantum dots, and the two quantum dots are applied to multi-value memories, and a driving method of the multi-value single electron memory, are provided. Thus, a multi-value memory can be realized using two quantum dots. Also, an ultra-highly integrated memory of 1 Tb or greater can be realized without encountering a physical limit such as a short channel effect (SCE) caused by scaling down MOSFETs, in contrast to other memories.

Abstract: A single electron memory device including quantum dots between a gate electrode and a single electron storage element and a method for manufacturing the same, wherein the single electron memory device includes a substrate on which a nano-scale channel region is formed between a source and a drain, and a gate lamination pattern including quantum dots on the channel region. The gate lamination pattern includes a lower layer formed on the channel region, a single electron storage medium storing a single electron tunneling through the lower layer formed on the lower layer, an upper layer including quantum dots formed on the single electron storage medium, and a gate electrode formed on the upper layer to be in contact with the quantum dots.

Abstract: A single electron transistor using porous silicon, which is fabricated by applying porous silicon having a size of several tens of nanometers obtained by electrochemically etching silicon, and a fabrication method thereof, are provided. In the single electron transistor using porous silicon, silicon pores, each of which has a diameter of 5 nm or less, are fabricated by electrochemically etching a silicon on insulator (SOI) substrate having silicon dioxide (SiO2) in its lower portion using an HF-based solution, and serve as islands of a single electron transistor. Also, a source and a drain are formed of silicon on which metal is deposited or silicon doped with impurities. Hence, formation of islands and tunnel barriers is easy, mass production is possible, and the sizes of islands can be controlled by oxidation, so that single electron transistors capable of operating at room temperature can be easily fabricated.

Abstract: A single electron transistor using porous silicon, which is fabricated by applying porous silicon having a size of several tens of nanometers obtained by electrochemically etching silicon, and a fabrication method thereof, are provided. In the single electron transistor using porous silicon, silicon pores, each of which has a diameter of 5 nm or less, are fabricated by electrochemically etching a silicon on insulator (SOI) substrate having silicon dioxide (SiO2) in its lower portion using an HF-based solution, and serve as islands of a single electron transistor. Also, a source and a drain are formed of silicon on which metal is deposited or silicon doped with impurities. Hence, formation of islands and tunnel barriers is easy, mass production is possible, and the sizes of islands can be controlled by oxidation, so that single electron transistors capable of operating at room temperature can be easily fabricated.

Abstract: A single electron transistor using porous silicon, which is fabricated by applying porous silicon having a size of several tens of nanometers obtained by electrochemically etching silicon, and a fabrication method thereof, are provided. In the single electron transistor using porous silicon, silicon pores, each of which has a diameter of 5 nm or less, are fabricated by electrochemically etching a silicon on insulator (SOI) substrate having silicon dioxide (SiO2) in its lower portion using an HF-based solution, and serve as islands of a single electron transistor. Also, a source and a drain are formed of silicon on which metal is deposited or silicon doped with impurities. Hence, formation of islands and tunnel barriers is easy, mass production is possible, and the sizes of islands can be controlled by oxidation, so that single electron transistors capable of operating at room temperature can be easily fabricated.

Abstract: A metal nitride oxide semiconductor (MNOS) type memory using a threshold voltage variation (&Dgr;Vth) due to charging of a single electron when the width of a channel of the memory is set to be smaller than or equal to the Debye screen length (LD) of an electron, and a driving method thereof, are provided. The MNOS memory uses a threshold voltage variation (&Dgr;Vth) due to charging of a single electron occurring when the width of a channel is set to be smaller than or equal to the Debye screen length (LD) which depends on the impurity concentration of a semiconductor substrate.