Abstract: The present invention relates to a method and device for distributing idle UE by a carrier in eNB of a multi-carrier based mobile communication system. The method of distributing idle UE in a multi-carrier based mobile communication system according to the present invention includes a process of determining a search rate by a carrier on the basis of information representing load on the carrier, a step of determining a cell reselection priority on the idle UE on the basis of the determined search rate, and a process of transmitting the determined cell reselection priority to the idle UE.

Abstract: A semiconductor device includes a first conductive structure and a second conductive structure. The first conductive structure is formed in a first region of a substrate, and includes a first polysilicon layer pattern, a first conductive layer pattern having a resistance smaller than that of the first polysilicon layer pattern, and a first hard mask. The second conductive structure is formed in a second region of the substrate and has a thickness substantially the same as that of the first conductive structure. The second conductive structure includes a second polysilicon layer pattern, a second conductive layer pattern having a resistance smaller than that of the second polysilicon layer pattern and having a thickness different from that of the first conductive layer pattern, and a second hard mask.

Abstract: A semiconductor device includes a first conductive structure and a second conductive structure. The first conductive structure is formed in a first region of a substrate, and includes a first polysilicon layer pattern, a first conductive layer pattern having a resistance smaller than that of the first polysilicon layer pattern, and a first hard mask. The second conductive structure is formed in a second region of the substrate and has a thickness substantially the same as that of the first conductive structure. The second conductive structure includes a second polysilicon layer pattern, a second conductive layer pattern having a resistance smaller than that of the second polysilicon layer pattern and having a thickness different from that of the first conductive layer pattern, and a second hard mask.

Abstract: A semiconductor device includes a first conductive structure and a second conductive structure. The first conductive structure is formed in a first region of a substrate, and includes a first polysilicon layer pattern, a first conductive layer pattern having a resistance smaller than that of the first polysilicon layer pattern, and a first hard mask. The second conductive structure is formed in a second region of the substrate and has a thickness substantially the same as that of the first conductive structure. The second conductive structure includes a second polysilicon layer pattern, a second conductive layer pattern having a resistance smaller than that of the second polysilicon layer pattern and having a thickness different from that of the first conductive layer pattern, and a second hard mask.

Abstract: A semiconductor device includes a first conductive structure and a second conductive structure. The first conductive structure is formed in a first region of a substrate, and includes a first polysilicon layer pattern, a first conductive layer pattern having a resistance smaller than that of the first polysilicon layer pattern, and a first hard mask. The second conductive structure is formed in a second region of the substrate and has a thickness substantially the same as that of the first conductive structure. The second conductive structure includes a second polysilicon layer pattern, a second conductive layer pattern having a resistance smaller than that of the second polysilicon layer pattern and having a thickness different from that of the first conductive layer pattern, and a second hard mask.

Abstract: For fabricating a field effect transistor, an extra-doped channel region is formed below a surface of a semiconductor substrate. An opening is formed in the semiconductor substrate into the extra-doped channel region. A gate insulator is formed at walls of the opening such that the extra-doped channel region abuts the gate insulator at a bottom portion of the opening. The opening is filled with a gate electrode. Such an extra-doped channel region prevents undesired body effect in the field effect transistor.

Abstract: The method of manufacturing a recess type MOS transistor improves a refresh characteristic. In the method, a channel impurity region is formed by ion implanting a first conductive impurity in an active region of a semiconductor substrate. Thereon, a second conductive impurity and the first conductive impurity are ion-implanted each alternately into the active region, to thus sequentially form first to third impurity regions having a dual diode structure on the channel impurity region, the second conductive impurity having conductivity opposite to the first conductive impurity. A trench is formed, and a gate insulation layer is formed in a gate region to produce a gate stack. The first conductive impurity is selectively ion-implanted in a source region, to thus form a fourth impurity region. A spacer is then formed in a sidewall of the gate stack, and the second conductive impurity is ion-implanted in the source/drain regions, to form a fifth impurity region.

Abstract: For fabricating a field effect transistor, an extra-doped channel region is formed below a surface of a semiconductor substrate. An opening is formed in the semiconductor substrate into the extra-doped channel region. A gate insulator is formed at walls of the opening such that the extra-doped channel region abuts the gate insulator at a bottom portion of the opening. The opening is filled with a gate electrode. Such an extra-doped channel region prevents undesired body effect in the field effect transistor.

Abstract: The method of manufacturing a recess type MOS transistor improves a refresh characteristic. In the method, a channel impurity region is formed by ion implanting a first conductive impurity in an active region of a semiconductor substrate. Thereon, a second conductive impurity and the first conductive impurity are ion-implanted each alternately into the active region, to thus sequentially form first to third impurity regions having a dual diode structure on the channel impurity region, the second conductive impurity having conductivity opposite to the first conductive impurity. A trench is formed, and a gate insulation layer is formed in a gate region to produce a gate stack. The first conductive impurity is selectively ion-implanted in a source region, to thus form a fourth impurity region. A spacer is then formed in a sidewall of the gate stack, and the second conductive impurity is ion-implanted in the source/drain regions, to form a fifth impurity region.

Abstract: For fabricating a field effect transistor, an extra-doped channel region is formed below a surface of a semiconductor substrate. An opening is formed in the semiconductor substrate into the extra-doped channel region. A gate insulator is formed at walls of the opening such that the extra-doped channel region abuts the gate insulator at a bottom portion of the opening. The opening is filled with a gate electrode. Such an extra-doped channel region prevents undesired body effect in the field effect transistor.