Abstract: A semiconductor device adopting an interlayer contact structure between upper and lower conductive layers and a method of manufacturing the semiconductor device adopting the structure are provided. The lower conductive layer includes a first conductive layer and a first silicide layer stacked together. The upper conductive layer includes a second conductive layer doped with impurities and a second silicide layer stacked together. In the interlayer contact structure, the first and second conductive layers are in direct contact with each other. This decreases the contact resistance between the two conductive layers and improves the electrical properties of the device.

Abstract: A method of forming a CMOS type semiconductor device having dual gate includes forming a first gate insulation layer and a first metal-containing layer sequentially on a surface of a substrate in first and second impurity type transistor regions, removing the first metal-containing layer and the first gate insulation layer in the second impurity type transistor region, forming a second gate insulation layer and a second metal-containing layer in the second impurity type transistor region, and forming first and second electrodes in the first and second impurity type transistor regions, respectively, by patterning the first and second metal-containing layers.

Abstract: A semiconductor device having a transistor of gate all around (GAA) type and a method of fabricating the same are disclosed. A SOI substrate composed of a SOI layer, a buried oxide layer and a lower substrate is prepared. The SOI layer has at least one unit dual layer of a silicon germanium layer and a silicon layer. The SOI layer is patterned to form an active layer pattern to a certain direction. An insulation layer is formed to cover the active layer pattern. An etch stop layer is stacked on the active layer pattern covered with the insulation layer. The etch stop layer is patterned and removed at a gate region crossing the active layer pattern at the channel region. The insulation layer is removed at the gate region. The silicon germanium layer is isotropically etched and selectively removed to form a cavity at the channel region of the active layer pattern.

Abstract: The present invention provides a highly reliable polycrystal silicon thin film transistor with N2O plasma oxide having an excellent leakage current characteristics comparable to the thermal oxide film formed on the crystalline silicon. Also, the present invention provides a method of fabricating EEPROM or flash memory using N2O plasma oxide as a tunnel oxide, and N2O plasma oxide film as an interpoly dielectric between the floating gate and the control gate.

Abstract: A method of forming a SOI type semiconductor device comprises forming a first trench in a SOI layer forming a portion of an isolation layer region between an element region and a ground region by etching the SOI layer of a SOI type substrate using an etch stop layer pattern as an etch mask, forming an impurity layer in or on a bottom surface of the first trench, forming a second trench exposing a buried oxide layer in the SOI layer in the remainder of the isolation layer region except the portion thereof between the element region and the ground region, and forming an isolation layer by depositing an insulation layer over the SOI substrate having the first and second trenches. The impurity layer can be formed by depositing a SiGe single crystal layer in the bottom surface of the first trench. Also, the impurity layer can be formed by implanting ions in the bottom surface of the first trench.

Abstract: In a CMOS semiconductor device having a substrate, a gate insulating layer formed on the substrate, at least one first polysilicon gate formed over the substrate in at least one PMOS transistor region, and at least one second polysilicon gate formed over the substrate in at least one NMOS transistor region, a total amount of Ge in the first polysilicon gate is the same as that in the second polysilicon gate, a distribution of Ge concentration in the first and/or second polysilicon gate is different according to a distance from the gate insulating layer, and Ge concentration in a portion of the first polysilicon gate adjacent to the gate insulating layer is higher than that in the second polysilicon gate. The Ge concentration in the portion of the first polysilicon gate adjacent to the gate insulating layer is more than two times as high as that in the second polysilicon gate.

Abstract: A multi-layer dielectric layer structure for a semiconductor device. The multi-layer dielectric layer structure comprises a silicate interface layer having a dielectric constant greater than that of silicon nitride and a high-k dielectric layer overlying the silicate interface layer. The high-k dielectric layer comprises one or more ordered pairs of first and second layers. With the present invention, the dielectric constant of the high-k dielectric layer can be optimized while improving interface characteristics. With a higher crystallization temperature realized by forming the multi-layer structure, each of whose layers is not more than the critical thickness, leakage current can be reduced, thereby improving device performance.

Abstract: A method of fabricating a trench isolation structure in a high-density semiconductor device that provides an isolation characteristic that is independent of the properties of adjacent MOS transistor devices, wherein a first trench in a first isolation area and a second trench implanted are formed on a semiconductor substrate, a nitrogen (N)-rich silicon layer is formed on the sidewall in a second isolation area, a subsequent oxidation process may be employed to fabricate oxide layers, each having a different thickness, on the sidewall surfaces of the first and second trenches. When the first and second oxide-layered trenches are filled with a stress relief liner and a dielectric material, the different thicknesses of the oxides prevent leakage currents from flowing to an adjacent semiconductor device, regardless of the doping properties of each device.

Abstract: A semiconductor device adopting an interlayer contact structure between upper and lower conductive layers and a method of manufacturing the semiconductor device adopting the structure are provided. The lower conductive layer includes a first conductive layer and a first silicide layer stacked together. The upper conductive layer includes a second conductive layer doped with impurities and a second silicide layer stacked together. In the interlayer contact structure, the first and second conductive layers are in direct contact with each other. This decreases the contact resistance between the two conductive layers and improves the electrical properties of the device.

Abstract: A semiconductor device adopting an interlayer contact structure between upper and lower conductive layers and a method of manufacturing the semiconductor device adopting the structure are provided. The lower conductive layer includes a first conductive layer and a first silicide layer stacked together. The upper conductive layer includes a second conductive layer doped with impurities and a second silicide layer stacked together. In the interlayer contact structure, the first and second conductive layers are in direct contact with each other. This decreases the contact resistance between the two conductive layers and improves the electrical properties of the device.

Abstract: A gate electrode in a semiconductor device comprising; a gate oxide layer formed on a semiconductor substrate, a polysilicon layer formed on the gate oxide layer, a silicide layer formed on the polysilicon layer and, a metal silicide layer formed on the silicide layer.

Abstract: A method for efficiently removing by-products produced in dry-etching a fabricated structure of a semiconductor device, particularly, a polycide structure. The method includes the steps of sequentially forming a polysilicon layer and a refractory metal silicide layer to overlie previously fabricated structures on a semiconductor substrate, dry-etching the polysilicon layer and the refractory metal silicide layer to form a patterned polysilicon layer and a patterned refractory metal silicide layer, and thermal treating the resultant structure to remove at least one kind of by-product produced in the dry-etching step at a temperature higher than the boiling point of any by-product.