Abstract: The MOSFET fabrication method allows application of a self-aligned contact (SAC) process while maintaining a metal gate, such as a tungsten gate, to have a uniform thickness. The process involves forming a metal oxide film during the formation of a metal gate structure of the MOSFET device. The metal oxide film is formed by subjecting the gate structure through a rapid thermal oxidation (RTO) treatment and then to an N2O plasma treatment. The treatments allow the thickness of the metal oxide to be precisely controlled. The metal oxide acts as an insulator, which prevents electrical shorts between the gate structure and a contact plug even if a misalignment of occurs during the SAC process. This is an improvement from the conventional practice of separately forming a SAC barrier film after the formation of the metal gate structure and thus saves money, time, and increases reliability and productivity. Also the performance characteristics of the device is enhanced.

Abstract: A method of forming a gate electrode in semiconductor device which can prevent transformation of the gate electrode, is disclosed. According to the present invention, a gate insulating layer, a doped polysilicon layer and a sacrificial layer are formed on a semiconductor substrate, sequentially. The sacrificial layer and the polysilicon layer are then etched in the shape of a gate electrode to form a sacrificial pattern and a polysilicon pattern. Next, the substrate is re-oxidized to form a re-oxidation layer on the side walls of the polysilicon pattern and LDD ions are implanted into the substrate of both sides of the re-oxidation layer. A spacer of an insulating layer is then formed on the side walls of the sacrificial pattern and the re-oxidation layer and impurity ions of a high concentration are implanted into the substrate of both sides of the spacer. Thereafter, an intermediate insulating layer is formed on the overall substrate and etched to expose the surface of the sacrificial pattern.

Abstract: A method of forming a gate electrode in a semiconductor device which can effectively prevent abnormal oxidation of a metal layer without occurring thermal budget and the deterioration of a gate insulating layer during gate re-oxidation process, is disclosed. In the present invention, one selected from a group consisting of an iridium(Ir) layer, a ruthenium(Ru) layer and an osmium(Os) layer capable of forming a nonvolatile conductive metal oxide layer, is used as a metal layer of a gate electrode instead of a W layer in conventional art. Therefore, although a gate re-oxidation process is performed by a well known method, it is effectively prevented that the metal layer is abnormally oxidized, thereby forming an uniform oxide layer on the side wall of the gate. Furthermore, since the oxide layer is conductive, the resistivity of the gate electrode is reduced.

Abstract: There is disclosed a method of manufacturing a semiconductor device capable of solving the problems that a conventional method could not secure a sufficient beam current upon ion injection when forming a junction region at shallow thickness as the integration level of'devices becomes higher, and also it causes a short channel effect etc. The method includes forming a junction region, forming a selective epitaxial growth layer and then forming a LDD region, using a facet phenomenon occurring at the edge portion of the gate electrode when forming an elevated junction structure by use of a selective epitaxial growth method. Thus, it can obtain a junction region having a very shallow depth, accomplish a higher integration level of devices and prohibit a short channel effect.

Abstract: A SOI device, comprising: a SOI wafer having a stack structure of a silicon substrate, a buried oxide layer having a first and a second contact holes and a silicon layer; an isolation layer formed in the silicon layer to define a device formation region; a transistor including a gate formed over the device formation region of the silicon layer defined by the isolation layer, source and drain regions formed at the both side of the gate in the device formation region, and a channel region which is a portion of the device formation region between the source and drain region; a conduction layer being contacted with the buried oxide layer; an impurity region for well pick-up formed in the silicon layer to be contacted with the buried oxide layer; a first contact layer formed within the first contact hole of the buried oxide layer to electrically connect the channel region of the transistor and the conduction layer; and a second contact layer formed with the second contact hole of the buried oxide layer to electri

Abstract: A method for forming an element isolation film of a semiconductor device and the semiconductor device. A pad insulator is constructed on a semiconductor substrate. An over-etching process is performed to recess the semiconductor substrate to a predetermined depth while giving a pad insulator pattern. After an insulator spacer is formed at the side wall of the pad insulator pattern, the exposed region of the semiconductor substrate is thermally oxidized to grow an oxide which is, then, removed to form a recess. An element isolation film is formed in the recess by break-through field oxidation and high temperature field oxidation. The element isolation film thus obtained can prevent the field oxide “ungrowth” phenomenon and at the same time mitigate the field oxide thinning effect as well as improve the properties of the gate oxide.

Abstract: The present invention relates to a method of manufacturing a junction in a semiconductor device. When forming an elevated source/drain junction (ESD) of a buried channel field effect transistor (BC-FET) using a selective epitaxial growth (SEG) technique, a self-aligned epitaxial silicon (SESS) is formed on the lower portion of a gate side-wall spacer, resulting in the improvement of a short channel characteristic by suppressing a facet occurred when forming an elevated source/drain junction (EDS) of the buried channel field effect transistors (BC-FETs) using a selective epitaxial growth (SEG) technique as well as the increase of the current density by lowering the series resistance of source/drain extension.

Abstract: A method for manufacturing a shallow trench isolation in a semiconductor device, the method including the steps of forming a trench mask patterned layer on a semiconductor substrate, forming a narrow trench and a wide trench by etching an exposed substrate, forming a second insulating layer on the entire surface including the trenches and the trench mask patterned layer whereby the narrow trench is completely filled and the wide trench is partially filled, and forming a third insulating layer on the first insulating layer, whereby the wide trench is filled completely.

Abstract: A method of forming a gate electrode with a titanium polycide structure which can prevent abnormal oxidation of the gate electrode and reduce the resistivity of the gate electrode when performing a re-oxidation process, is disclosed. According to the present invention, a gate oxide layer, a polysilicon layer and a titanium silicide layer are formed on a semiconductor substrate, in sequence. A mask insulating layer is then formed in the shape of a gate electrode on the titanium silicide layer and the titanium silicide layer and the polysilicon layer are etched using the mask insulating layer to form a gate electrode. Thereafter, the substrate is oxidized using re-oxidation process to form an oxide layer with a uniform thickness on the side wall of the gate electrode and on the surface of the substrate. Here, the re-oxidation process is performed at the temperature of 750° C. or less using dry oxidation. Furthermore, the re-oxidation process is performed at the temperature of 700 to 750° C.

Abstract: Disclosed herein is a method of forming a gate in a semiconductor device capable of preventing a deterioration in the property of a gate electrode formed of a refractory metal in a heat treatment process.

Abstract: A SOI device, comprising: a SOI wafer having a stack structure of a silicon substrate, a buried oxide layer having a first and a second contact holes and a silicon layer; an isolation layer formed in the silicon layer to define a device formation region; a transistor including a gate formed over the device formation region of the silicon layer defined by the isolation layer, source and drain regions formed at the both side of the gate in the device formation region, and a channel region which is a portion of the device formation region between the source and drain region; a conduction layer being contacted with the buried oxide layer; an impurity region for well pick-up formed in the silicon layer to be contacted with the buried oxide layer; a first contact layer formed within the first contact hole of the buried oxide layer to electrically connect the channel region of the transistor and the conduction layer; and a second contact layer formed with the second contact hole of the buried oxide layer to electri

Abstract: A method of forming a gate electrode in a semiconductor device which can easily perform etching process for forming the gate electrode and reduce the resistivity of a gate electrode, is disclosed. In the present invention, a gate oxide layer, an amorphous silicon layer and a tungsten silicide layer are sequentially formed on a semiconductor substrate. A mask oxide pattern is then formed on the tungsten silicide layer in the shape of a gate electrode. Next, the tungsten silicide layer and the amorphous silicon layer are etched using the mask oxide pattern as an etch mask, to form a gate electrode. Thereafter, the amorphous silicon layer and the tungsten silicide layer of the gate electrode are thermal-treated by RTP spike annealing and an oxide layer is then formed on the side wall of the gate electrode.

Abstract: A method for forming a field oxide of a semiconductor device and the semiconductor device. In order to form the field oxide, first, an element isolation mask is constructed on a semiconductor substrate. Then, a nitride spacer is formed at the side wall of the mask. At this time, a nitrogen-containing polymer is produced on the field region. The exposed region of the semiconductor substrate is oxidized at a temperature of 1,050-1,200.degree. C. to grow a recess-oxide while transforming the nitrogen-containing polymer into a nitride. Thereafter, the recess oxide is removed, together with the nitride, to create a trench in which the field oxide is formed through thermal oxidation. Therefore, the method can prevent an FOU phenomenon upon the growth of a field oxide and improve the field oxide thinning effect, thereby bringing a significant improvement to the production yield and the reliability of a semiconductor device.