Abstract: A semiconductor memory device and a method of manufacturing the same improves an efficiency of injection of channel hot electrons while suppressing injection of drain avalanche hot carriers. In the semiconductor memory device, a first nitrided oxide film (RNO film) containing a first content of hydrogen is formed at a drain avalanche hot carrier injection region. Thereby, injection of drain avalanche hot carriers is effectively suppressed during a data writing operation. A second nitrided oxide film (NO film) containing a second content of hydrogen larger than the first content is formed at a channel hot electron injection region. Thereby, an efficiency of injection of channel hot electrons is improved during the data writing operation.

Abstract: An MIS transistor manufacturing method which can prevent unwanted diffusion of extensions caused by the drive to the source/drain so that the diffusion of the source/drain and the diffusion of the extensions can independently be controlled so as to obtain optimum structure for each. Source/drain are formed by ion implantation using, as a mask, L-shaped silicon nitride films formed on sides of a gate electrode and silicon oxide films covering the silicon nitride films. The silicon oxide films are then removed leaving the silicon nitride films. Impurity ions are then ion-implanted into the main surface of the silicon substrate through the silicon nitride films. Since the silicon nitride films are thicker in the vicinity of the gate electrode and thinner in the vicinity of the source/drain, this process forms extensions penetrating under the gate electrode for a small distance.

Abstract: Obtained are a semiconductor device which can prevent diffusion of an impurity contained in a gate electrode and a method of fabricating the same. In this semiconductor device, a gate oxide film and a P+-type gate electrode which are formed on a P-type silicon substrate are doped with nitrogen.

Abstract: This invention provides a MIS transistor with less electrical short between a gate and source/drain electrodes. A sidewall spacer 15 has a two-layer structure including a buffer layer 13 which consists of nitrided oxide silicon and a silicon nitrided layer 14 formed on the buffer layer 13. The sidewall spacer 15 serves as a mask to form a silicide film 10.

Abstract: This invention provides a MIS transistor with less electrical short between a gate and source/drain electrodes. A sidewall spacer 15 has a two-layer structure including a buffer layer 13 which consists of nitrided oxide silicon and a silicon nitrided layer 14 formed on the buffer layer 13. The sidewall spacer 15 serves as a mask to form a silicide film 10.

Abstract: A method of manufacturing a MISFET includes the steps of forming a gate insulation film (2) on a semiconductor substrate (1), forming a dummy gate (3B) made of a material having an etch selectivity relative to the material of the gate insulation film (2) on the gate insulation film (2), implanting an impurity into the semiconductor substrate (1), forming an interlayer insulation film (7), made of a material having an etch selectivity relative to the material of the dummy gate (3B) on a side surface of the dummy gate (3B), etching away the dummy gate (3B), and filling a space in which the dummy gate (3B) has been present with a gate electrode material of metal. Gradually thinning the dummy gate in the step of impurity implantation allows the formation of LDD regions and the patterning of a gate electrode below a minimum patterning size limit of a photolithographic technique.

Abstract: A gate electrode is made up of a polycrystalline silicon film containing phosphorous as a dopant for determining its conductivity type, a titanium silicide film of the C54 structure, and a tungsten silicide film all of which films are laid one on another in said order. A method of manufacturing a semiconductor device of the present invention involves sequentially forming a non-single-crystal silicon film containing a dopant for determining a conductivity type of the non-single-crystal silicon film, a titanium film, and a metal silicide film on a substrate. A titanium silicide film of a C49 and/or C54 structure is formed by performing a heat treatment so as to cause the titanium film to react with the non-single-crystal silicon film while reducing a first native oxide film formed in a first interface between the titanium film and the non-single-silicon film and a second native oxide film formed in a second interface between the titanium film and the metal silicide film.

Abstract: A high withstand voltage semiconductor device includes a semiconductor substrate of a first conductivity type, a metallic wiring formed on a surface of the semiconductor substrate and having a contact face with said semiconductor substrate, a highly doped impurity region formed within the semiconductor substrate below the contact face and of a second conductivity type, a lightly doped impurity region formed around the highly doped impurity region and of the second conductivity type, and a MOSFET with a second conductivity-type having a source or drain region formed on the surface of the semiconductor substrate and electrically connected to the metallic wiring through the impurity regions.

Abstract: A boron diffusion region is formed at a surface of a silicon substrate. A pair of n-type source/drain regions are formed at a surface of boron diffusion region. A gate electrode is formed at a region located between paired source/drain regions with a gate insulating film therebetween. A nitrogen implanted region is formed at the surface of silicon substrate located between paired n-type source/drain regions. Nitrogen implanted region has a peak nitrogen concentration at a position of a depth not exceeding 500 .ANG. from the surface of silicon substrate. Thereby, a transistor structure which can be easily miniaturized can be obtained.

Abstract: A silicided region (11a) is formed in part of a surface of a gate electrode (3a) which is far from a storage node when a diffusion region (7a) is connected to a bit line and a diffusion region (8a) is connected to the storage node. A silicided region (12a) is formed in a surface of the diffusion region (7a) connected to the bit line. A MOSFET which suppresses a leakage current from the storage node to the gate electrode and decreases the resistance of the diffusion region connected to the bit line and the resistance of said gate electrode is provided.

Abstract: A surface of a conductive member such as a gate electrode provided with a silicon layer is roughened. The roughened silicon layer is silicified so that its width is substantially increased, whereby phase transition of the silicide layer is simplified. Thus, the resistance of the refined silicide layer is reduced due to the simplified phase transition.

Abstract: A surface of a conductive member such as a gate electrode provided with a silicon layer is roughened. The roughened silicon layer is silicified so that its width is substantially increased, whereby phase transition of the silicide layer is simplified. Thus, the resistance of the refined silicide layer is reduced due to the simplified phase transition.

Abstract: A dummy cell part <31> includes a capacitor <311> having a first end which is connected to one of a plurality of pads <2> and a P-N junction element <312> having a first end which is connected to one of the plurality of pads <2> and a second end which is connected to one of the plurality of pads <2>. A sense part <32> is connected to a second end of the capacitor <311>, for sensing a potential on the second end of the capacitor <311> and outputting the result of sensing to one of the plurality of pads <2>. Thus, a memory cell evaluation semiconductor device which can evaluate a single memory cell, a method of fabricating the same and a memory cell evaluation method are obtained.

Abstract: To form a silicide layer excellent in flatness, uniform in film thickness, and less in junction leak, by destroying the natural oxide film which adversely affects a formation of silicide layer of cobalt or nickel. A cobalt layer (7) is formed in a film thickness of 20 nm or less on an electrode layer (4A) of a gate electrode (4) and on source/drain diffusion layers (1, 2), and a nitrogen (8) is injected by the ion implantation at a density of about 1E15/cm.sup.3 with an injection energy of 10 keV or more. At this time, the nitrogens (8) destroy the natural oxide film existing in the interface of the cobalt layer (7) and electrode layer (4A), and in the interface of the cobalt layer (7) and the source/drain diffusion layers (1, 2), and distribute deeply into the electrode layer (4A) and the source/drain diffusion layers (1, 2). Later, by a silicide forming reaction of cobalt, a silicide layer (6) is formed. Since the natural oxide film does not exist, the silicide forming reaction proceeds uniformly.

Abstract: A high withstand voltage semiconductor device includes a semiconductor substrate of a first conductivity type, a metallic wiring formed on a surface of the semiconductor substrate and having a contact face with said semiconductor substrate, a highly doped impurity region formed within the semiconductor substrate below the contact face and of a second conductivity type, a lightly doped impurity region formed around the highly doped impurity region and of the second conductivity type, and a MOSFET with a second conductivity-type having a source or drain region formed on the surface of the semiconductor substrate and electrically connected to the metallic wiring through the impurity regions.

Abstract: In order to obtain a semiconductor device having an internal wire of low resistance, a conductive layer whose surface is silicified is provided in a surface of a semiconductor substrate. A conductor whose surface is silicified is provided on the semiconductor substrate in proximity to the conductive layer. This semiconductor device is provided with an internal wiring layer, which is formed by a titanium film and a titanium silicide layer for electrically connecting the surface of the conductive layer and a surface of an end of the conductor with each other, to cover a side wall surface and a bottom surface of a contact hole.

Abstract: A gate electrode is made up of a polycrystalline silicon film containing phosphorous as a dopant for determining its conductivity type, a titanium silicide film of the C54 structure, and a tungsten silicide film all of which films are laid one on another in said order.

Abstract: To form a silicide layer excellent in flatness, uniform in film thickness, and less in junction leak, by destroying the natural oxide film which adversely affects a formation of silicide layer of cobalt or nickel. A cobalt layer (7) is formed in a film thickness of 20 nm or less on an electrode layer (4A) of a gate electrode (4) and on source/drain diffusion layers (1, 2), and a nitrogen (8) is injected by the ion implantation at a density of about 1E15/cm.sup.3 with an injection energy of 10 keV or more. At this time, the nitrogens (8) destroy the natural oxide film existing in the interface of the cobalt layer (7) and electrode layer (4A), and in the interface of the cobalt layer (7) and the source/drain diffusion layers (1, 2), and distribute deeply into the electrode layer (4A) and the source/drain diffusion layers (1, 2). Later, by a silicide forming reaction of cobalt, a silicide layer (6) is formed. Since the natural oxide film does not exist, the silicide forming reaction proceeds uniformly.

Abstract: A boron diffusion region is formed at a surface of a silicon substrate. A pair of n-type source/drain regions are formed at a surface of boron diffusion region. A gate electrode is formed at a region located between paired source/drain regions with a gate insulating film therebetween. A nitrogen implanted region is formed at the surface of silicon substrate located between paired n-type source/drain regions. Nitrogen implanted region has a peak nitrogen concentration at a position of a depth not exceeding 500 .ANG. from the surface of silicon substrate. Thereby, a transistor structure which can be easily miniaturized can be obtained.

Abstract: In order to obtain a semiconductor device having an internal wire of low resistance, a conductive layer whose surface is silicified is provided in a surface of a semiconductor substrate. A conductor whose surface is silicified is provided on the semiconductor substrate in proximity to the conductive layer. This semiconductor device is provided with an internal wiring layer, which is formed by a titanium film and a titanium silicide layer for electrically connecting the surface of the conductive layer and a surface of an end of the conductor with each other, to cover a side wall surface and a bottom surface of a contact hole.