Abstract: A nonvolatile semiconductor memory device includes a tunnel insulating film, a floating gate electrode, an inter-electrode insulating film, and a control gate electrode. The tunnel insulating film is formed on a selected part of a surface of a semiconductor substrate. The floating gate electrode is formed on the tunnel insulating film. At least that interface region of the floating gate electrode, which is opposite to the substrate, is made of n-type Si or metal-based conductive material. The inter-electrode insulating film is formed on the floating gate electrode and made of high-permittivity material. The control gate electrode is formed on the inter-electrode insulating film. At least that interface region of the control gate electrode, which is on the side of the inter-electrode insulating film, is made of a p-type semiconductor layer containing at least one of Si and Ge.

Abstract: A complementary semiconductor device includes a semiconductor substrate, a first semiconductor region formed on a surface of the semiconductor substrate, a second semiconductor region formed on the surface of the semiconductor substrate apart from the first semiconductor region, an n-MIS transistor having a first gate insulating film including La and Al, formed on the first semiconductor region, and a first gate electrode formed on the gate insulating film, and a p-MIS transistor having a second gate insulating film including La and Al, formed on the second semiconductor region, and a second gate electrode formed on the gate insulating film, an atomic density ratio Al/La in the second gate insulating film being larger than an atomic density ratio Al/La in the first gate insulating film.

Abstract: According to an aspect of the invention, a nonvolatile semiconductor memory device includes: a semiconductor layer comprising an n-type semiconductor region; p-type source-drain regions separated from each other within the n-type semiconductor region; a charge storage layer provided on the semiconductor layer and between the p-type source-drain regions, the charge storage layer comprising a high dielectric constant material; and a control gate electrode provided on the charge storage layer and comprising a material selected from n-type Si, a metal-based conductive material, and a p-type semiconductor material including at least one of Si and Ge.

Abstract: A nonvolatile semiconductor memory device includes a tunnel insulating film, a floating gate electrode, an inter-electrode insulating film, and a control gate electrode. The tunnel insulating film is formed on a selected part of a surface of a semiconductor substrate. The floating gate electrode is formed on the tunnel insulating film. At least that interface region of the floating gate electrode, which is opposite to the substrate, is made of n-type Si or metal-based conductive material. The inter-electrode insulating film is formed on the floating gate electrode and made of high-permittivity material. The control gate electrode is formed on the inter-electrode insulating film. At least that interface region of the control gate electrode, which is on the side of the inter-electrode insulating film, is made of a p-type semiconductor layer containing at least one of Si and Ge.

Abstract: It is made possible to form a silicon nitride film, an aluminum oxide film and a transition metal high-k insulation film of high quality. A manufacturing method includes: forming an insulation film having at least one kind of bonds selected out of silicon-nitrogen bonds, aluminum-oxygen bonds, transition metal-oxygen-silicon bonds, transition metal-oxygen-aluminum bonds, and transition metal-oxygen bonds on either a film having a semiconductor as a main component or a semiconductor substrate, and irradiating the insulation film with pulse infrared light having a wavelength corresponding to a maximum intensity in a wavelength region depending upon the insulation film and having a wavelength absorbed by the insulation film.

Abstract: A MIS-type semiconductor device is configured with a semiconductor substrate, and a p-type MIS transistor, and a n-type MIS transistor which is provided on the semiconductor substrate, the p-type MIS transistor including a gate electrode which is made of Ge and one element which is selected from the group consisting of Ta, V and Nb.

Abstract: After a barrier film is formed on a pad electrode, Ni particles having a diameter of 2 ?m or less are selectively deposited on the barrier film, thereby forming a Ni fine particle film. Then, a bump electrode made of a solder ball is provided on the pad electrode through the Ni fine particle film. Thereafter, the bump electrode is melted by a heat treatment to join the Ni fine particle film to the bump electrode. Thus, a bump electrode structure is finished.

Abstract: After a barrier film is formed on a pad electrode, Ni particles having a diameter of 2 ?m or less are selectively deposited on the barrier film, thereby forming a Ni fine particle film. Then, a bump electrode made of a solder ball is provided on the pad electrode through the Ni fine particle film. Thereafter, the bump electrode is melted by a heat treatment to join the Ni fine particle film to the bump electrode. Thus, a bump electrode structure is finished.

Abstract: After a barrier film is formed on a pad electrode, Ni particles having a diameter of 2 &mgr;m or less are selectively deposited on the barrier film, thereby forming a Ni fine particle film. Then, a bump electrode made of a solder ball is provided on the pad electrode through the Ni fine particle film. Thereafter, the bump electrode is melted by a heat treatment to join the Ni fine particle film to the bump electrode. Thus, a bump electrode structure is finished.

Abstract: After a barrier film is formed on a pad electrode, Ni particles having a diameter of 2 &mgr;m or less are selectively deposited on the barrier film, thereby forming a Ni fine particle film. Then, a bump electrode made of a solder ball is provided on the pad electrode through the Ni fine particle film. Thereafter, the bump electrode is melted by a heat treatment to join the Ni fine particle film to the bump electrode. Thus, a bump electrode structure is finished.

Abstract: A method of manufacturing a semiconductor device including the steps of forming an insulating film on a silicon region of a substrate having the silicon region on a surface the insulating film having an opening for forming an exposed region of the silicon region, supplying a gas containing a halogen onto the silicon region, and supplying a source gas of silicon onto the silicon region, thereby selectively depositing the silicon on the exposed region of the silicon region.

Abstract: A semiconductor device manufacturing method includes the step of forming a silicon oxide film on the surface of a silicon region, and the step of supplying anhydrous hydrofluoric acid gas to the silicon oxide film, thereby removing the silicon oxide film. The total concentration of Si--H bonds, Si--O--H bonds, and H.sub.2 O molecules, in the silicon oxide film is 1.times.10.sup.13 /cm.sup.2 or more.

Abstract: Disclosed is a method of manufacturing a semiconductor device, comprising the step of detachably mounting a plurality of semiconductor substrates to a first holder board so as to form a complex semiconductor substrate, and the step of subjecting the plural semiconductor substrates included in the complex semiconductor substrates to common steps of manufacturing a semiconductor device. At least one of the plural semiconductor substrates is mounted to a second holder board. The particular semiconductor substrate is detached from the second holder board and, then, mounted to the first holder board. Alternatively, at least one of the plural semiconductor substrates is detached from the first holder board and, then, mounted to a third holder board differing in size from the first holder board.

Abstract: A method of manufacturing a semiconductor device includes the steps of forming an insulating film on a silicon region of a substrate having the silicon region on a surface the insulating film having an opening for forming an exposed region of the silicon region, supplying a gas containing a halogen onto the silicon region, and supplying a source gas of silicon onto the silicon region, thereby selectively depositing the silicon on the exposed region of the silicon region.

Abstract: A method for rounding the corners of trench formed on the silicon substrate with metal, metal silicide or polycrystalline silicon thin film or the step portions of lead layers is provided. The steps of rounding are performed by chemical dry etching using a gas mixture of fluorine and oxygen. The abundance ratio of oxygen is determined to be one or more with respect to the fluorine. This method contributes significantly to the prevention of leakage current and the enhancement of insulating effect in the case of forming trench capacitors or the like.

Abstract: Oxide material, on a substrate, in a reactor, is etched by dissolving a hydrogen halide reaction product in a liquid phase reaction product. Both the hydrogen halide and liquid phase reaction products are produced through a chemical reaction of a reactive gas containing hydrogen and halogen elements as well as at least one gaseous compound which has been remotely activated. The liquid phase reaction product is obtained by condensation on the oxide material. The use of charged particle beams and irradiating light is discussed.