Abstract: An ion implantation apparatus according to an embodiment includes an ion implantation unit, a position detection unit, a charge supply unit, a current value detection unit, and a determination unit. The ion implantation unit scans the surface of a substrate with an ion beam containing positively charged ions and implants the ions into the substrate. The position detection unit detects the scan position of the ion beam on the substrate. The charge supply unit generates a plasma, emits electrons contained in the plasma, and supplies the electrons to the substrate. The current value detection unit detects a current value that changes in accordance with the amount of electrons emitted by the charge supply unit. The determination unit determines the charge build-up state of the substrate based on a change in the current value, the change being accompanied by a change in the scan position.

Abstract: An ion implantation apparatus according to an embodiment includes an ion implantation unit, a position detection unit, a charge supply unit, a current value detection unit, and a determination unit. The ion implantation unit scans the surface of a substrate with an ion beam containing positively charged ions and implants the ions into the substrate. The position detection unit detects the scan position of the ion beam on the substrate. The charge supply unit generates a plasma, emits electrons contained in the plasma, and supplies the electrons to the substrate. The current value detection unit detects a current value that changes in accordance with the amount of electrons emitted by the charge supply unit. The determination unit determines the charge build-up state of the substrate based on a change in the current value, the change being accompanied by a change in the scan position.

Abstract: An insulating film formed on a conducting layer is dry-etched so as to make a connection hole in the insulating film to expose the conducting layer. Plasma is supplied onto the exposed conducting layer to dry-clean a damage layer produced in the connection hole. A product produced in the connection hole as a result of the dry cleaning is removed by a wet process. An oxide film formed in the connection hole as a result of the wet process is etched by a chemical dry process using a gas including either NF3 or HF. A thermally decomposable reaction product produced as a result of the etching is removed by heat treatment.

Abstract: An insulating film formed on a conducting layer is dry-etched so as to make a connection hole in the insulating film to expose the conducting layer. Plasma is supplied onto the exposed conducting layer to dry-clean a damage layer produced in the connection hole. A product produced in the connection hole as a result of the dry cleaning is removed by a wet process. An oxide film formed in the connection hole as a result of the wet process is etched by a chemical dry process using a gas including either NF3 or HF. A thermally decomposable reaction product produced as a result of the etching is removed by heat treatment.

Abstract: An insulating film formed on a conducting layer is dry-etched so as to make a connection hole in the insulating film to expose the conducting layer. Plasma is supplied onto the exposed conducting layer to dry-clean a damage layer produced in the connection hole. A product produced in the connection hole as a result of the dry cleaning is removed by a wet process. An oxide film formed in the connection hole as a result of the wet process is etched by a chemical dry process using a gas including either NF3 or HF. A thermally decomposable reaction product produced as a result of the etching is removed by heat treatment.

Abstract: An insulating film formed on a conducting layer is dry-etched so as to make a connection hole in the insulating film to expose the conducting layer. Plasma is supplied onto the exposed conducting layer to dry-clean a damage layer produced in the connection hole. A product produced in the connection hole as a result of the dry cleaning is removed by a wet process. An oxide film formed in the connection hole as a result of the wet process is etched by a chemical dry process using a gas including either NF3 or HF. A thermally decomposable reaction product produced as a result of the etching is removed by heat treatment.

Abstract: According to an embodiment of the present invention, a plating apparatus, including: a plating solution tank configured to store a plating solution; a holder configured to hold a substrate on which a seed layer is formed in said plating solution tank; a first anode disposed in said plating solution tank, composed of a more anodic material in its oxidation-reduction potential than the oxidation-reduction potential of a metal composing the seed layer, and electrically connectable to the seed layer of the substrate held by said holder; and a second anode disposed in said plating solution tank, capable of applying a voltage between the seed layer of the substrate held by holder, is provided.

Abstract: A semiconductor device includes a metal wiring provided on a semiconductor substrate. The device further includes an anti-metal diffusion film formed on the metal wiring, a buffer layer which is formed on the anti-metal diffusion film and includes at least a silicon-methyl radical bond and a silicon-oxygen bond, and a low-dielectric constant film layer which is formed on the buffer layer and includes at least the silicon-methyl radical bond and the silicon-oxygen bond, wherein the silicon-methyl radical bonding density of the buffer layer is less than the silicon-methyl radical bonding density of the low-dielectric constant film layer.

Abstract: Disclosed is a method of manufacturing a semiconductor device, in which a silicon oxide film containing fluorine, said film exhibiting a low dielectric constant and a low hygroscopicity and acting as an insulating film for electrically isolating wirings included in a semiconductor device, is formed by a plasma CVD method using a source gas containing at least silicon, oxygen and fluorine, under the conditions that the relationship between the gas pressure P (Torr) and the ion energy E (eV) satisfies formula A given below:P.gtoreq.5.times.10.sup.-4, P.ltoreq.10.sup.-1.times.10.sup.-E/45( A)and the relationship between the ion energy E (eV) and the plasma density D (/cm.sup.3) satisfies the formula B given below:D.gtoreq.2.times.10.sup.11.times.10.sup.-E/45, 10 .ltoreq.

Abstract: Disclosed is a method of manufacturing a semiconductor device, in which a silicon oxide film containing fluorine, said film exhibiting a low dielectric constant and a low hygroscopicity and acting as an insulating film for electrically isolating wirings included in a semiconductor device, is formed by a plasma CVD method using a source gas containing at least silicon, oxygen and fluorine, under the conditions that the relationship between the gas pressure P (Torr) and the ion energy E (eV) satisfies formula A given below:P.gtoreq.5.times.10.sup.-4,P.ltoreq.10.sup.-1 .times.10.sup.-E/45(A)and the relationship between the ion energy E (ev) and the plasma density D (/cm.sup.3) satisfies the formula B given below:D.gtoreq.2.times.10.sup.11 .times.10.sup.-E/45, 10.ltoreq.