Abstract: A plating apparatus can form a plated film having a uniform thickness over the entire surface of a substrate without a change of members. The plating apparatus includes a substrate holder, a cathode contact for contacting a conductive film formed on the substrate so that the conductive film serves as a cathode, a ring-shaped seal member for covering the cathode contact and bringing its inner circumferential portion into contact with the peripheral portion of the substrate to seal the peripheral portion of the substrate, an anode disposed so as to face the conductive film formed on the substrate, and an auxiliary cathode disposed with respect to the seal member such that at least part of the auxiliary cathode is exposed on a surface of the seal member. Plating is carried out by bringing the conductive film, the anode and the auxiliary cathode into contact with a plating solution.

Abstract: A plating apparatus can form a plated film having a uniform thickness over the entire surface of a substrate without a change of members. The plating apparatus included a substrate holder, a cathode contact for contacting a conductive film formed on the substrate so that the conductive film serves as a cathode, a ring-shaped seal member for covering the cathode contact and bringing its inner circumferential portion into contact with the peripheral portion of the substrate to seal the peripheral portion of the substrate, an anode disposed so as to face the conductive film formed on the substrate, and an auxiliary cathode disposed to the seal member such that at least part of the auxiliary cathode expose on a surface of the seal member. Plating is carried out by bringing the conductive film, the anode and the auxiliary cathode into contact with a plating solution.

Abstract: A plating method can form a plated film having a uniform thickness over the entire surface, including the peripheral surface, of a substrate. The plating method includes: disposing an anode so as to face a conductive film, formed on a substrate, which serves as a cathode, and disposing an auxiliary cathode on an ring-shaped seal member for sealing a peripheral portion of the substrate; bringing the conductive film, the anode and the auxiliary cathode into contact with a plating solution; and supplying electric currents between the anode and the conductive film, and between the anode and the auxiliary cathode to carry out plating.

Abstract: An electrolytic processing method is used to remove a metal film formed on a surface of a substrate. The electrolytic processing method includes providing a feeding electrode 31 and a processing electrode 32 on a table 12, providing an insulating member 36 between the feeding electrode and the processing electrode, holding the substrate W by a substrate carrier 11, bringing the substrate into contact with the insulating member, supplying first and second electrolytic processing liquids to gaps between the feeding electrode and the substrate and between the processing electrode and the substrate, respectively, while the first and second electrolytic processing liquids are electrically isolated, applying voltage between the feeding electrode and the processing electrode, and making a relative movement between the substrate carrier and the table to electrically process the metal film.

Abstract: An electrolytic processing apparatus can planarize uniformly over an entire surface of a substrate under a low pressure without any damages to the substrate. The electrolytic processing apparatus has a substrate holder configured to hold and rotate a substrate having a metal film formed on a surface of the substrate and an electrolytic processing unit configured to perform an electrolytic process on the substrate held by the substrate holder. The electrolytic processing unit has a rotatable processing electrode, a polishing pad attached to the rotatable processing electrode, and a pressing mechanism configured to press the polishing pad against the substrate.

Abstract: An electrolytic processing apparatus is used to remove a metal film formed on a surface of a substrate. The electrolytic processing apparatus includes a feeding electrode 31 for feeding electricity to a metal film 6 on a substrate W, a processing electrode 32 for processing the metal film 6, a substrate carrier 11 for holding the substrate W, a first supply passage 51 for supplying a first electrolytic processing liquid, a second supply passage 52 for supplying a second electrolytic processing liquid, an insulating member 36 for electrically isolating the first electrolytic processing liquid and the second electrolytic processing liquid, a table 12 on which the feeding electrode 31, the processing electrode 32, and the insulating member 36 are disposed, and a relative movement mechanism 17 for making a relative movement between the table 12 and the substrate carrier 11.

Abstract: The present invention relates to a plasma-enhanced chemical vapor deposition (PECVD) method of depositing a thin layer of a material, such as silicon dioxide, on the surface of a body, such as a semiconductor substrate. The method includes forming in a deposition chamber a plasma by means of two electrical power sources of different frequencies. A reaction gas is admitted into the deposition chamber and subjected to the plasma. The reaction gas is a mixture of tetraethylorthosilicate and a halogen gas, such as a gas of fluorine, chlorine or bromine. The reaction gas is reacted by the plasma to cause the material of the gas to deposit on the body which is within the chamber. This results in a deposited layer having a smoothly tapered surface even when the surface of the body possesses valleys and mesas, and thus prevents the formation of voids.

Abstract: A method of forming conformal, high quality silicon oxide films that can be deposited over closely spaced, submicron lines and spaces without the formation of voids, comprises forming a plasma of TEOS and a selected halogen-containing gas in certain ratios. By proper control of the energy sources that create the plasma, the proper selection of the halogen-containing gas and selection of other processing parameters, high deposition rates can also be achieved.