Abstract: A vacuum-processing apparatus comprising a vacuum vessel, a processing chamber arranged in the vacuum vessel and a heater for heating a circumferential wall of the processing chamber, wherein a substrate is arranged in the processing chamber and the substrate is vacuum-processed in the processing chamber, characterized in that the vacuum-processing apparatus has a cooling plate arranged at a position to oppose the circumferential wall of the processing chamber for cooling the circumferential wall of the processing chamber, and a mechanism for moving the cooling plate so as to change a distance between the cooling plate and the circumferential wall of the processing chamber.

Abstract: A deposition apparatus of the present invention is arranged so that a surface area of a radio-frequency power applying cathode electrode disposed in a glow discharge space, in a space in contact with discharge is greater than a surface area of the whole of a ground electrode (anode electrode) including a beltlike member in the discharge space. This structure can maintain the potential (self-bias) of the cathode electrode disposed in the glow discharge space automatically at a positive potential with respect to the ground (anode) electrode including the beltlike member. As a result, the bias is applied in the direction of irradiation of ions with positive charge to a deposit film on the beltlike member, so that the ions existing in the plasma discharge are accelerated more efficiently toward the beltlike member, thereby effectively giving energy to the surface of deposit film by ion bombardment.

Abstract: In the step of forming a microcrystalline i-type semiconductor layer by high-frequency plasma CVD, wherein an area of the parallel-plate electrode is represented by S; a width of the discharge space in its direction perpendicular to the transport direction of the belt-like substrate, by Ws; a width of a region formed by the parallel-plate electrode together with its surrounding insulating region, in its direction perpendicular to the transport direction of the belt-like substrate, by Wc; a width of the belt-like substrate in the direction perpendicular to its transport, by Wk; a distance between the parallel-plate electrode and the belt-like substrate, by h; a power density at which crystal fraction begins to saturate at predetermined substrate temperature, material gas flow rate and pressure, by Pd; and a high-frequency power, by P, 2h/(Ws−Wc)≧2.5, (Ws/h)×2(Ws−Wk)/[4h+(Ws−Wc) ]≧10, and P≧(10/8)×Pd×S.

Abstract: For efficiently forming a semiconductor element with excellent adhesion and environment resistance, a semiconductor element forming method is configured to have a step of forming a plurality of pin junctions of a silicon-based material on a substrate by a high-frequency plasma CVD process under a pressure of not more than atmospheric pressure, and the method further has a step of forming a p-layer, an i-layer, and a portion of an n-layer of a first pin junction of the pin junctions or forming an n-layer, an i-layer, and a portion of a p-layer of a first pin junction of the pin junctions, and thereafter exposing the p-layer or the n-layer exposed in the surface, to an oxygen-containing atmosphere; a step of forming on the p-layer or the n-layer as exposed to the oxygen-containing atmosphere a layer of the same conductivity type as that of the p-layer or the n-layer; and a step of forming an n-layer or a p-layer of a second pin junction adjacent to the first pin junction to form a pn interface.

Abstract: A film-forming apparatus which has at least a vacuum vessel whose inside is capable of being vacuumed and a film-forming chamber having a discharge region provided in said vacuum vessel and in which a substrate web having a desired width and a desired length is arranged so as to constitute a part of said film-forming chamber, wherein said substrate web is continuously moved to pass through said discharge region of said film-forming chamber to continuously form a deposited film on said substrate web, characterized in that said film-forming chamber is provided with an opening-adjusting member such that said opening-adjusting member constitutes an entrance or/and an exit of said film-forming chamber, and a face of said opening-adjusting member which is opposed to said substrate web has one or more grooves formed substantially in parallel to a direction for said substrate web to be transported.

Abstract: A method for forming a non-single-crystal semiconductor thin film and a photovoltaic device using an apparatus, which has a film deposition chamber with a film-forming space surrounded by a film deposition chamber wall and a belt-like substrate. An external chamber surrounding the deposition chamber wall is provided in the apparatus. While the belt-like substrate is moved in a longitudinal direction, a film-forming gas is introduced through a gas supply device into the film-forming space and microwave energy is radiated from a microwave applicator into the film-forming space to induce a microwave plasma, and thereby form a non-single-crystal semiconductor thin film on a surface of the belt-like substrate. A cooling mechanism and a temperature-increasing mechanism covering a part of an outside surface of the deposition chamber wall provide temperature control.

Abstract: The photovoltaic element of the present invention is a photovoltaic element comprised of a semiconductor-junctioned element, characterized in that the element includes a first electrically conductive type semiconductor layer, a non-crystalline i type semiconductor layer, a microcrystalline i type semiconductor layer and a microcrystalline second electrically conductive type semiconductor layer and is pin-junctioned, and a method of and an apparatus for manufacturing the same are characterized by efficiently and continuously mass-producing the photovoltaic element having an excellent current-voltage characteristic and excellent photoelectric conversion efficiency.

Abstract: In the step of forming a microcrystalline i-type semiconductor layer by high-frequency plasma CVD, where an area of the parallel-plate electrode is represented by S; a width of the discharge space in its direction perpendicular to the transport direction of the belt-like substrate, by Ws; a width of a region formed by the parallel-plate electrode together with its surrounding insulating region, in its direction perpendicular to the transport direction of the belt-like substrate, by Wc; a width of the belt-like substrate in the direction perpendicular to its transport, by Wk; a distance between the parallel-plate electrode and the belt-like substrate, by h; a power density at which crystal fraction begins to saturate at predetermined substrate temperature, material gas flow rate and pressure, by Pd; and a high-frequency power, by P; these are set as follows:

Abstract: A vacuum-processing apparatus comprising a vacuum vessel, a processing chamber arranged in said vacuum vessel and a heater for heating a circumferential wall of said processing chamber, wherein a substrate is arranged in said processing chamber and said substrate is vacuum-processed in said processing chamber, characterized in that said vacuum-processing apparatus has a cooling plate arranged at a position to oppose said circumferential wall of said processing chamber for cooling said circumferential wall of said processing chamber, and a mechanism for moving said cooling plate so as to change a distance between said cooling plate and said circumferential wall of said processing chamber.

Abstract: A chemical-reaction inducing means is provided in an exhaust line connecting a processing space for subjecting a substrate or a film to plasma processing to an exhaust means, and at least either an unreacted gas or byproduct exhausted from the processing space are caused to chemically react without allowing plasma in the processing space to reach the chemical-reaction inducing means, thereby improving the processing ability of the chemical-reaction inducing means to process the unreacted gas or byproduct.

Abstract: To provide an apparatus for forming a deposited film, which is a parallel plate electrode type CVD apparatus, with a discharge vessel receiving a material gas flowing therein and discharging air therefrom, decomposing the material gas by the aid of a plasma generated therein, and depositing the film on the substrate, in which the exhaust port of the material gas exhaust means has an opening wider in the lateral direction than the parallel plate electrode. This structure diminishes the stagnant region of the material gas during the deposited film forming process and controls formation of by-products, to deposit the film uniform in quality and thickness.

Abstract: A process is provided for producing a photovoltaic element which has at least one pin junction, and a buffering semiconductor layer constituted of plural sublayers between an n-type layer and an i-type layer and/or between an i-type layer and a p-type layer, through production steps of introducing a source material gas into an electric discharge space in a reaction chamber, and decomposing the source material gas by plasma discharge to form a non-monocrystalline semiconductor layer. In the process, in electric discharge generation for formation of at least one of the sublayers, the polarity of the electrode confronting the substrate for formation of a first sublayer and the polarity of the electrode confronting the substrate for formation of a second sublayer adjacent to the first sublayer is made different from each other, or the potential of one of the electrodes is set at zero volt. Thereby, diffusion of the dopant from the p-type layer or the n-type layer into the i-type layer is prevented effectively.

Abstract: The photovoltaic element of the present invention is a photovoltaic element comprised of a semiconductor-junctioned element, characterized in that the element includes a first electrically conductive type semiconductor layer, a non-crystalline i type semiconductor layer, a microcrystalline i type semiconductor layer and a microcrystalline second electrically conductive type semiconductor layer and is pin-junctioned, and a method of and an apparatus for manufacturing the same are characterized by efficiently and continuously mass-producing the photovoltaic element having an excellent current-voltage characteristic and excellent photoelectric conversion efficiency.

Abstract: There is provided a method of forming a photovoltaic element, in which a p-type semiconductor layer is formed in a device for forming a semiconductor thin film having a cathod electrode structure, in which in a plasma discharge space, the surface area of a cathod electrode in a plasma discharge space is larger than the sum of surface areas of a belt-like member and an anode electrode, a potential of said cathod electrode at the time of excitation of glow discharge is positive relative to the belt-like member and the anode electrode, and a separator electrode partially constituting the cathod electrode is configured to have a form of a fin or a block, and an n-type semiconductor layer is formed in a device for forming a semiconductor thin film having a cathod electrode structure of a capacitive-coupling, parallel-plate type.

Abstract: An apparatus for forming a non-single-crystal semiconductor thin film comprising a film deposition chamber having a film-forming space surrounded by a film deposition chamber wall and a beltlike substrate, and an external chamber surrounding the deposition chamber wall is provided. While the beltlike substrate is moved in a longitudinal direction, a film-forming gas is introduced through a gas supply device into the film-forming space and microwave energy is radiated from a microwave applicator into the film-forming space to induce a microwave plasma, and thereby form a non-single-crystal semiconductor thin film on a surface of the beltlike substrate. A cooling mechanism and a temperature-increasing mechanism are provided to cover a part of an outside surface of the deposition chamber wall. An apparatus for forming a non-single-crystal semiconductor thin film where the gas supply device comprises a gas manifold set apart from the deposition chamber wall is another embodiment.

Abstract: The deposited-film-forming apparatus of the present invention is an apparatus for forming deposited films while continuously passing a belt-like member through the insides of a plurality of vacuum chambers connected via connecting members and superposingly forming a plurality of different thin films on the surface of the belt-like member by plasma-assisted CVD, wherein the vacuum chambers are fixed to a stand for supporting the vacuum chambers, and a mechanism for relaxing stress acting in the transport direction of the belt-like member, generated in the vacuum chambers by the action of expansion and contraction due to thermal expansion of the vacuum chambers, is provided between each vacuum chamber and each connecting member.

Abstract: The present invention aims to provide a continuous forming method and apparatus for functional deposited films having excellent characteristics while preventing any mutual mixture of gases between film forming chambers having different pressures, wherein semiconductor layers of desired conductivity type are deposited on a strip-like substrate within a plurality of film forming chambers, by plasma CVD, while the strip-like substrate is moved continuously in a longitudinal direction thereof through the plurality of film forming chambers connected via gas gates having means for introducing a scavenging gas into a slit-like separation passage, characterized in that at least one of the gas gates connecting the i-type layer film forming chamber for forming the semiconductor junction and the n- or p-type layer film forming chamber having higher pressure than the i-type layer film forming chamber has the scavenging gas introducing position disposed on the n- or p-type layer film forming chamber side off from the cent

Abstract: The present invention aims to provide a continuous forming method and apparatus for functional deposited films having excellent characteristics while preventing any mutual mixture of gases between film forming chambers having different pressures, wherein each of semiconductor layers of desired conduction type is deposited on a strip-like substrate within a plurality of film forming chambers, by plasma CVD, while the strip-like substrate is being moved continuously in a longitudinal direction thereof through the plurality of film forming chambers connected via a gas gate having the structure of introducing a scavenging gas into a slit-like separation passage, characterized in that at least one of the gas gates connecting the i-type layer film forming chamber for forming the semiconductor junction and the n- or p-type layer film forming chamber having higher pressure than the i-type layer film forming chamber has the scavenging gas introducing position disposed on the n- or p-type layer film forming chamber sid

Abstract: A method of manufacturing thin films by plasma CVD is described. This method comprises supplying power to a power electrode in a way such that a self-bias upon plasma discharge of the power applying electrode, which is situated in a plasma discharge space, is a positive potential relative to a ground electrode.

Abstract: A continuous film-forming apparatus includes a plurality of reaction chambers each capable of forming a semiconductor film with a different chemical composition. The reaction chambers are arranged such that a substrate web on which a film is to be formed can be hermetically moved through each of the reaction chambers under a vacuum condition. A gas gate is disposed at a central position between each pair of adjacent reaction chambers, with each gas gate provided with a slit for communication between the adjacent reaction chambers.