摘要:
An improved pin junction photovoltaic element which causes photoelectromotive force by the junction of a p-type semiconductor layer, an i-type semiconductor layer and an n-type semiconductor layer, characterized in that at least one of said p-type semiconductor layer and said n-type semiconductor layer comprises a p-typed or n-typed ZSnSe.sub.1-x Te.sub.x :H:M film, where M is a dopant of p-type or n-type: the quantitative ratio of the Se to the Te is in the range of from 1:9 to 3:7 in terms of atomic ratio: the amount of the H is in the range of from 1 to 4 atomic %: and said film contains crystal grain domains in a proportion of 65 to 85 vol % per unit volume; and said i-type semiconductor layer comprises a non-single crystal Si(H,F) film or a non-single crystal Si(C,Ge)(H,F) film.
摘要:
A photovoltaic element which generates photoelectromotive force by the contact of a p-type semiconductor layer and an n-type semiconductor layer, characterized in that at least one of said semiconductor layers is made up from a deposited film composed of zinc atoms, selenium atoms, optional tellurium atoms, and at least hydrogen atoms, said deposited film containing a p-type or n-type doping agent, containing 1 to 4 atomic % of hydrogen atoms, containing selenium atoms and tellurium atoms in a ratio of 1:9 to 3:7 (in terms of number of atoms), and also containing crystal grains in a ratio of 65 to 85 vol % per unit volume.
摘要:
An improved pin junction photovoltaic element which generates photoelectromotive force by the junction of a p-type semiconductor layer, an i-type semiconductor layer and an n-type semiconductor layer, characterized in that at least said i-type semiconductor layer comprises a member selected from the group consisting of a ZnSe:H deposited film containing the hydrogen atoms in an amount of 1 to 4 atomic % and crystal grain domains in a proportion of 65 to 85 vol % per unit volume and a ZnSe.sub.1-x Te.sub.x :H deposited film containing the hydrogen atoms in an amount of 1 to 4 atomic % and crystal grain domains in a proportion of 65 to 85 vol % per unit volume and also containing the selenium atoms and the tellurium atoms in a Se/Te quantitative ratio of 1:9 to 3:7.The pin junction photovoltaic element exhibits an improved photoelectric conversion efficiency for short-wavelength light and has a high open-circuit voltage. The pin junction photovoltaic element does not exhibit any undesirable light-induced fatigue even upon continuous use for a long period of time.
摘要:
There is provided a functional ZnSe:H deposited film composed of zinc atoms, selenium atoms, and at least hydrogen atoms, with the content of hydrogen atoms being 1 to 4 atomic % and the ratio of crystal grains per unit volume being 65 to 85 vol %. It is capable of efficient doping and is stable to irradiation. It can be made into a high conductivity p-type of n-type ZnSe:H:M film by doping. It can be efficiently deposited on a non-single crystal substrate such as metal, glass, and synthetic resin which was incapable of efficient depositing. Thus the invention makes it possible to form a high-functional device such as a photovoltaic element of ZnSe film on a non-single crystal substrate.
摘要:
An improved pin junction photovoltaic element which causes photoelectromotive force by the junction of a p-type semiconductor layer, an i-type semiconductor layer and an n-type semiconductor layer, characterized in that at least one of said p-type semiconductor layer and said n-type semiconductor layer comprises a p-typed or n-typed ZnSe:H:M film, where M is a dopant of p-type or n-type: the amount of the H is in the range of from 1 to 4 atomic %: and said film contains crystal grain domains in a proportion of 65 to 85 vol % per unit volume; and said i-type semiconductor layer comprises a non-single crystal Si(H,F) film or a non-single crystal Si(C,Ge)(H,F) film.
摘要:
A process for producing a semiconductor layer by introducing a raw gas into a discharge chamber and supplying high-frequency power to the chamber to decompose the raw gas by discharge, thereby forming a semiconductor layer on a substrate within the discharge chamber, the process comprising the steps of supplying high-frequency power of at least very high frequency (VHF) as the high-frequency power; supplying bias power of direct current power and/or high-frequency power of radio-frequency (RF) together with the high-frequency power of VHF to the discharge chamber; and controlling a direct current component of an electric current flowing into an electrode, to which the bias power is supplied, so as to fall within a range of from 0.1 A/m2 to 10 A/m2 in terms of a current density based on the area of an inner wall of the discharge chamber. A good-quality semiconductor layer can be deposited over a large area at a high speed.
摘要翻译:一种制造半导体层的方法,该方法是通过将原料气体引入放电室并向室内供给高频电力,以通过放电来分解原料气体,由此在放电室内的基板上形成半导体层,该方法包括 提供至少非常高频(VHF)的高频功率作为高频功率的步骤; 将直流电力和/或射频(RF)的高频功率与VHF的高频功率一起提供给放电室; 并且以电流密度为基础控制流入施加偏压功率的电极的电流的直流分量,以0.1A / m 2至10A / m 2的范围内 放电室内壁面积。 高质量的半导体层可以在大面积上高速沉积。
摘要:
A high frequency plasma processing apparatus and a high frequency plasma processing method according to the invention can suitably be used for uniformly forming on a substrate a deposition film over a large area. The apparatus and the related method solve the problem wherein high frequency power supplied to a known plasma processing apparatus can become distorted to produce harmonics and give rise to difficulty in correctly reading the incident and reflected powers and realizing an accurate matching when a VHF is used in order to raise the processing rate.
摘要:
A process for forming a deposited film, a process for manufacturing a semiconductor element and a process for manufacturing a photoelectric conversion element are disclosed which each comprises a step of forming a first conductivity type semiconductor layer comprising a non-monocrystalline semiconductor on a substrate, a step of forming a substantially i-type semiconductor layer comprising an amorphous semiconductor on the first conductivity type semiconductor layer, a step of forming a substantially i-type semiconductor layer comprising a microcrystalline semiconductor on the substantially i-type semiconductor layer comprising the amorphous semiconductor while decreasing the film forming rate thereof and a step of forming a second conductivity type semiconductor layer comprising a non-monocrystalline semiconductor on the substantially i-type semiconductor layer comprising the microcrystalline semiconductor. Further, a process for forming a deposited film, a process for manufacturing a semiconductor element and a process for manufacturing a photoelectric conversion element are disclosed which each comprises a step of forming a first conductivity type semiconductor layer comprising a non-monocrystalline semiconductor on a substrate, a step of forming a substantially i-type semiconductor layer comprising an amorphous semiconductor on the first conductivity type semiconductor layer, a step of forming a substantially i-type semiconductor layer comprising a microcrystalline semiconductor on the substantially i-type semiconductor layer comprising the amorphous semiconductor and a step of forming a second conductivity type semiconductor layer comprising a non-monocrystalline semiconductor on the substantially i-type semiconductor layer comprising the microcrystalline semiconductor while increasing the film forming rate thereof. Thereby, a photoelectric conversion element having a high photoelectric conversion efficiency can be obtained with a high productivity.
摘要:
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. Thereby, a photovoltaic element having a high quality and superior uniformity over a large area, less defects, superior photo deterioration property and improved series resistance can be manufactured providing a high throughput in large quantities with good reproducibility.
摘要:
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. Thereby, there are provided a photovoltaic element in which the junction interface between the non-crystalline i type layer and the microcrystalline electrically conductive type layer has good grating consistency and which has an excellent current-voltage characteristic and excellent photoelectric conversion efficiency, and a method of and an apparatus for continuously mass-producing the same.