Patent application number | Description | Published |
20090046757 | Laser irradiation apparatus, laser irradiation method, and manufacturing method of semiconductor device - An object is to provide a laser irradiation apparatus and a laser irradiation method with which positions of crystal grain boundaries generated at the time of laser crystallization can be controlled. Laser light emitted from a laser | 02-19-2009 |
20090072343 | SEMICONDUCTOR DEVICE AND ELECTRONIC APPLIANCE - A high-performance semiconductor device using an SOI substrate in which a low-heat-resistance substrate is used as a base substrate. Further, a high-performance semiconductor device formed without using chemical polishing. Further, an electronic device using the semiconductor device. An insulating layer over an insulating substrate, a bonding layer over the insulating layer, and a single-crystal semiconductor layer over the bonding layer are included, and the arithmetic-mean roughness of roughness in an upper surface of the single-crystal semiconductor layer is greater than or equal to 1 nm and less than or equal to 7 nm. Alternatively, the root-mean-square roughness of the roughness may be greater than or equal to 1 nm and less than or equal to 10 nm. Alternatively, a maximum difference in height of the roughness may be greater than or equal to 5 nm and less than or equal to 250 nm. | 03-19-2009 |
20090111244 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A single crystal semiconductor substrate is irradiated with ions that are generated by exciting a hydrogen gas and are accelerated with an ion doping apparatus, thereby forming a damaged region that contains a large amount of hydrogen. After the single crystal semiconductor substrate and a supporting substrate are bonded, the single crystal semiconductor substrate is heated to be separated along the damaged region. While a single crystal semiconductor layer separated from the single crystal semiconductor substrate is heated, this single crystal semiconductor layer is irradiated with a laser beam. The single crystal semiconductor layer undergoes re-single-crystallization by being melted through laser beam irradiation, thereby recovering its crystallinity and planarizing the surface of the single crystal semiconductor layer. | 04-30-2009 |
20090115028 | METHOD FOR MANUFACTURING SEMICONDUCTOR SUBSTRATE, SEMICONDUCTOR DEVICE AND ELECTRONIC DEVICE - A semiconductor substrate including a single crystal semiconductor layer with a buffer layer interposed therebetween is manufactured. A semiconductor substrate is doped with hydrogen to form a damaged layer containing a large amount of hydrogen. After the single crystal semiconductor substrate and a supporting substrate are bonded, the semiconductor substrate is heated so that the single crystal semiconductor substrate is separated along a separation plane. The single crystal semiconductor layer is irradiated with a laser beam from the single crystal semiconductor layer side to melt a region in the depth direction from the surface of the laser-irradiated region of the single crystal semiconductor layer. Recrystallization progresses based on the plane orientation of the single crystal semiconductor layer which is solid without being melted; therefore, crystallinity of the single crystal semiconductor layer is recovered and the surface of the single crystal semiconductor layer is planarized. | 05-07-2009 |
20090115029 | Semiconductor substrate and method for manufacturing the same, and method for manufacturing semiconductor device - A semiconductor substrate is irradiated with accelerated hydrogen ions, thereby forming a damaged region including a large amount of hydrogen. After a single crystal semiconductor substrate and a supporting substrate are bonded to each other, the semiconductor substrate is heated, so that the single crystal semiconductor substrate is separated in the damaged region. A single crystal semiconductor layer which is separated from the single crystal semiconductor substrate is irradiated with a laser beam. The single crystal semiconductor layer is melted by laser beam irradiation, whereby the single crystal semiconductor layer is recrystallized to recover its crystallinity and to planarized a surface of the single crystal semiconductor layer. After the laser beam irradiation, the single crystal semiconductor layer is heated at a temperature at which the single crystal semiconductor layer is not melted, so that the lifetime of the single crystal semiconductor layer is improved | 05-07-2009 |
20090117692 | MANUFACTURING METHOD OF SEMICONDUCTOR DEVICE - A single crystal semiconductor substrate bonded over a supporting substrate with a buffer layer interposed therebetween and having a separation layer is heated to separate the single crystal semiconductor substrate using the separation layer or a region near the separation layer as a separation plane, thereby forming a single crystal semiconductor layer over the supporting substrate. The single crystal semiconductor layer is irradiated with a laser beam to re-single-crystallize the single crystal semiconductor layer through melting. An impurity element is selectively added into the single crystal semiconductor layer to form a pair of impurity regions and a channel formation region between the pair of impurity regions. The single crystal semiconductor layer is heated at temperature which is equal to or higher than 400° C. and equal to or lower than a strain point of the supporting substrate and which does not cause melting of the single crystal semiconductor layer. | 05-07-2009 |
20090117716 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE, AND SEMICONDUCTOR DEVICE AND ELECTRONIC DEVICE - To provide a high-performance semiconductor device using an SOI substrate in which a substrate having low heat resistance is used as a base substrate, to provide a high-performance semiconductor device without performing mechanical polishing, and to provide an electronic device using the semiconductor device, planarity of a semiconductor layer is improved and defects in the semiconductor layer are reduced by laser beam irradiation. Accordingly, a high-performance semiconductor device can be provided without performing mechanical polishing. In addition, a semiconductor device is manufactured using a region having the most excellent characteristics in a region irradiated with the laser beam. Specifically, instead of the semiconductor layer in a region which is irradiated with the edge portion of the laser beam, the semiconductor layer in a region which is irradiated with portions of the laser beam except the edge portion is used as a semiconductor element. Accordingly, performance of the semiconductor device can be greatly improved. Moreover, an excellent electronic device can be provided. | 05-07-2009 |
20090142879 | METHOD OF MANUFACTURING PHOTOELECTRIC CONVERSION DEVICE - A fragile layer is formed in a region at a depth of less than 1000 nm from one surface of a single crystal semiconductor substrate, and a first impurity semiconductor layer and a first electrode are formed at the one surface side. After bonding the first electrode and a supporting substrate, the single crystal semiconductor substrate is separated using the fragile layer or the vicinity as a separation plane, thereby forming a first single crystal semiconductor layer over the supporting substrate. An amorphous semiconductor layer is formed on the first single crystal semiconductor layer, and a second single crystal semiconductor layer is formed by heat treatment for solid phase growth of the amorphous semiconductor layer. A second impurity semiconductor layer having a conductivity type opposite to that of the first impurity semiconductor layer and a second electrode are formed over the second single crystal semiconductor layer. | 06-04-2009 |
20090142904 | METHOD FOR MANUFACTURING SOI SUBSTRATE - A second single crystal semiconductor film is formed over a first single crystal semiconductor film; a separation layer is formed by addition of ions into the second single crystal semiconductor film; a second insulating film functioning as a bonding layer is formed over the second single crystal semiconductor film; a surface of a first SOI substrate and a surface of a second substrate are made to face each other, so that a surface of the second insulating film and the surface of the second substrate are bonded to each other; and then heat treatment is performed to cause cleavage at the separation layer, so that a second SOI substrate in which a part of the second single crystal semiconductor film is provided over the second substrate with the second insulating film interposed therebetween is formed. | 06-04-2009 |
20090142908 | METHOD OF MANUFACTURING PHOTOELECTRIC CONVERSION DEVICE - A photoelectric conversion device having an excellent photoelectric conversion characteristic is provided while effectively utilizing limited resources. A fragile layer is formed in a region at a depth of less than 1000 nm from one surface of a single crystal semiconductor substrate, and a first impurity semiconductor layer, a first electrode, and an insulating layer are formed on the one surface side of the single crystal semiconductor substrate. After bonding the insulating layer to a supporting substrate, the single crystal semiconductor substrate is separated with the fragile layer or its vicinity used as a separation plane, thereby forming a first single crystal semiconductor layer over the supporting substrate. A second single crystal semiconductor layer is formed by epitaxially growing a semiconductor layer on the first single crystal semiconductor layer in accordance with a plasma CVD method in which a silane based gas and hydrogen with a flow rate 50 times or more that of the silane gas are used as a source gas. A second impurity semiconductor layer which has a conductivity type opposite to that of the first impurity semiconductor layer is formed over the second single crystal semiconductor layer. A second electrode is formed over the second impurity semiconductor layer. | 06-04-2009 |
20090162992 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - There are provided a semiconductor device having a structure which can realize not only suppression of a punch-through current but also reuse of a silicon wafer used for bonding, in manufacturing a semiconductor device using an SOI technique, and a manufacturing method thereof. A semiconductor film into which an impurity imparting a conductivity type opposite to that of a source region and a drain region is implanted is formed over a substrate, and a single crystal semiconductor film is bonded to the semiconductor film by an SOI technique to form a stacked semiconductor film. A channel formation region is formed using the stacked semiconductor film, thereby suppressing a punch-through current in a semiconductor device. | 06-25-2009 |
20090197392 | MANUFACTURING METHOD OF SOI SUBSTRATE - An SOI substrate is manufactured by a method in which a first insulating film is formed over a first substrate over which a plurality of first single crystal semiconductor films is formed; the first insulating film is planarized; heat treatment is performed on a single crystal semiconductor substrate attached to the first insulating film; a second single crystal semiconductor film is formed; a third single crystal semiconductor film is formed using the first single crystal semiconductor films and the second single crystal semiconductor films as seed layers; a fragile layer is formed by introducing ions into the third single crystal semiconductor film; a second insulating film is formed over the third single crystal semiconductor film; heat treatment is performed on a second substrate superposed on the second insulating film; and a part of the third single crystal semiconductor film is fixed to the second substrate. | 08-06-2009 |
20090209059 | METHOD FOR MANUFACTURING PHOTOELECTRIC CONVERSION DEVICE - The purpose is manufacturing a photoelectric conversion device with excellent photoelectric conversion characteristics typified by a solar cell with effective use of a silicon material. A single crystal silicon layer is irradiated with a laser beam through an optical modulator to form an uneven structure on a surface thereof. The single crystal silicon layer is obtained in the following manner; an embrittlement layer is formed in a single crystal silicon substrate; one surface of a supporting substrate and one surface of an insulating layer formed over the single crystal silicon substrate are disposed to be in contact and bonded; heat treatment is performed; and the single crystal silicon layer is formed over the supporting substrate by separating part of the single crystal silicon substrate fixed to the supporting substrate along the embrittlement layer or a periphery of the embrittlement layer. Then, irradiation with a laser beam is performed on a separation surface of the single crystal silicon layer through an optical modulator which modulates light intensity regularly, and unevenness is formed on the surface. Due to the unevenness, reflection of incident light is reduced and absorptance with respect to light is improved, therefore, photoelectric conversion efficiency of the photoelectric conversion device is improved. | 08-20-2009 |
20090269875 | METHOD FOR MANUFACTURING PHOTOELECTRIC CONVERSION DEVICE - An embrittlement layer is formed in the single crystal semiconductor substrate and a first impurity semiconductor layer, a first electrode, and an insulating layer are formed on one surface of the single crystal semiconductor substrate. After attaching the insulating layer and a supporting substrate to each other to bond the single crystal semiconductor substrate and the supporting substrate, the single crystal semiconductor substrate is separated along the embrittlement layer to form a stack including a first single crystal semiconductor layer. A first semiconductor layer and a second semiconductor layer are formed over the first single crystal semiconductor layer. A second single crystal semiconductor layer is formed by solid phase growth. A second impurity semiconductor layer having a conductivity type opposite to that of the first impurity semiconductor layer is formed on the second single crystal semiconductor layer. A second electrode is formed on the second impurity semiconductor layer. | 10-29-2009 |
20090269906 | METHOD FOR MANUFACTURING SEMICONDUCTOR SUBSTRATE - A semiconductor substrate is provided by a method suitable for mass production. Further, a semiconductor substrate having an excellent characteristic with effective use of resources is provided. A single crystal semiconductor substrate is irradiated with ions to form a damaged region in the single crystal semiconductor substrate; an insulating layer is formed over the single crystal semiconductor substrate; the insulating layer and a supporting substrate are bonded to each other; a first single crystal semiconductor layer is formed over the supporting substrate by partially separating the single crystal semiconductor substrate at the damaged region; a first semiconductor layer is formed over the first single crystal semiconductor layer; a second semiconductor layer is formed over the first semiconductor layer with a different condition from that used for forming the first semiconductor layer; a second single crystal semiconductor layer is formed by improving crystallinity of the first and the second semiconductor layers. | 10-29-2009 |
20090305469 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A stack including at least an insulating layer, a first electrode, and a first impurity semiconductor layer is provided over a supporting substrate; a first semiconductor layer to which an impurity element imparting one conductivity type is added is formed over the first impurity semiconductor layer; a second semiconductor layer to which an impurity element imparting the one conductivity type is added is formed over the first semiconductor layer under a condition different from that of the first semiconductor layer; crystallinity of the first semiconductor layer and crystallinity of the second semiconductor layer are improved by a solid-phase growth method to form a second impurity semiconductor layer; an impurity element imparting the one conductivity type and an impurity element imparting a conductivity type different from the one conductivity type are added to the second impurity semiconductor layer; and a gate electrode layer is formed via a gate insulating layer. | 12-10-2009 |
20100081254 | METHOD FOR MANUFACTURING SOI SUBSTRATE AND METHOD FOR MANUFACTURING SINGLE CRYSTAL SEMICONDUCTOR LAYER - An object is to provide a single crystal semiconductor layer with extremely favorable characteristics without performing CMP treatment or heat treatment at high temperature. Further, an object is to provide a semiconductor substrate (or an SOI substrate) having the above single crystal semiconductor layer. A first single crystal semiconductor layer is formed by a vapor-phase epitaxial growth method on a surface of a second single crystal semiconductor layer over a substrate; the first single crystal semiconductor layer and a base substrate are bonded to each other with an insulating layer interposed therebetween; and the first single crystal semiconductor layer and the second single crystal semiconductor layer are separated from each other at an interface therebetween so as to provide the first single crystal semiconductor layer over the base substrate with the insulating layer interposed therebetween. Thus, an SOI substrate can be manufactured. | 04-01-2010 |
20100129948 | METHOD FOR MANUFACTURING SEMICONDUCTOR SUBSTRATE AND METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - An object is to manufacture a semiconductor substrate having a single crystal semiconductor layer with favorable characteristics, without requiring CMP treatment and/or heat treatment at high temperature. In addition, another object is to improve productivity of semiconductor substrates. Vapor-phase epitaxial growth is performed by using a first single crystal semiconductor layer provided over a first substrate as a seed layer, whereby a second single crystal semiconductor layer is formed over the first single crystal semiconductor layer, and separation is performed at an interface of the both layers. Thus, the second single crystal semiconductor layer is transferred to the second substrate to provide a semiconductor substrate, and the semiconductor substrate is reused by performing laser light treatment on the seed layer. | 05-27-2010 |
20100275990 | PHOTOELECTRIC CONVERSION DEVICE AND MANUFACTURING METHOD THEREOF - To provide a novel photoelectric conversion device and a manufacturing method thereof. Over a base substrate having a light-transmitting property, a light-transmitting insulating layer and a single crystal semiconductor layer over the insulating layer are formed. A plurality of first impurity semiconductor layers each having one conductivity type is provided in a band shape in a surface layer of the single crystal semiconductor layer or on a surface of the single crystal semiconductor layer, and a plurality of second impurity semiconductor layers each having a conductivity type which is opposite to the one conductivity type is provided in a band shape in such a manner that the first impurity semiconductor layers and the second impurity semiconductor layers are alternately provided and do not overlap with each other. First electrodes in contact with the first impurity semiconductor layers and second electrodes in contact with the second impurity semiconductor layers are provided, and a back contact cell is formed, whereby a photoelectric conversion device provided with a photo acceptance surface on the base substrate side is formed. | 11-04-2010 |
20100291754 | SEMICONDUCTOR SUBSTRATE AND METHOD FOR MANUFACTURING THE SAME, AND METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A semiconductor substrate is irradiated with accelerated hydrogen ions, thereby forming a damaged region including a large amount of hydrogen. After a single crystal semiconductor substrate and a supporting substrate are bonded to each other, the semiconductor substrate is heated, so that the single crystal semiconductor substrate is separated in the damaged region. A single crystal semiconductor layer which is separated from the single crystal semiconductor substrate is irradiated with a laser beam. The single crystal semiconductor layer is melted by laser beam irradiation, whereby the single crystal semiconductor layer is recrystallized to recover its crystallinity and to planarized a surface of the single crystal semiconductor layer. After the laser beam irradiation, the single crystal semiconductor layer is heated at a temperature at which the single crystal semiconductor layer is not melted, so that the lifetime of the single crystal semiconductor layer is improved. | 11-18-2010 |
20100291755 | MANUFACTURING METHOD OF SOI SUBSTRATE - An SOI substrate is manufactured by a method in which a first insulating film is formed over a first substrate over which a plurality of first single crystal semiconductor films is formed; the first insulating film is planarized; heat treatment is performed on a single crystal semiconductor substrate attached to the first insulating film; a second single crystal semiconductor film is formed; a third single crystal semiconductor film is formed using the first single crystal semiconductor films and the second single crystal semiconductor films as seed layers; a fragile layer is formed by introducing ions into the third single crystal semiconductor film; a second insulating film is formed over the third single crystal semiconductor film; heat treatment is performed on a second substrate superposed on the second insulating film; and a part of the third single crystal semiconductor film is fixed to the second substrate. | 11-18-2010 |
20110053343 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - There are provided a semiconductor device having a structure which can realize not only suppression of a punch-through current but also reuse of a silicon wafer used for bonding, in manufacturing a semiconductor device using an SOI technique, and a manufacturing method thereof. A semiconductor film into which an impurity imparting a conductivity type opposite to that of a source region and a drain region is implanted is formed over a substrate, and a single crystal semiconductor film is bonded to the semiconductor film by an SOI technique to form a stacked semiconductor film. A channel formation region is formed using the stacked semiconductor film, thereby suppressing a punch-through current in a semiconductor device. | 03-03-2011 |
20110092013 | Method Of Manufacturing Photoelectric Conversion Device - A fragile layer is formed in a region at a depth of less than 1000 nm from one surface of a single crystal semiconductor substrate, and a first impurity semiconductor layer and a first electrode are formed at the one surface side. After bonding the first electrode and a supporting substrate, the single crystal semiconductor substrate is separated using the fragile layer or the vicinity as a separation plane, thereby forming a first single crystal semiconductor layer over the supporting substrate. An amorphous semiconductor layer is formed on the first single crystal semiconductor layer, and a second single crystal semiconductor layer is formed by heat treatment for solid phase growth of the amorphous semiconductor layer. A second impurity semiconductor layer having a conductivity type opposite to that of the first impurity semiconductor layer and a second electrode are formed over the second single crystal semiconductor layer. | 04-21-2011 |
20110129969 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A stack including at least an insulating layer, a first electrode, and a first impurity semiconductor layer is provided over a supporting substrate; a first semiconductor layer to which an impurity element imparting one conductivity type is added is formed over the first impurity semiconductor layer; a second semiconductor layer to which an impurity element imparting the one conductivity type is added is formed over the first semiconductor layer under a condition different from that of the first semiconductor layer; crystallinity of the first semiconductor layer and crystallinity of the second semiconductor layer are improved by a solid-phase growth method to form a second impurity semiconductor layer; an impurity element imparting the one conductivity type and an impurity element imparting a conductivity type different from the one conductivity type are added to the second impurity semiconductor layer; and a gate electrode layer is formed via a gate insulating layer. | 06-02-2011 |
20110303272 | Photoelectric Conversion Device and Manufacturing Method Thereof - An object is to provide a photoelectric conversion device in which defects are suppressed as much as possible by filling a separation process region of a semiconductor film with an insulating resin. A photoelectric conversion device includes a first conductive layer formed over a substrate; first to third semiconductor layers formed over the first conductive layer; a second conductive layer formed over the third semiconductor layer; a first separation groove for separating the first conductive layer and the first to third semiconductor layers into a plurality of pieces; a second separation groove for separating the first to third semiconductor layers into a plurality of pieces; and a third separation groove for separating the second conductive layer into a plurality of pieces. An insulating resin is filled in a structural defect that exists in at least one of the first to third semiconductor layers, and in the first separation groove. | 12-15-2011 |
20110318864 | METHOD FOR MANUFACTURING PHOTOELECTRIC CONVERSION DEVICE - The purpose is manufacturing a photoelectric conversion device with excellent photoelectric conversion characteristics typified by a solar cell with effective use of a silicon material. A single crystal silicon layer is irradiated with a laser beam through an optical modulator to form an uneven structure on a surface thereof. The single crystal silicon layer is obtained in the following manner; an embrittlement layer is formed in a single crystal silicon substrate; one surface of a supporting substrate and one surface of an insulating layer formed over the single crystal silicon substrate are disposed to be in contact and bonded; heat treatment is performed; and the single crystal silicon layer is formed over the supporting substrate by separating part of the single crystal silicon substrate fixed to the supporting substrate along the embrittlement layer or a periphery of the embrittlement layer. Then, irradiation with a laser beam is performed on a separation surface of the single crystal silicon layer through an optical modulator which modulates light intensity regularly, and unevenness is formed on the surface. Due to the unevenness, reflection of incident light is reduced and absorptance with respect to light is improved, therefore, photoelectric conversion efficiency of the photoelectric conversion device is improved. | 12-29-2011 |
20120007078 | SEMICONDUCTOR DEVICE - It is an object to provide a method of manufacturing a crystalline silicon device and a semiconductor device in which formation of cracks in a substrate, a base protective film, and a crystalline silicon film can be suppressed. First, a layer including a semiconductor film is formed over a substrate, and is heated. A thermal expansion coefficient of the substrate is 6×10 | 01-12-2012 |
20120086005 | PHOTOELECTRIC CONVERSION DEVICE AND MANUFACTURING METHOD THEREOF - A photoelectric conversion device including a single crystal silicon substrate; a first amorphous silicon layer in contact with a surface (a light-receiving surface) of the single crystal silicon substrate; a first polarity (p-type) impurity diffusion layer in contact with the first amorphous silicon layer; a second amorphous silicon layer in contact with a back surface of the single crystal silicon substrate; and a second polarity (n-type) impurity diffusion layer in contact with the second amorphous silicon layer, in which the first and second polarity impurity diffusion layers are microcrystalline silicon layers formed under a deposition condition where a pressure in a reaction chamber is adjusted to be greater than or equal to 450 Pa and less than or equal to 10000 Pa is provided. | 04-12-2012 |
20120115273 | MANUFACTURING METHOD OF PHOTOELECTRIC CONVERSION DEVICE - A photoelectric conversion device has a structure that includes a first amorphous silicon layer and a second amorphous silicon layer that are in contact with a single crystalline silicon substrate, and a first microcrystalline silicon layer with one conductivity type and a second microcrystalline silicon layer with a conductivity type that is opposite the one conductivity type that are in contact with the first and second amorphous silicon layers, respectively. The first and second microcrystalline silicon layers are formed using a plasma CVD apparatus that is suitable for high pressure film formation conditions. | 05-10-2012 |
20120153416 | PHOTOELECTRIC CONVERSION ELEMENT - An object is to provide a photoelectric conversion element with high conversion efficiency. In a photoelectric conversion element with a fine periodic structure on a light-receiving surface side, focus is given to the traveling direction of light that is reflected off another surface. The photoelectric conversion element may be given a structure in which a textured structure that reflects light to the other surface is provided, and light that travels from the light-receiving surface side to the other surface side is reflected so that a component that travels along the photoelectric conversion layer increases. By the distance traveled by the reflected light inside the photoelectric conversion layer increasing, the light that enters the photoelectric conversion element is more easily absorbed by the photoelectric conversion layer and less easily released from the light-receiving surface side, and a photoelectric conversion element with high conversion efficiency can be provided. | 06-21-2012 |
20120184064 | METHOD OF MANUFACTURING PHOTOELECTRIC CONVERSION DEVICE - A fragile layer is formed in a region at a depth of less than 1000 nm from one surface of a single crystal semiconductor substrate, and a first impurity semiconductor layer and a first electrode are formed at the one surface side. After bonding the first electrode and a supporting substrate, the single crystal semiconductor substrate is separated using the fragile layer or the vicinity as a separation plane, thereby forming a first single crystal semiconductor layer over the supporting substrate. An amorphous semiconductor layer is formed on the first single crystal semiconductor layer, and a second single crystal semiconductor layer is formed by heat treatment for solid phase growth of the amorphous semiconductor layer. A second impurity semiconductor layer having a conductivity type opposite to that of the first impurity semiconductor layer and a second electrode are formed over the second single crystal semiconductor layer. | 07-19-2012 |
20120211065 | PHOTOELECTRIC CONVERSION DEVICE - An object is to provide a photoelectric conversion device in which the amount of light loss due to light absorption in a window layer is small and light efficiency is high. A photoelectric conversion device, having a p-i-n junction, in which a light-transmitting semiconductor with p-type conductivity, a first silicon semiconductor layer with i-type conductivity, and a second silicon semiconductor layer with n-type conductivity are stacked between a pair of electrodes, is formed. The light-transmitting semiconductor layer is formed using an organic compound and an inorganic compound. A high hole-transport material is used for the organic compound, and a transition metal oxide having an electron-accepting property is used for the inorganic compound. | 08-23-2012 |
20120211066 | PHOTOELECTRIC CONVERSION DEVICE - A photoelectric conversion device in which photoelectric conversion in a light-absorption region in a crystalline silicon substrate is efficiently performed is provided. In the photoelectric conversion device, a light-transmitting conductive film which has a high effect of passivation of defects on a silicon surface and improves the reflectance oh a back electrode side is provided between the back electrode and the crystalline silicon substrate. The light-transmitting conductive film includes an organic compound arid an inorganic compound. The organic compound includes a material having an excellent hole-transport property. The inorganic compound includes a transition metal oxide having ah electron-accepting property. | 08-23-2012 |
20120211067 | PHOTOELECTRIC CONVERSION DEVICE - A photoelectric conversion device in which photoelectric conversion in a light-absorption layer is efficiently performed is provided. In the photoelectric conversion device, a light-transmitting conductive film which has a high effect of passivation of defects on a silicon surface and improves the reflectance on a back electrode side is provided between the back electrode and one of semiconductor layers for generation of an internal electric field. The light-transmitting conductive film includes an organic compound and an inorganic compound. The organic compound includes a material having an excellent hole-transport property. The inorganic compound includes a transition metal oxide having an electron-accepting property. | 08-23-2012 |
20120211081 | PHOTOELECTRIC CONVERSION DEVICE - An object is to provide a photoelectric conversion device which has little loss of light absorption in a window layer and has high conversion efficiency. A photoelectric conversion device including a crystalline silicon substrate having n-type conductivity and a light-transmitting semiconductor layer having p-type conductivity between a pair of electrodes is formed. In the photoelectric conversion device, a p-n junction is formed between the crystalline silicon, substrate and the light-transmitting semiconductor layer, and the light-transmitting semiconductor layer serves as a window layer. The light-transmitting semiconductor layer includes an organic compound and an inorganic compound. As the organic compound and the inorganic compound, a material having a high hole-transport property and a transition metal oxide having an electron-accepting property are respectively used. | 08-23-2012 |