Abstract: A photovoltaic device, including at least one photovoltaic cell, a flexible transparent layer formed over the at least one photovoltaic cell, a first encapsulant layer formed over a first major surface of the flexible transparent layer facing the at least one photovoltaic cell and a second encapsulant layer formed over a second major surface of the flexible transparent layer facing away from the at least one photovoltaic cell. The second encapsulant layer is made of a shear thickening polymer.

Abstract: An apparatus having a substrate, an LED light source attached to the substrate, an electrical connector attached to the substrate and electrically connected to the LED light source, a potting material on the substrate and covering at least a portion of the electrical connector; and a barrier separating the potting material from the LED light source, the barrier having a height that exceeds the thickness of the potting material on the substrate.

Abstract: The thermal management and method for large scale processing of CIS and/or CIGS based thin film overlaying glass substrates. According to an embodiment, the present invention provides a method for fabricating a copper indium diselenide semiconductor film. The method includes providing a plurality of substrates, each of the substrates having a copper and indium composite structure. The method also includes transferring the plurality of substrates into a furnace, each of the plurality of substrates provided in a vertical orientation with respect to a direction of gravity, the plurality of substrates being defined by a number N, where N is greater than 5. The method further includes introducing a gaseous species including a selenide species and a carrier gas into the furnace and transferring thermal energy into the furnace to increase a temperature from a first temperature to a second temperature, the second temperature ranging from about 350° C. to about 450° C.

Abstract: The thermal management and method for large scale processing of CIS and/or CIGS based thin film overlaying glass substrates. According to an embodiment, the present invention provides a method for fabricating a copper indium diselenide semiconductor film. The method includes providing a plurality of substrates, each of the substrates having a copper and indium composite structure. The method also includes transferring the plurality of substrates into a furnace, each of the plurality of substrates provided in a vertical orientation with respect to a direction of gravity, the plurality of substrates being defined by a number N, where N is greater than 5. The method further includes introducing a gaseous species including a selenide species and a carrier gas into the furnace and transferring thermal energy into the furnace to increase a temperature from a first temperature to a second temperature, the second temperature ranging from about 350° C. to about 450° C.

Abstract: Disclosed herein are a photovoltaic panel and a method of manufacturing the same. The photovoltaic panel includes a photovoltaic unit having a single substrate and a protective polymer layer wrapping around the photovoltaic unit and being sealed around the edges of a surface of the substrate. The manufacturing method includes the steps of providing a substrate, forming a photovoltaic cell on a first surface of the substrate to form a photovoltaic unit, wrapping a protective polymer layer around the photovoltaic unit with a portion of the protective polymer layer extended beyond the first surface, and thermal treating the protective polymer layer so as to shrink the to protective polymer layer and thereby sealing the portion of the protective polymer layer extended beyond the first surface of the substrate around the edges of the second surface.

Abstract: The invention relates generally to methods of repairing defects in thin films. Void defects in thin films are repaired using methods that take advantage of substrate manufacturing protocols rather than conventional superstrate manufacturing protocols. Methods described herein are simple, robust and compatible with existing processes and equipment used in the manufacture of superstrate devices.

Abstract: A method of placing a die includes providing an embedded plane. The embedded plane has a openings, grid lines, and protruding portions. Each of the plurality of openings are surrounding by a subset of the plurality of grid lines. At least one of the protruding portions extends into one of the openings. A die is placed into one of the openings and at least one of the protruding portions bends during such placement so that it is in contact with at least a portion of a minor surface of the die.

Abstract: The present invention is an optically transparent laminate film comprising: at least three layers of film, wherein at least two of the at least three layers comprise ionomeric films, and wherein the film can be suitable for use in a photovoltaic cell or in packaging.

Abstract: A photosensitizing chip package construction and manufacturing method thereof is comprised of photosensitizing chips constructed on one side of a wafer using a bonding layer; a color attachment array being disposed over those photosensitizing chips; a glass substrate provided with weir and covered up over the color attachment array; a proper gap being defined between the glass substrate and the color attachment array to promote permeability of stream of light by direct receiving stream of light from those photosensitizing chips constructed over the wafer.

Abstract: Various combinations of a first encapsulant and a second encapsulant on different locations of a photovoltaic module are used to meet various requirements of optical clarity, tensile strength, waterproofness, and resistivity.

Abstract: Disclosed herein is a method of manufacturing a photovoltaic device. The method includes the steps of providing a front substrate and a back substrate, forming a photovoltaic cell on the front substrate, encapsulating the photovoltaic cell by an encapsulant, attaching a solid state sealant tape on one of the two substrates, and adhering the two substrates through the solid state sealant tape and the encapsulant. The solid state sealant tape is in solid state at room temperature. The photovoltaic cell and the encapsulant are situated within an enclosed space formed by the two substrates and the solid state sealant tape.

Abstract: The invention relates to a method for producing a thin-film solar cell with a photoactive layer (100) that has, on the front side, an electrode (104) optically transparent in the range of visible light, wherein an electrically conductive network (110) of conductor tracks is applied on the rear side and/or the front side of the photoactive layer (100), which network, macroscopically seen, is transparent in the range of visible light.

Abstract: A method of protecting a substrate during fabrication of semiconductor, MEMS, or biotechnology devices. The method includes application of a protective thin film which typically has a thickness ranging from about 3 ? to about 1,000 ?, wherein precursor materials used to deposit the protective thin film are organic-based precursors which include at least one fluorine-comprising functional group at one end of a carbon back bone and at least one functional bonding group at the opposite end of a carbon backbone, and wherein the carbon backbone ranges in length from 4 carbons through about 12 carbons. In many applications at least a portion of the protective thin film is removed during fabrication of the devices.

Abstract: An electrical device and method of making same is provided wherein a chip or other electrical component is embedded in a substrate. The substrate may be a thermoplastic material capable of deforming around the chip and at least partially encasing the chip when heat and/or pressure is applied to the substrate. Electromagnetic radiation such a near infrared radiation can be used to heat the substrate. The substrate may include a compressible layer that can be compressed and/or crushed to form a recess into which the chip can be inserted. Once embedded, the chip or electrical component is secured by the substrate and may be coupled to another electrical component. A method of making an RFID transponder is also provided wherein an RFID chip is embedded in a substrate using heat and/or pressure, an antenna structure is applied to the substrate, and the RFID chip and antenna structure are coupled together.

Abstract: The present invention provides an image sensor and a fabricating method thereof capable of approaching higher quantum efficiency and reducing cost. The method comprises: providing a substrate; forming a pixel region on a top surface of the substrate; forming an interlayer insulating layer and at least a metal line on the pixel region; forming an isolation carrier layer having a hole array therein on the interlayer insulating layer; grinding a lower surface of the substrate to reduce the thickness of the substrate; placing a plurality of conductors into the hole array to form a plurality of bumps on the isolation carrier layer.

Abstract: A photovoltaic device including a current collection element and a method of making same. The photovoltaic device includes a substrate, a conductive layer, an active photovoltaic material, a transparent electrode and a current collection element. The current collection element includes a transparent support and one or more conductive wires integrated therewith. The conductive wires are in electrical communication with the transparent electrode. Current generated by the active photovoltaic material passes to the transparent electrode. The current collection element facilitates delivery of current passing through the transparent electrode to leads that deliver the current to an external load. The method includes placing a pre-fabricated current collection element in direct contact with the transparent electrode of the photovoltaic device. The time and expense of assembling the conductive wires during fabrication of the photovoltaic device is thereby avoided and higher manufacturing speeds are achieved.

Abstract: An image pickup device including a semiconductor substrate that is irradiated with light from a first surface side thereof, and reading signal charges generated in the semiconductor substrate in accordance with the light from a second surface side thereof, wherein the semiconductor substrate includes: a photoelectric converting layer that includes a plurality of impurity diffusion layers on the second surface side of the semiconductor substrate, and that produces the signal charges by photoelectric conversion; and an embedded member that includes a light blocking material, and that is embedded in an impurity diffusion layer on a surface side of the photoelectric converting layer, the surface side facing the second surface side of the semiconductor substrate.

Abstract: Disclosed herein is a semiconductor device including: a first semiconductor chip having an electronic circuit section and a first connecting section formed on one surface thereof; a second semiconductor chip having a second connecting section formed on one surface thereof, the second semiconductor chip being mounted on the first semiconductor chip with the first and the second connecting sections connected to each other by a bump; a dam formed to fill a gap between the first and the second semiconductor chips on a part of an outer edge of the second semiconductor chip, the part of the outer edge being on a side of a region of formation of the electronic circuit section; and an underfill resin layer filled into the gap, protrusion of the resin layer from the outer edge of the second semiconductor chip to a side of the electronic circuit section being prevented by the dam.

Abstract: It is desirable to provide a variable light condensing lens apparatus and a solar cell apparatus provided therewith in a simple configuration, yet capable of reducing dependency of light condensing efficiency on the angle of incidence of light and thereby improving power generation efficiency of the solar cell apparatus. The variable light condensing lens apparatus according to the present disclosure is provided with a translucent support having a hydrophilic photocatalyst on a surface thereof and a first translucent liquid supported on the surface of the translucent support in contact therewith and the solar cell apparatus according to the present disclosure is provided with a solar cell element, a pair of electrodes connected to the solar cell element and the variable light condensing apparatus according to the present disclosure disposed opposed to the solar cell element.

Abstract: A solar cell module and a method for manufacturing a solar cell module are provided. The solar cell module includes an interconnect sheet and a back contact solar cell mounted on the interconnect sheet. Electrodes of the back contact solar cell and interconnects of the interconnect sheet are connected to each other. An electrically insulating cured resin is disposed in a region between interconnects adjacent to each other of the interconnect sheet, the region being located between a semiconductor substrate of the back contact solar cell and an insulating base material of the interconnect sheet.

Abstract: In some embodiments, a semiconductor device includes a semiconductor chip configured to receive or emit light, a chip mounting region for mounting the semiconductor chip, an electrode arranged surrounding the chip mounting region, an electric connecting element which electrically connects the semiconductor chip and the electrode, an optically-transparent element arranged on a top surface of the semiconductor chip and made of optically-transparent material, a protection film arranged on a top surface of the optically-transparent element so as to surround a light passing region through which the light passes, and a filler-contained insulating resin which seals the semiconductor chip, the electric connecting element, the electrode, the optically-transparent element, and the protection film in a state in which a top surface of the protection film and the light passing region surrounded by the protection film are exposed outside.

Abstract: A method for large scale manufacture of photovoltaic devices includes loading a substrate into a load lock station and transferring the substrate in a controlled ambient to a first process station. The method includes using a first physical deposition process in the first process station to cause formation of a first conductor layer overlying the surface region of the substrate. The method includes transferring the substrate to a second process station, and using a second physical deposition process in the second process station to cause formation of a second layer overlying the surface region of the substrate. The method further includes repeating the transferring and processing until all thin film materials of the photovoltaic devices are formed. In an embodiment, the invention also provides a method for large scale manufacture of photovoltaic devices including feed forward control. That is, the method includes in-situ monitoring of the physical, electrical, and optical properties of the thin films.

Abstract: Method and apparatus providing a wafer level fabrication of imager modules in which a permanent carrier protects imager devices on an imager wafer and is used to support a lens wafer.

Abstract: The bow in a wafer that results from fabricating a large number of MEMS devices on the top surface of the passivation layer of the wafer so that a MEMS device is formed over each die region is reduced by forming a stress relief layer between the passivation layer and the MEMS devices.

Abstract: A packaging structure and process of solar cell is disclosed. The packaging structure of solar cell comprises two conductive films and two surface electrodes disposed on a photovoltaic cell (PV cell), wherein two conductive films are respectively electrically coupled with the surface electrodes via a plurality of solder balls.

Abstract: Improved photovoltaic module backsheets, and processes for making the same, are disclosed, including nylon resin films filled with mineral additives, for use in photovoltaic laminated modules. The present disclosure provides nylon-11 and/or nylon-1010 films and mineral additives for use as backsheet materials in photovoltaic modules having improved thermal and humidity performance.

Abstract: Provided are an electronic device package and a method of manufacturing the same. The electronic device package includes an electronic device including a polymer layer and a passivation layer configured to protect a device layer, a substrate assembly facing the electronic device, and a sealing ring formed in a closed loop between the electronic device and the substrate assembly and surrounding a sealing region. At least one side surface of the sealing ring contacts the polymer layer, and the sealing ring is disposed on the passivation layer. A polymer layer such as a microlens and a color filter is removed from a region provided with a sealing ring to form the sealing ring on a passivation layer, thereby making the sealing ring and joints the same height, thus preventing an electrical defect.

Abstract: Melted encapsulant is extruded directly onto the photovoltaic panel to encapsulate a photovoltaic panel.

Abstract: A method for installing a sorption element in a cavity including: disposing, within the cavity, a getter material, a reaction material, and a protective material, the protective material covering at least one part of the getter material so as to bury the at least one part; raising a temperature up to at least one removal temperature; and moving the protective material towards the reaction material by reaction between the protective material and the reaction material so that at least one portion of the part of the getter material is no longer covered with the protective material.

Abstract: A light receiving device 1 includes a support substrate 12 provided thereon with a photodetector 11 including a photodetecting portion 111 and a base substrate 112 on which the photodetecting portion 111 is placed; and a transparent substrate 13 disposed so as to oppose the face of the support substrate 12 on which the photodetector 11 is provided. Between the support substrate 12 and the transparent substrate 13, a frame portion 14 is provided so as to surround the photodetector 11. The frame portion 14 is a photo-curing adhesive, and directly adhered to the transparent substrate 13 and the support substrate 12. Such structure provides a light receiving device capable of exhibiting the desired performance, and a method of manufacturing such light receiving device can also be provided.

Abstract: A plurality of sensor packages (4) are fixed to a circuit assembly board (47) and placed on a lower mold die (56) of a transfer molding apparatus (54). Attached inside a cavity (58a) of an upper mold die (58) is a protection sheet (65), which will make contact with the upper face of a cover glass (6) of each sensor package (4). When the upper mold die (58) meshes with the lower mold die (56), the upper face of the cover glass (6) is tightly covered with the protection sheet (65). A plunger (62) is activated to fill the cavities (56a, 58a) with sealing resin (7). The upper face of the cover glass (6) is not stained or damaged when the peripheries of the sensor packages (4) are sealed.

Abstract: A sealant disposed between substrates for sealing, a dye-sensitized solar cell including the same, and a method of manufacturing the dye-sensitized solar cell, the sealant including hot melt adhesives for absorbing heat and adhering to the substrates; and heat generation particles absorbing energy and generating heat.

Abstract: In a solar cell module and a manufacturing method thereof according to an embodiment of the present invention, a solar cell (55) composed of a transparent electrode film, a photoelectric conversion layer and a back face electrode film is laminated on a light-transmitting insulating substrate (51). On the back face electrode film of the solar cell (55), an insulated lead wire (62, 63) and a back film (65) having an opening (65a) for drawing out an output lead portion (62a, 63a) of the lead wire (62, 63) are sequentially laminated. In such a solar cell module, an insulating sheet (11) is disposed between the back face electrode film of the solar cell (55) and the back film (65) so as to completely cover the opening (65a) of the back film (65). The insulating sheet (11) is disposed so as to cover the entire perimeter of the edge of the opening (65a) of the back film (65).

Abstract: Devices for converting light into electric current are provided. A representative device has an encasing structure having at least one portion transparent. The encasing structure is configured to pass light energy into an interior of the encasing structure. The device further has a photovoltaic device positioned within the interior of the encasing structure. The photovoltaic device is positioned to receive light energy. The photovoltaic device is operable to transform the light energy into electric current. The device further has a protective space material, disposed between the encasing structure and the photovoltaic device. The protective space material is operable to transmit the light energy. The protective space material is a non-solid material having a physical property such as a viscosity of less than 1×106 cP and/or a thermal coefficient of expansion of greater than 500×10?6/° C.

Abstract: A solar cell module includes a substrate having a thin-film layer patterned in a manner to form with a split window and a solar cell disposed on the substrate. The solar cell includes plurality of material layers and a plurality of split ways corresponding to the material layers. The scope of the split window is constituted by at least one of the split ways.

Abstract: The present invention is a sealing laminated sheet for an electronic device in which a first sheet and a second sheet 5 are laminated, wherein the first sheet contains an acid-modified polyolefin-based thermoplastic resin, the second sheet 5 has a melting point higher than that of the first sheet, and a peel strength at 25° C. of the second sheet 5 relative to the first sheet is 0.5 to 10.0 N/15 mm. According to the present invention, the production yield of an electronic device can be improved.

Abstract: A dye-sensitized solar cell manufacturing method of the invention comprises the steps of: preparing a first electrode having an oxide semiconductor layer and a second electrode; forming a first sealing portion by melting and bonding a thermoplastic resin at a first annular section of the first electrode; forming a second sealing portion by melting and bonding a thermoplastic resin at a second annular section of the second electrode; loading a photosensitive dye on the oxide semiconductor layer; forming an electrolyte layer by arranging an electrolyte on the first electrode within the first sealing portion; and forming a sealing portion through bonding the first and second sealing portions, wherein the electrolyte layer is formed after forming the first sealing portion; the sealing portion is formed after loading the dye and forming the electrolyte layer; and the sealing portion is formed through melting the first and second sealing portions, applying pressure.

Abstract: Size reduction of an image pickup module is promoted, and reliability of electric connection and electric noise resistance are improved by decreasing the numbers of components and connection spots. The problems are solved by providing an image pickup module including a solid-state image pickup element chip having an image pickup surface, a cover glass that covers the image pickup surface, and a wiring board on which the solid-state image pickup element chip is mounted, in which the solid-state image pickup element chip and the wiring board have an overlap structure in which end portions thereof are overlapped with each other, and a first electrode portion formed on the end portion of the solid-state image pickup element chip and a second electrode portion formed on the end portion of the wiring board are electrically connected through a bump.

Abstract: A process for assembling a camera module is provided. Firstly, a first conductive bump and a second conductive bump are placed on a signal terminal of a substrate and a contact pad of an image sensing chip, respectively. Then, the substrate and the image sensing chip are laminated, so that the first conductive bump and the second conductive bump are combined together and the signal terminal of the substrate and the contact pad of the image sensing chip are electrically connected with each other. Then, an underfill is applied to a region between the substrate and the image sensing chip. Since the two conductive bumps are connected with each other by the assembling process, the quality of the camera module of the present invention is enhanced.

Abstract: A method of forming an asymmetrical encapsulant bead on a series of wire bonds electrically connecting a micro-electronic device to a series of conductors, the micro-electronic device having a planar active surface. The method has the steps of positioning the die and the wire bonds beneath an encapsulant jetter that jets drops of encapsulant on to the wire bonds, the drops of encapsulant following a vertical trajectory, tilting the die such that the active surface is inclined to the horizontal and, jetting the drops of encapsulant to form a bead of encapsulant material covering the series of wire bonds, the bead having a cross sectional profile that is asymmetrical about an axis parallel to a normal to the active surface.

Abstract: An imaging device includes a lens (3), an optical filter (5), a semiconductor imaging element (4) having a light receiving section, and a tridimensional substrate (2) on which the semiconductor imaging element (4) and the optical filter (5) are mounted, wherein the tridimensional substrate (2) has an opening (14) corresponding to the light receiving section of the semiconductor imaging element (4), the semiconductor imaging element (4) and the optical filter (5) are located on one side of the opening (14), the lens (3) is located on the other side of the opening (14), and the semiconductor imaging element (4) and the optical filter (5) are fixed to the tridimensional substrate (2) under the condition that the semiconductor imaging element (4) and the optical filter (5) are curved, and have respective centers moved in a direction away from the lens (3).

Abstract: An embodiment of the invention provides a chip package, which includes: a semiconductor substrate having a device region; a package layer disposed on the semiconductor substrate; a spacing layer disposed between the semiconductor substrate and the package layer and surrounding the device region; and an auxiliary pattern having a hollow pattern formed in the spacing layer, a material pattern located between the spacing layer and the device region, or combinations thereof.

Abstract: A method for processing a thin film photovoltaic module. The method includes providing a plurality of substrates, each of the substrates having a first electrode layer and an overlying absorber layer composed of copper indium gallium selenide (CIGS)or copper indium selenide (CIS) material. The absorber material comprises a plurality of sodium bearing species. The method maintains the plurality of substrates in a controlled environment after formation of at least the absorber layer through one or more processes up to a lamination process. The controlled environment has a relative humidity of less than 10% and a temperature ranging from about 10 degrees Celsius to about 40 degrees Celsius. The method subjects the plurality of substrates to a liquid comprising water at a temperature from about 10 degrees Celsius to about 80 degrees Celsius to process the plurality of substrates after formation of the absorber layer.

Abstract: A photovoltaic structure can include a protective cap, which can include sodium.

Abstract: In an optical device having a direct attachment structure and a method of manufacturing the optical device, a light-transmissive member can be bonded to an element region without being misaligned. In the optical device, the element region is formed in a top surface of a semiconductor substrate. The light-transmissive member is bonded to the element region with a light-transmissive adhesive interposed therebetween. A dam portion is formed outside the element region on the top surface of the semiconductor substrate. A raised portion is formed on a top surface of the dam portion.

Abstract: A photovoltaic cell module, a photovoltaic array including at least two modules, and a method of forming the module are provided. The module includes a first outermost layer and a photovoltaic cell disposed on the first outermost layer. The module also includes a second outermost layer disposed on the photovoltaic cell and sandwiching the photovoltaic cell between the second outermost layer and the first outermost layer. The method of forming the module includes the steps of disposing the photovoltaic cell on the first outermost layer, disposing a silicone composition on the photovoltaic cell, and compressing the first outermost layer, the photovoltaic cell, and the second layer to form the photovoltaic cell module.

Abstract: A package structure of optical devices has a chip, a sealant, a cover, a substrate, a plurality of bonding wires, and a transparent encapsulant. The chip has at least an optical device and a plurality of chip connection pads. The sealant is disposed around the optical elements. The cover is disposed on the sealant. The substrate supports the chip and has a plurality of connection pads. The bonding wires are used for electrically connecting the chip connection pads of the chip to the connection pads of the substrate. The transparent encapsulant is formed over the substrate and the cover, and encapsulates the bonding wires.

Abstract: Methods and systems for photovoltaic roofing systems are provided. The system includes a back sheet including a length, L, a width, W, and a thickness, T, the back sheet including an overlap portion extending along length L having a width, WO and an active portion extending along length L having a width, WA. The system also includes a photovoltaic cell formed on a surface of the active portion, the photovoltaic cell including a photovoltaic member electrically responsive to an absorption of photons, a negative electrode coupled to a surface of the photovoltaic member, and a positive electrode coupled to the surface of the photovoltaic member, wherein the thickness T is selected such that thickness T plus a thickness of the photoelectric cell substantially match a thickness of a proximate non-photovoltaic roofing member when the photovoltaic roofing system is installed.

Abstract: The invention provides an integrated circuit package and method of fabrication thereof. The integrated circuit package comprises an integrated circuit chip having a photosensitive device thereon; a bonding pad formed on an upper surface of the integrated circuit chip and electrically connected to the photosensitive device; a barrier formed between the bonding pad and the photosensitive device; and a conductive layer formed on a sidewall of the integrated circuit chip and electrically connected to the bonding pad. The barrier layer blocks overflow of the adhesive layer into a region, on which the photosensitive device is formed, to improve yield for fabricating the integrated circuit package.

Abstract: Protuberances, having vertical and lateral dimensions less than the wavelength range of lights detectable by a photodiode, are formed at an optical interface between two layers having different refractive indices. The protuberances may be formed by employing self-assembling block copolymers that form an array of sublithographic features of a first polymeric block component within a matrix of a second polymeric block component. The pattern of the polymeric block component is transferred into a first optical layer to form an array of nanoscale protuberances. Alternately, conventional lithography may be employed to form protuberances having dimensions less than the wavelength of light. A second optical layer is formed directly on the protuberances of the first optical layer. The interface between the first and second optical layers has a graded refractive index, and provides high transmission of light with little reflection.