Patent application number | Description | Published |
20100086464 | NANOSTRUCTURE ARRAYS AND METHODS FOR FORMING SAME - A method for forming an array of elongated nanostructures includes in one embodiment, providing a member having a top surface, forming a plurality of pores in the member having an upper portion opening onto the top surface and a lower portion to form a template, and the upper portion being sized greater than the lower portion, introducing a catalyst in the lower portion of the plurality of pores and below the upper portion, and growing a plurality of elongated nanostructures from the catalyst spaced from the sides of the upper portion of the plurality of pores. | 04-08-2010 |
20100108132 | NANO-DEVICES AND METHODS OF MANUFACTURE THEREOF - Disclosed herein is a nanodevice. Disclosed herein too is a method of manufacturing a nanodevice. In one embodiment the nanodevice includes a first substrate; a second substrate; a nanowire; the nanowire contacting the first substrate and the second substrate; the nanowire comprising a metal, a semi-conductor or a combination thereof. | 05-06-2010 |
20100128439 | THERMAL MANAGEMENT SYSTEM WITH GRAPHENE-BASED THERMAL INTERFACE MATERIAL - A thermal management system includes graphene paper disposed between a heat source and a heat sink to transfer heat therebetween. The graphene paper is oriented such that the individual layers are substantially perpendicular to the plane of the heat source and the plane of the heat sink to maximize heat transfer. The heat source and the heat sink can be any physical structure that emits and absorbs thermal energy, respectively. The graphene paper may be bonded to the heat source and the heat sink using a bonding agent, such as a thermally conductive material, and the like. The graphene paper may be formed in several different configurations, such as a spring structure, and the like. | 05-27-2010 |
20100259823 | NANOSTRUCTURED ANTI-REFLECTION COATINGS AND ASSOCIATED METHODS AND DEVICES - An anti-reflection coating is described. The coating is disposed on a surface of a substrate. The anti-reflection coating includes an array of substantially transparent nanostructures having a primary axis substantially perpendicular to the surface of the substrate. The array of substantially transparent nanostructures is characterized by a graded refractive index. In some embodiments, each of the nanostructures has a substantially uniform cross-sectional area along the primary axis. Related methods and devices are also described. | 10-14-2010 |
20100261338 | Nanostructures, methods of depositing nanostructures and devices incorporating the same - A method for depositing nanowires is disclosed. The method includes depositing multiple nanowires onto a surface of a liquid. The method also includes partially compressing the nanowires. The method also includes dipping a substrate into the liquid. The method further includes pulling the substrate out of the liquid at a controlled speed. The method also includes transferring the nanowires onto the substrate parallel to a direction of the pulling. | 10-14-2010 |
20100283033 | CARBIDE NANOSTRUCTURES AND METHODS FOR MAKING SAME - A structure includes a substrate and a metallized carbon nano-structure extending from a portion of the substrate. In a method of making a metallized carbon nanostructure, at least one carbon structure formed on a substrate is placed in a furnace. A metallic vapor is applied to the carbon nanostructure at a preselected temperature for a preselected period of time so that a metallized nanostructure | 11-11-2010 |
20110012086 | NANOSTRUCTURED FUNCTIONAL COATINGS AND DEVICES - In one aspect of the present invention, an article including a nanostructured functional coating disposed on a substrate is described. The functional coating is characterized by both anti-reflection properties and down-converting properties. Related optoelectronic devices are also described. | 01-20-2011 |
20110146744 | PHOTOVOLTAIC CELL - A photovoltaic (PV) cell is disclosed. The PV cell comprises a plurality of ultrafine structures embedded within a photo-active absorber layer comprising a n-type compound semiconductor. | 06-23-2011 |
20110146788 | PHOTOVOLTAIC CELL - A photovoltaic (PV) cell is disclosed. The PV cell comprises, a plurality of ultrafine structures electrically coupled to, and embedded within, a polycrystalline photo-active absorber layer comprising a p-type compound semiconductor. | 06-23-2011 |
20110185728 | HIGH EFFICIENCY SOLAR THERMAL RECEIVER - In accordance with the present disclosure, a receiver panel is provided that includes multiple thermally conductive nanostructures. The thermally conductive nanostructures may be provided on a substrate that supports the multiple thermally conductive nanostructures. In one embodiment, the thermally conductive nanostructures may be substantially orthogonal with respect to the surface of the substrate. | 08-04-2011 |
20110269264 | METHODS FOR FABRICATION OF NANOWALL SOLAR CELLS AND OPTOELECTRONIC DEVICES - A photovoltaic device that includes a substrate and a nanowall structure disposed on the substrate surface. The device also includes at least one layer conformally deposited over the nanowall structure. The conformal layer(s) is at least a portion of a photoactive junction. A method for making a photovoltaic device includes generating a nanowall structure on a substrate surface and conformally depositing at least one layer over the nanowall structure thereby forming at least one photoactive junction. A solar panel includes at least one photovoltaic device based on a nanowall structure. The solar panel isolates such devices from its surrounding atmospheric environment and permits the generation of electrical power. Optoelectronic device may also incorporate a photovoltaic device based on a nanowall structure. | 11-03-2011 |
20120080066 | PHOTOVOLTAIC DEVICES - A photovoltaic device having a down-converting layer disposed on the device, is presented. The down-converting layer have a graded refractive index, wherein a value of refractive index at a first surface of the down-converting layer varies from a value of refractive index at a second surface of the layer. A photovoltaic module having a plurality of such photovoltaic devices is also presented. | 04-05-2012 |
20120080067 | PHOTOVOLTAIC DEVICES - A photovoltaic device including a composite down-converting layer disposed on the device, is presented. The composite down-converting layer includes down-converting material particles dispersed in a matrix. The size of the down-converting material particles is a function of a difference in respective refractive indices (Δn) of the down-converting material and the matrix such that: (i) for Δn less than about 0.05, the size of down-converting material particles is in a range from about 0.5 micron to about 10 microns, and (ii) for Δn at least about 0.05, the size of down-converting material particles is in a range from about 1 nanometer to about 500. A photovoltaic module having a plurality of such photovoltaic devices is also presented. | 04-05-2012 |
20120080070 | PHOTOVOLTAIC DEVICES - In one aspect of the present invention, a photovoltaic device having a down-converting layer is presented. The device includes a glass plate having a first surface and a second surface. The first surface is exposed to ambient radiation. A transparent conductive layer is disposed adjacent to the second surface of the glass plate. The device further includes a first type semiconductor layer disposed adjacent to the transparent conductive layer and a second type semiconductor layer disposed adjacent to the first type semiconductor layer. The down-converting layer is interposed between the second surface of the glass plate and the transparent conducting layer. The down-converting layer exhibits an effective refractive index that has a value between the respective refractive indices of the glass plate and the transparent conductive layer. A photovoltaic module having a plurality of such photovoltaic devices is also presented. | 04-05-2012 |
20120132277 | PHOTOVOLTAIC DEVICE AND METHOD FOR MAKING - An article, such as a solar cell or module, is presented. In one embodiment, the article includes a photovoltaically active region and a photovoltaically inactive region. A filler material is disposed in the inactive region; the filler material includes a reflective material configured to scatter at least 50% of light incident on the filler material. Another embodiment is an article that includes a photovoltaically active region and a photovoltaically inactive region. A filler material is disposed in the inactive region; the filler material includes a wavelength converting material. Other embodiments are described herein in which the filler material described above and disposed in the inactive region includes both the reflective material and the wavelength converting material. | 05-31-2012 |
20130153002 | SUPPORT INSERT FOR THIN FILM PHOTOVOLTAIC DEVICES AND THEIR METHODS OF MANUFACTURE - Photovoltaic devices that include a transparent substrate; a plurality of thin film layers defining a plurality of photovoltaic cells connected in series to each other on the transparent substrate; a first lead connected to one of the photovoltaic cells; and an encapsulation substrate on the plurality of thin film layers are provided. The encapsulation substrate defines a connection aperture through which the first lead extends. A support insert, which defines a plug portion and a flange, can be positioned within the connection aperture such that the flange extends over the back surface of the encapsulation substrate. The support insert can be configured to mechanically support the transparent substrate in an area opposite to the connection aperture while still enabling the first lead to extend through the connection aperture while the support insert is in place within the connection aperture. | 06-20-2013 |
20130153003 | ADHESIVE PLUG FOR THIN FILM PHOTOVOLTAIC DEVICES AND THEIR METHODS OF MANUFACTURE - Photovoltaic devices are provided that include: a transparent substrate; a plurality of thin film layers on the glass substrate; and, a first lead connected to one of the photovoltaic cells. An encapsulation substrate can be positioned on the plurality of thin film layers, and defines a connection aperture through which the first lead extends. The connection aperture generally has a perimeter defined by an aperture wall of the encapsulation substrate. An adhesive plug can be positioned within the connection aperture to mechanically support the transparent substrate in the area of the connection aperture. A back plate or back washer can also be bonded to the adhesive plug and/or back surface of the encapsulation substrate to help dissipate energy in and/or provide support to the encapsulation substrate. Methods are also provided for mechanically supporting a transparent substrate in an area opposite to a connection aperture defined in an encapsulation substrate. | 06-20-2013 |
20130153004 | JUNCTION BOX WITH A SUPPORT MEMBER FOR THIN FILM PHOTOVOLTAIC DEVICES AND THEIR METHODS OF MANUFACTURE - Photovoltaic devices are generally provided that can include, in one particular embodiment, a transparent substrate; a plurality of thin film layers defining a plurality of photovoltaic cells connected in series to each other on the transparent substrate; a first lead connected to one of the photovoltaic cells; and, an encapsulation substrate on the plurality of thin film layers. The encapsulation substrate can generally define a back surface and a connection aperture through which the first lead extends. A junction box can be positioned over the connection aperture and connected to the first lead. The junction box generally comprises a support member extending through the connection aperture to mechanically support the transparent substrate in an area opposite to the connection aperture. Methods and kits are also generally provided. | 06-20-2013 |
20130153029 | METHODS OF SUPPORTING A TRANSPARENT SUBSTRATE OF A THIN FILM PHOTOVOLTAIC DEVICE - Methods are generally provided for adhering a support insert within a connection aperture defined in an encapsulating substrate of a photovoltaic device that has a first lead. The connection aperture generally has a perimeter defined by an aperture wall of the encapsulating substrate. The method can, in one particular embodiment, include threading the first lead through the connection aperture; and positioning a support insert within the connection aperture such that the first lead is still able to extend through the connection aperture. The support insert can generally define a channel within its construction that extends from a channel opening in the support insert to an exit port. An adhesive composition can be injected into the channel opening such that a first amount of the adhesive composition flows through the channel and out of the exit port to bond the support insert within the connection aperture. | 06-20-2013 |