Abstract: A method for creating a nanostructure according to one embodiment includes depositing material in a template for forming an array of nanocables; removing only a portion of the template such that the template forms an insulating layer between the nanocables; and forming at least one layer over the nanocables. A nanostructure according to one embodiment includes a nanocable having a roughened outer surface and a solid core. A nanostructure according to one embodiment includes an array of nanocables each having a roughened outer surface and a solid core, the roughened outer surface including reflective cavities; and at least one layer formed over the roughened outer surfaces of the nanocables, the at least one layer creating a photovoltaically active p-n junction. Additional systems and methods are also presented.

Abstract: A method for forming a nanostructure according to one embodiment includes creating a hole in an insulating layer positioned over an electrically conductive layer; and forming a nanocable in the hole such that the nanocable extends through the hole in the insulating layer and protrudes therefrom, the nanocable being in communication with the electrically conductive layer. Additional systems and methods are also presented.

Abstract: Nanostructures and photovoltaic structures are disclosed. A nanostructure according to one embodiment includes an array of nanocables extending from a substrate, the nanocables in the array being characterized as having a spacing and surface texture defined by inner surfaces of voids of a template; an electrically insulating layer extending along the substrate; and at least one layer overlaying the nanocables. A nanostructure according to another embodiment includes a substrate; a portion of a template extending along the substrate, the template being electrically insulative; an array of nanocables extending from the template, portions of the nanocables protruding from the template being characterized as having a spacing, shape, and surface texture defined by previously-present inner surface of voids of the template; and at least one layer overlaying the nanocables.

Abstract: Nanostructures and photovoltaic structures are disclosed. A nanostructure according to one embodiment includes an array of nanocables extending from a substrate, the nanocables in the array being characterized as having a spacing and surface texture defined by inner surfaces of voids of a template; an electrically insulating layer extending along the substrate; and at least one layer overlaying the nanocables. A nanostructure according to another embodiment includes a substrate; a portion of a template extending along the substrate, the template being electrically insulative; an array of nanocables extending from the template, portions of the nanocables protruding from the template being characterized as having a spacing, shape and surface texture defined by previously-present inner surfaces of voids of the template; and at least one layer overlaying the nanocables.

Abstract: Nanostructures and photovoltaic structures are disclosed. A nanostructure according to one embodiment includes an array of nanocables extending from a substrate, the nanocables in the array being characterized as having a spacing and surface texture defined by inner surfaces of voids of a template; an electrically insulating layer extending along the substrate; and at least one layer overlaying the nanocables. A nanostructure according to another embodiment includes a substrate; a portion of a template extending along the substrate, the template being electrically insulative; an array of nanocables extending from the template, portions of the nanocables protruding from the template being characterized as having a spacing, shape and surface texture defined by previously-present inner surfaces of voids of the template; and at least one layer overlaying the nanocables.

Abstract: A method for creating a nanostructure according to one embodiment includes depositing material in a template for forming an array of nanocables; removing only a portion of the template such that the template forms an insulating layer between the nanocables; and forming at least one layer over the nanocables. A nanostructure according to one embodiment includes a nanocable having a roughened outer surface and a solid core. A nanostructure according to one embodiment includes an array of nanocables each having a roughened outer surface and a solid core, the roughened outer surface including reflective cavities; and at least one layer formed over the roughened outer surfaces of the nanocables, the at least one layer creating a photovoltaically active p-n junction. Additional systems and methods are also presented.

Abstract: Nanostructures and photovoltaic structures are disclosed. Method for creating nanostructures are also presented. A method according to one embodiment includes adding a template to a substrate; depositing conductive material in the template thereby forming an array of conductive nanocables on the substrate; removing at least part of the template; and depositing at least one layer of photovoltaic material on exposed portions of the conductive nanocables. A nanostructure according to one embodiment includes an array of nanocables extending from a substrate, the array of nanocables having physical characteristics of having been formed using an at least partially removed template; an insulating layer extending along the substrate; and at least one layer of photovoltaic material overlaying portions of the nanocables.

Abstract: A photovoltaic nanostructure according to one embodiment of the present invention includes an electrically conductive nanocable coupled to a first electrode, a second electrode extending along at least two sides of the nanocable, and a photovoltaically active p-n junction formed between the nanocable and the second electrode. A photovoltaic array according to one embodiment includes a plurality of photovoltaic nanostructures as recited above. Methods for forming nanostructures are also presented.

Abstract: A method for forming a nanostructure according to one embodiment includes creating a hole in an insulating layer positioned over an electrically conductive layer; and forming a nanocable in the hole such that the nanocable extends through the hole in the insulating layer and protrudes therefrom, the nanocable being in communication with the electrically conductive layer. Additional systems and methods are also presented.

Abstract: A photovoltaic nanostructure according to one embodiment of the present invention includes an electrically conductive nanocable coupled to a first electrode, a second electrode extending along at least two sides of the nanocable, and a photovoltaically active p-n junction formed between the nanocable and the second electrode. A photovoltaic array according to one embodiment includes a plurality of photovoltaic nanostructures as recited above. Methods for forming nanostructures are also presented.

Abstract: A fitting for tube and/or pipe includes two legs formed at a nominal included angle that is other than a right angle. An example would be a nominal included angle of about 2°±.5° from a right angle. A fitting is also provided that is drainable under the influence or force of gravity. Methods of forming such fittings are also provided including various combinations of steps of bending, cutting and welding.