Abstract: Structures and methods for controlling phonon-scattering are provided. In some embodiments, a metamaterial structure comprises a light absorbing layer (16) capable of absorbing solar energy and converting the absorbed energy into electrical current, a first patterned layer (14) disposed on a light absorbing surface of the light absorbing layer (16), the first patterned layer (14) being configured to increase light absorption in the light absorbing layer (16), and a second patterned layer (60) disposed in proximity to the light absorbing layer (16), the second patterned layer (60) being configured to control phonon-scattering by storing or protecting the hot electron energy in the light absorbing layer (16).

Abstract: Super-transparent electrodes for photovoltaic applications are disclosed. In some embodiments, a photovoltaic cell (1) includes an absorber material (16) capable of absorbing solar energy and converting the absorbed energy into electrical current; a window electrode (10) disposed on a light-entry surface of the absorber material (16), the window electrode (10) comprising an anti-reflective coating (ARC) layer (12) and a metallic layer (13), and a rear electrode (18) disposed on a surface of the absorber material (16) in opposing relation to the window electrode (10), wherein the rear electrode (18) in combination with the window electrode (10) are configured to collect electrical current generated in the absorber material (16).

Abstract: Broadband metamaterial absorbers are disclosed. In some embodiments, a photovoltaic cell includes a light absorbing layer capable of absorbing solar energy and converting the absorbed energy into electrical current; a perforated conductive film disposed on a light absorbing surface of the light absorbing layer, the conductive film being configured to increase light absorption in the light absorbing layer; and a rear electrode disposed on a surface of the absorbing layer opposite to the light absorbing surface of the light absorbing layer, wherein the rear electrode and the conductive film are in electrical communication with the absorbing layer to collect electrical current generated in the light absorbing material.

Abstract: An apparatus and methods for solar conversion using nanoscale cometal structures are disclosed herein. The cometal structures may be coaxial and coplanar. A nanoscale optics apparatus for use as a solar cell comprises a plurality of nanoscale cometal structures each including a photovoltaic material located between a first electrical conductor and a second electrical conductor. A method of fabricating solar cells comprises preparing a plurality of nanoscale planar structures; coating a plurality of planar surfaces of the plurality of planar structures with a photovoltaic semiconductor while leaving space between the plurality of planar surfaces; and coating the photovoltaic semiconductor with an outer electrical conductor layer, wherein a portion of the outer electrical conductor layer is located between the planar structures to form coplanar structures.

Abstract: Nanoscopically thin photovoltaic junction solar cells are disclosed herein. In an embodiment, there is provided a photovoltaic film 100 that includes a p-doped region 102, an n-doped region 106, and an intrinsic region 104 positioned between the p-doped region 102 and the n-doped region 106, wherein an overall thickness of the photovoltaic film is between about 15 nm to about 30 nm so as to extract hot carriers excited across a band gap, wherein the extracted hot carriers are capable of resulting in an open circuit voltage, Voc, of the photovoltaic film that increases with optical frequency, and wherein the extracted hot carriers are capable of resulting in a total short-circuit current density, Jsc, between about 4 mA/cm2 and about 8 mA/cm2.

Abstract: An apparatus and methods for solar conversion using nanoscale cometal structures are disclosed herein. The cometal structures may be coaxial and coplanar. A nanoscale optics apparatus for use as a solar cell comprises a plurality of nanoscale cometal structures each including a photovoltaic material located between a first electrical conductor and a second electrical conductor. A method of fabricating solar cells comprises preparing a plurality of nanoscale planar structures; coating a plurality of planar surfaces of the plurality of planar structures with a photovoltaic semiconductor while leaving space between the plurality of planar surfaces; and coating the photovoltaic semiconductor with an outer electrical conductor layer, wherein a portion of the outer electrical conductor layer is located between the planar structures to form coplanar structures.

Abstract: An apparatus and methods for solar conversion using nanoscale cometal structures are disclosed herein. The cometal structures may be coaxial and coplanar. A nanoscale optics apparatus for use as a solar cell comprises a plurality of nanoscale cometal structures each including a photovoltaic material located between a first electrical conductor and a second electrical conductor. A method of fabricating solar cells comprises preparing a plurality of nanoscale planar structures; coating a plurality of planar surfaces of the plurality of planar structures with a photovoltaic semiconductor while leaving space between the plurality of planar surfaces; and coating the photovoltaic semiconductor with an outer electrical conductor layer, wherein a portion of the outer electrical conductor layer is located between the planar structures to form coplanar structures.

Abstract: An apparatus and methods for optical switching using nanoscale optics are disclosed herein. A nano-optics apparatus for use as an optical switch includes a metallic film having a top surface, a bottom surface and a plurality of cylindrical channels containing a dielectric material, the metallic film acting as an outer electrode; and an array of non-linear optical components penetrating the metallic film through the plurality of cylindrical channels, the array acting as an array of inner electrodes.

Abstract: An apparatus and methods for nanolithography using nanoscale optics are disclosed herein. Submicron-scale structures may be obtained using standard photolithography systems with a de-magnifying lens. A de-magnifying lens for use in a standard photolithography system includes a film having a top surface, a bottom surface and a plurality of cylindrical channels containing a dielectric material; and an array of carbon nanotubes penetrating the film through the plurality of cylindrical channels, wherein an image on the top surface of the film is converted into a de-magnified image on the bottom surface of the film by the carbon nanotubes.

Abstract: Nanoscale optical probes for use with nanoscale optical microscopy are disclosed herein. A nanoscale optical probe for use with a near-field scanning optical microscope includes an inner conductor having a top end, a bottom end, and a body; a dielectric material engaging the inner conductor; and an outer conductor engaging the dielectric material, wherein the inner conductor is longer at a tip surface of the probe than the dielectric material and the outer conductor.

Abstract: An apparatus and methods for manipulating light using nanoscale cometal structures are disclosed. A nanoscale optics apparatus for manipulating light includes a plurality of nanoscale cometal structures each comprising a dielectric material located between a first electrical conductor and a second electrical conductor. A method of fabricating a nanoscale optics apparatus for manipulating light includes preparing a plurality of nanoscale planar structures; coating a plurality of planar surfaces of the plurality of planar structures with a dielectric while leaving space between the plurality of planar surfaces; and coating the dielectric with an outer electrical conductor layer, wherein a portion of the outer electrical conductor layer is located between the planar structures to form coplanar structures.