Abstract: First and second solar panels are mounted in an operative position. Each panel includes an upward-facing photovoltaic surface and a downward-facing photovoltaic surface that are configured to photovoltaically generate electricity from light. The downward-facing photovoltaic surface is spaced above a reflective surface. The first and second panels are spaced apart in a first direction by a spacing distance that is about 25% to about 100% of the width of the first panel in the first direction. Some downwardly-directed light rays can strike the upward-facing photovoltaic surfaces of the panels. Other downwardly-directed light rays can pass between the first and second panels and be reflected upward by the reflective surface to strike the downward-facing photovoltaic surfaces of the panels.

Abstract: A solar assembly apparatus is provided that comprises one or more photovoltaic modules, a first end rail to which the first ends of the one or more photovoltaic modules are fixed and a first stiffening member to which the first end rail is attached. In some instances, the one or more photovoltaic modules are a plurality of electrically-interconnected elongated photovoltaic modules forming an array and each elongated photovoltaic module in the plurality of elongated photovoltaic modules is elongated along an axis and has a first end and a second end that are axially opposite each other. Furthermore, in such instances, each elongated photovoltaic module in the plurality of elongated photovoltaic modules has photovoltaic surface portions facing away from the axis in different directions to receive light to generate electricity.

Abstract: A scribing system comprising a mounting mechanism, stylus, and force generating mechanism is provided. The mounting mechanism is configured to rotate an elongated object in such a manner that the object is subjected to a bow effect wherein a middle portion of the object bends relative to the end portions of the object. The stylus is for scribing the object at a position x along the long dimension of the object while the mounting mechanism rotates the object. The force generating mechanism is connected to the stylus so that the stylus applies the same constant force to the elongated object regardless of the position x along the long dimension of the object that the stylus is positioned, while the mounting mechanism rotates the object and thereby subjects the object to the bow effect, thereby scribing the object.

Abstract: A support system for a solar panel comprises a plurality of legs configured to receive multiple solar panels. The legs each comprise a base, a plurality of shafts, and a support precipice. The support precipice is divided into two sides by a t-bar. The first side comprises a guiding wing to effectuate modular assembly of the support system. The second side comprises a beveled edge to effectuate secure coupling of a solar panel. The system is able to be assembled and disassembled without the use of tools or implements. The system is also movable.

Abstract: Methods and apparatus to facilitate the measurement of the amount of scattered electrons collected by an anti-fogging baffle arrangement are provided. For some embodiments, by affixing a lead to an electrically isolated (floating) portion of the baffle arrangement, the amount of scattered electrons collected thereby may be read out, for example, as a current signal. Thus, for such embodiments, the baffle arrangement may double as a detector, allowing an image of surface (e.g., a mask or substrate surface) to be generated.

Abstract: Methods for forming photovoltaic modules, and the photovoltaic modules produced by such methods are provided. A back-electrode layer is disposed on an elongated substrate. A first patterning is performed on the back-electrode layer using a laser scriber or a mechanical scriber. A semiconductor junction layer is disposed on top of the back-electrode layer. A second patterning is performed on the semiconductor junction layer using a mechanical scriber. A transparent conductor layer is disposed on top of the semiconductor junction layer. A third patterning is performed on the transparent conductor layer using a mechanical scriber thereby forming at least a first solar cell and a second solar cell, where the first solar cell and the second solar cell each comprise an isolated portion of the back-electrode layer, the semiconductor junction layer, and the transparent conductor layer.

Abstract: An apparatus is provided that has photovoltaic modules and a concentrator mechanically attached to a frame. Each module has (i) an outer shell defining an inner volume, (ii) a substrate in the inner volume, and (iii) a material on the substrate that converts light to electric energy. The outer shell allows light energy that strikes the shell to be directed towards the material. The concentrator has concentrator assemblies, each associated with a respective photovoltaic module. Each concentrator assembly comprises a first and second surface that form a concave structure that transmits light energy entering the concave structure to the associated photovoltaic module. The first and second surfaces each comprise substantially the shape of the involute of the particular photovoltaic module associated with the concentrator assembly. Each photovoltaic module extends from a first to a second support of the frame and is electrically coupled to an electric contact in the first support.

Abstract: A method for generating a flash. The method includes computing dose correction multipliers taking into account fogging scattering effects, backscattering effects and fast secondary scattering effects; and using the dose correction multipliers to generate the flash.

Abstract: A photovoltaic module comprising an elongated substrate in which at least a portion of the elongated substrate is rigid is provided. One or more solar cells are disposed on the elongated substrate and each comprise: (i) a back-electrode disposed on the elongated substrate, (ii) a semiconductor junction layer disposed on all or a portion of a surface of the back-electrode, and (iii) a transparent conductive layer, having a first refractive index, is disposed on all or a portion of a surface of the semiconductor junction. The photovoltaic module further comprises a filler material, having a second refractive index that is smaller or equal in value to the first refractive index, disposed on the transparent conductive layer of the one or more solar cells. The photovoltaic module further comprises a transparent casing disposed on the filler material thereby sealing the photovoltaic module.

Abstract: A shaped particle beam writing strategy can be used to write a pattern with a particle beam onto a substrate. The pattern comprises a circuit design that is fractured into a plurality of arbitrary polygons. The writing strategy comprises transforming and fracturing the arbitrary polygons into a plurality of restricted polygons, each restricted polygon being represented by a location coordinate, at least two dimension coordinates, and at least one external edge indicator. Thereafter, the restricted polygons are tiled into a set of tiles comprising interior tiles and external edge tiles. Flash data is assigned for each tile such that the interior tiles are assigned a first flash area and the external edge tiles are assigned a second flash area that is smaller than the first flash area. The flash data is arranged in a selected order to write the pattern with a modulated particle beam, such as an electron beam, on a substrate.

Abstract: A method for generating a charged particle beam flash. The method includes computing an array of dose correction multipliers, based, at least in part, on a resist sensitivity correction factor, and computing a displacement vector to account for placement effects, such as resist charging. The displacement vector is defined as {right arrow over (?)}c=dP{circle around (×)}{right arrow over (K)} , where {right arrow over (?)}c—represents the displacement vector, d represents the array of dose correction multipliers, P represents pattern exposure data, {circle around (×)} represents a mathematical convolution operation, and {right arrow over (K)} represents a Poisson kernel converted to a spatial domain. The method further includes using the displacement vector to modify position of the charged particle beam flash.

Abstract: A solar cell unit comprising a cylindrical shaped solar cell and a transparent tubular casing is provided. The tubular shaped solar cell comprises a back-electrode, a semiconductor junction circumferentially disposed on the back-electrode and a transparent conductive layer disposed on the semiconductor junction. The transparent tubular casing is circumferentially sealed onto the transparent conductive layer of the cylindrical shaped solar cell. A solar cell unit comprising a cylindrical shaped solar cell, a filler layer, and a transparent tubular casing is provided. The cylindrical shaped solar cell comprises a cylindrical substrate, a back-electrode circumferentially disposed on the cylindrical substrate, a semiconductor junction circumferentially disposed on the back-electrode, and a transparent conductive layer disposed on the semiconductor junction.

Abstract: A multifunction module for an electron beam column comprises upper and lower electrodes, and a central ring electrode. The upper and lower electrodes have multipoles and are capable of deflecting, or correcting an aberration of, an electron beam passing through the electrodes. A voltage can be applied to the central ring electrode independently of the voltages applied to the upper and lower electrodes to focus the electron beam on a substrate.

Abstract: A solar cell unit comprising a cylindrical shaped solar cell and a transparent tubular casing is provided. The tubular shaped solar cell comprises a back-electrode, a semiconductor junction circumferentially disposed on the back-electrode and a transparent conductive layer disposed on the semiconductor junction. The transparent tubular casing is circumferentially sealed onto the transparent conductive layer of the cylindrical shaped solar cell. A solar cell unit comprising a cylindrical shaped solar cell, a filler layer, and a transparent tubular casing is provided. The cylindrical shaped solar cell comprises a cylindrical substrate, a back-electrode circumferentially disposed on the cylindrical substrate, a semiconductor junction circumferentially disposed on the back-electrode, and a transparent conductive layer disposed on the semiconductor junction.

Abstract: A solar cell unit comprising a solar cell and an at least partially transparent casing that encases the solar cell. The solar cell includes a nonplanar substrate defining a length of the solar cell, wherein a length of the nonplanar substrate is at least three times longer than a width of the nonplanar substrate. A back-electrode is disposed around all or a portion of the nonplanar substrate, and extends along all or a portion of the length of the nonplanar substrate. A semiconductor junction is disposed on the back-electrode, and has first and second layers, each of which has an inorganic semiconductor. An at least partially transparent conductive layer is disposed on the semiconductor junction. Optionally, filler material is disposed on the transparent conductive layer, which can for example be a liquid or gel.

Abstract: A beam re-registration system and method for error correction of a particle or other beam are disclosed. The beam re-registration system and method may include a particle or other beam, a stage movable in relation to the particle beam, at least two servos for controlling movement of the stage, a fixed target or grid located on the stage, and a re-registration controller adapted to control the servos. The re-registration controller may attenuate high frequency signals and amplify low frequency signals, and may be a type 2 controller which accurately corrects a ramp disturbance.

Abstract: An electron beam column comprises a thermal field emission electron source to generate an electron beam, an electron beam blanker, a beam shaping module, and electron beam optics comprising a plurality of electron beam lenses. In one version, the optical parameters of the electron beam blanker, beam shaping module, and electron beam optics are set to achieve an acceptance semi-angle ? of from about ¼ to about 3 mrads, where the acceptance semi-angle ? is half the angle subtended by the electron beam at the writing plane. The beam-shaping module can also operate as a single lens using upper and lower projection lenses. A multifunction module for an electron beam column is also described.

Abstract: A system and method of determining shape and position corrections of a beam such as a particle or other beam used in a system such as a particle beam lithography. The method of providing corrected deflector voltages may include determining a voltage step value by subtracting a previous deflector voltage value with a current deflector voltage value; determining a plurality of correction values using the voltage step value and an exposure time for the current deflector voltage value; selecting a current voltage correction value from the plurality of correction values using the current deflector voltage value; and calculating a corrected deflector voltage value by adding the current voltage correction value to the current deflector voltage value.

Abstract: A photovoltaic assembly has elongated photovoltaic modules. The photovoltaic modules each have a substrate with a photovoltaic material disposed on the substrate. Each respective photovoltaic module lies in the concave structure of a corresponding concentrator assembly. The concentrator assemblies have surfaces made with reflective material that form such concave structures. The concentrator assemblies each transmit light to their corresponding photovoltaic module. The surfaces of each concentrator assembly are shaped at least in part as an involute of the surface of their corresponding photovoltaic modules, and do not exceed the height of the their corresponding module. A frame is provided having a first support and a second support, where the modules extend between the supports. The concentrator is mechanically attached to the frame. A substantial portion of light striking the concentrator is ultimately redirected to the modules without associated tracking and/or control devices.

Abstract: An apparatus for converting light energy into electric energy has a concentrator with at least a first and second wall. The walls are made at least in part of a material that reflects light. The concentrator has an opening defined by the walls, and is operable to admit light energy into an interior portion of the apparatus. An elongated photovoltaic module is disposed between the walls. The module has a substrate, and a photovoltaic covering disposed on the substrate. The module can generate electric energy from light energy that directly strikes the module and light energy redirected from the concentrator to the module. The walls are substantially the shape of an involute of the module. The walls are limited to the height of the topmost portion of the elongated photovoltaic module. The module is disposed upon or above a joining of the walls.