Abstract: A photovoltaic cell may include a semiconductor base, a semiconductor mesa extending from the semiconductor base, a dielectric and a conductive material. The semiconductor mesa includes a top surface and a side wall, and a first portion of the dielectric is disposed on the top surface, a second portion of the dielectric is disposed on the side wall, and a third portion of the dielectric is disposed on the base. The conductive material is disposed on the top surface of the mesa and on the dielectric, and the conductive material covers the first portion of the dielectric, the second portion of the dielectric, and a portion of the third portion.

Abstract: Methods of counterdoping a solar cell, particularly an IBC solar cell are disclosed. One surface of a solar cell may require portions to be n-doped, while other portions are p-doped. Traditionally, a plurality of lithography and doping steps are required to achieve this desired configuration. In contrast, one lithography step can be eliminated by the use of a blanket doping of one conductivity and a mask patterned counterdoping process of the opposite conductivity. The areas dosed during the masked patterned doping receive a sufficient dose so as to completely reverse the effect of the blanket doping and achieve a conductivity that is opposite the blanket doping. In another embodiment, the counterdoping is performed by means of a direct patterning technique, thereby eliminating the remaining lithography step. Various methods of direct counterdoping processes are disclosed.

Abstract: A photodetector includes a first layer, a second layer and a plurality of nanowires established between the first and second layers. At least some of the plurality of nanowires have a bandgap that is different from a bandgap of at least some other of the plurality of nanowires.

Abstract: An embodiment of array of Geiger-mode avalanche photodiodes, wherein each photodiode is formed by a body of semiconductor material, having a first conductivity type and housing an anode region, of a second conductivity type, facing a top surface of the body, a cathode-contact region, having the first conductivity type and a higher doping level than the body, facing a bottom surface of the body, an insulation region extending through the body and insulating an active area from the rest of the body, the active area housing the anode region and the cathode-contact region. The insulation region is formed by a first mirror region of polycrystalline silicon, a second mirror region of metal material, and a channel-stopper region of dielectric material, surrounding the first and second mirror regions.

Abstract: An organic thin film solar cell comprises: positive and negative electrode layers; and an organic thin film layer disposed between the positive and negative electrode layers, the organic thin film layer including: a mixture of at least a first organic compound having a light-absorbing dye moiety and an electron-accepting second organic compound, in which the organic thin film layer further includes inorganic nanoparticles.

Abstract: Embodiments relate to an image sensor that may include transistors, a first dielectric, a crystalline semiconductor layer on and/or over the first dielectric, a photodiode, a dummy region, via contacts, and a second dielectric. A photodiode may be formed by implanting impurity ions into a crystalline semiconductor layer to correspond the pixel region. A dummy region may be formed in the crystalline semiconductor layer excepting a region for the photodiode. Via contacts may penetrate the dummy region, and may be connected to the first metal interconnections. A second dielectric may include a plurality of second metal interconnections on and/or over the crystalline semiconductor layer. The plurality of second metal interconnections may electrically connect the via contacts to the photodiode.

Abstract: Dimensional parameters of structures on a substrate are measured by providing a substrate with a structured surface. The structured surface includes a number of juxtaposed structural elements. A radiation source is configured to emit a beam of radiation having a wavelength in the infrared range. The substrate is illuminated with the beam of radiation. A signal corresponding to a part of the beam of radiation being transmitted through the substrate is detected. Dimensional parameters of the structural elements are calculated based on the transmitted beam signal.

Abstract: A photodiode includes a photosensitive element formed in a silicon semiconductor layer on an insulation layer. The photosensitive element includes a low concentration diffusion layer, a P-type high concentration diffusion layer, and an N-type high concentration diffusion layer. A method of producing the photodiode includes the steps of: forming an insulation material layer on the silicon semiconductor layer after the P-type impurity and the N-type impurity are implanted into the low concentration diffusion layer, the P-type high concentration diffusion layer, and the N-type high concentration diffusion layer; forming an opening portion in the insulation material layer in an area for forming the low concentration diffusion layer; and etching the silicon semiconductor layer in the area for forming the low concentration diffusion layer so that a thickness of the silicon semiconductor layer is reduced to a specific level.

Abstract: A system may include a solar cell, a support defining an opening over the solar cell and comprising a retention feature, and an optical element disposed within the opening. The optical element may include a location feature engaged with the retention feature of the support. In some aspects, the optical element includes an upper surface to receive concentrated light and a lower surface through which light passes to the solar cell, and the location feature is disposed between the upper surface and the lower surface. The retention feature may be a lip defining the opening over the solar cell, and/or the location feature may consist of a notch defined by an edge of the optical element.

Abstract: A method of forming a multijunction solar cell including an upper subcell, a middle subcell, and a lower subcell, the method including: providing first substrate for the epitaxial growth of semiconductor material; forming a first solar subcell on the substrate having a first band gap; forming a second solar subcell over the first solar subcell having a second band gap smaller than the first band gap; forming a barrier layer over the second subcell to reduce threading dislocations; forming a grading interlayer over the barrier layer, the grading interlayer having a third band gap greater than the second band gap; and forming a third solar subcell over the grading interlayer having a fourth band gap smaller than the second band gap such that the third subcell is lattice mismatched with respect to the second subcell.

Abstract: The present invention discloses a solar cell having a multi-layered structure that is used to generate, transport, and collect electric charges. The multi-layered nanostructure comprises a cathode, a conducting metal layer, a photo-active layer, a hole-transport layer, and an anode. The photo-active layer comprises a tree-like nanostructure array and a conjugate polymer filler. The tree-like nanostructure array is used as an electron acceptor while the conjugate polymer filler is as an electron donor. The tree-like nanostructure array comprises a trunk part and a branch part. The trunk part is formed in-situ on the surface of the conducting metal layer and is used to provide a long straight transport pathway to transport electrons. The large contact area between the branch part and the conjugate polymer filler provides electron-hole separation.

Abstract: Photodetectors and integrated circuits including photodetectors are disclosed. A photodetector in accordance with the present invention comprises a silicon-on-insulator (SOI) structure resident on a first substrate, the SOI structure comprising a passive waveguide, and a III-V structure bonded to the SOI structure, the III-V structure comprising a quantum well region, a hybrid waveguide, coupled to the quantum well region and the SOI structure adjacent to the passive waveguide, and a mesa, coupled to the quantum well region, wherein when light passes through the hybrid waveguide, the quantum well region detects the light and generates current based on the light detected.

Abstract: There is described a photovoltaic module (2) in the form of a multi-layer body with photovoltaic cells (21, 21i) arranged on a carrier layer (20) and having at least one organic polymer-based photoactive layer (213) arranged between a first and a second electrode layer (212, 215), which are electrically connected together in a series circuit. Hole blocker layers (214) and the electron blocker layers (212) in the series circuit of mutually following adjacent photovoltaic cells (21, 21i) are arranged in inverse succession relative to each other with respect to the carrier layer (20). Electrode layers (211, 215), which are electrically connected together by an electrically conducting connecting portion (22), of the mutually following adjacent photovoltaic cells (21, 211) are arranged in a common plane.

Abstract: The invention relates to a method for producing solar cells comprising at least one p-i-n layer sequence containing micro-crystalline layers with the aid of a PECVD method. Said method is characterised in that all layers of the p-i-n layer sequence are deposited in a single-chamber process. The electrodes are interspaced at a distance of between 5 and 15 mm and the gas is distributed by means of a shower-head gas inlet, which guarantees a homogeneous distribution of the gas over the substrate. SiH4 gas streams with values of between 0.01 and 3 sccm/cm2 are added with a process pressure of between 8 and 50 hPa. The heater temperature is set at between 50 and 280° C. and the HF output is between 0.2 and 2 watt/cm2. The H2 gas streams have values of between 0.3 and 30 sccm/cm2, in particular between 0.3 and 10 sccm/cm2.

Abstract: In a method of transforming light, an optical film for performing the method and a display device having the optical film, an optical film includes an anisotropic film, an isotropic film, a ?/4 phase difference film and a ?/2 phase difference film. The anisotropic film having a first refractive index with respect to a first ray and a second refractive index with respect to a second ray. A refractive index of the isotropic film is substantially identical to the first refractive index. The ?/4 phase difference film delays wavelengths of the first and second rays by about ?/4. The ?/2 phase difference film delays the wavelength of the second ray by about ?/2.

Abstract: A semiconductor radiation detector crystal is patterned by using a Q-switched laser to selectively remove material from a surface of said semiconductor radiation detector crystal, thus producing a groove in said surface that penetrates deeper than the thickness of a diffused layer on said surface.

Abstract: In accordance with the present invention, the method for manufacturing the solar cell includes: forming a dividing groove 8a that reaches a n-type single crystal silicon substrate 1 in a thickness direction of a photoelectric conversion part 10; and fracturing the photoelectric conversion part 10 along the dividing groove 8a, wherein the dividing groove 8a is formed continuously in an inside of an outer circumference portion of the photoelectric conversion part 10.

Abstract: In accordance with the present invention, the dividing grooves 8 are formed so as not to be parallel to cleavage planes of the semiconductor substrate 1, and the semiconductor substrate 1 is bent along the dividing grooves 8, whereby the semiconductor substrate 1 is fractured along the dividing grooves 8.

Abstract: The present invention, in one aspect, relates to a solar cell. In one embodiment, the solar cell includes an anode; an active organic layer comprising an electron-donating organic material and an electron-accepting organic material; a semiconducting layer formed between the anode and the active organic layer; and an electron-blocking layer (EBL) formed between the semiconducting layer and the active organic layer, where the EBL is transparent and adapted for blocking electron leakage from the active organic layer to the anode while transporting holes from the active organic layer to the anode.

Abstract: A solar panel apparatus and method. The apparatus has an optically transparent member comprising a predetermined thickness and an aperture surface region. The apparatus has a solar cell coupled to a portion of the optically transparent member. In a specific embodiment, the solar cell includes a transparent polymeric member and a plurality of photovoltaic regions provided within a portion of the transparent polymeric member. In a specific embodiment, the plurality of photovoltaic regions occupies at least about 10 percent of the aperture surface region of the transparent polymeric member and less than about 80% of the aperture surface region of the transparent polymeric member.

Abstract: An ambient light sensor includes a substrate, a buffer layer formed on the substrate, an absorption layer formed on the buffer layer for absorbing the visible light, and a filter layer formed on the absorption layer for filtering infrared light and high-energy photon insensitive to human eye. The absorption layer is a PIN junction having a compositional graded intrinsic layer. The peak wavelength of responsivity spectrum of the ambient light sensor is very close to that of human eye.

Abstract: Electrical devices comprised of nanowires are described, along with methods of their manufacture and use. The nanowires can be nanotubes and nanowires. The surface of the nanowires may be selectively functionalized. Nanodetector devices are described.

Abstract: A method of processing a substrate having first and second surfaces applies a first dopant in liquid form on the first surface of the substrate, and applies a second dopant in liquid form on the second surface of the substrate. The method then causes the first and second dopants to diffuse into the substrate.

Abstract: Provided are methods for making a device or device component by providing a multilayer structure having a plurality of functional layers and a plurality of release layers and releasing the functional layers from the multilayer structure by separating one or more of the release layers to generate a plurality of transferable structures. The transferable structures are printed onto a device substrate or device component supported by a device substrate. The methods and systems provide means for making high-quality and low-cost photovoltaic devices, transferable semiconductor structures, (opto-)electronic devices and device components.

Abstract: The invention is directed to a hermetically packaged and implantable integrated circuit for electronics that is made my producing streets in silicon-on-insulator chips that are subsequently coated with a selected electrically insulating thin film prior to completing the dicing process to yield an individual chip. A thin-layered circuit may transmit light, allowing a photodetector to respond to transmitted light to stimulate a retina, for example. Discrete electronic components may be placed in the three-dimensional street area of the integrated circuit package, yielding a completely integrated hermetic package that is implantable in living tissue.

Abstract: A first laser beam is emitted from a first laser oscillator in a pulsed manner at a high repetition frequency, and converged onto a substrate by a first intermediate optical system 2 so as to form a slit-like first beam spot. A second laser beam is emitted from a second laser beam oscillator in a pulsed manner to rise precedent to and fall subsequent to the first laser beam, and converged onto the substrate by a second intermediate optical system so as to form a second beam spot similar in configuration to the first beam spot and to contain the first beam spot. Crystallization of a semiconductor thin film on the substrate is carried out while the substrate or the first, second beam spots are moved. Thereby, the whole semiconductor thin film is formed into a crystal surface that has grown in one direction and free from ridges. Thus, the semiconductor thin film has an extremely flat surface, extremely few defects, large crystal grains and high throughput.

Abstract: Electrical devices comprised of nanowires are described, along with methods of their manufacture and use. The nanowires can be nanotubes and nanowires. The surface of the nanowires may be selectively functionalized. Nanodetector devices are described.