Abstract: A manufacturing method for manufacturing a light-sensing structure is provided. The manufacturing method includes the steps as follows. (a) A circuit layer is formed on an upper surface of a first substrate, wherein the first substrate includes at least one light-sensing device and the circuit layer includes at least one device structure and at least one release feature that is made of metal and is formed on part of the light-sensing device and the device structure. (b) A first light-filtering layer is formed on part of the circuit layer. (c) The release feature is removed by a wet-etching process.

Abstract: An image sensor includes an array of photo-sensing regions formed in a semiconductor substrate, a dielectric layer over the array of photo-sensing regions, and an array of microlenses formed in the dielectric layer. Each of the microlenses is center-aligned over one of the photo-sensing regions and has a truncated plano-convex shape. The microlenses have an index of refraction that is higher than the dielectric layer's refraction index. Each of the microlenses has a smooth circular top, a flat circular bottom, and a curved circumferential side convex towards the semiconductor substrate.

Abstract: An integrated optical receiver architecture may be used to couple light between a multi-mode fiber (MMF) and silicon chip which includes integration of a silicon de-multiplexer and a high-speed Ge photo-detector. The proposed architecture may be used for both parallel and wavelength division multiplexing (WDM) based optical links with a data rate of 25 Gb/s and beyond.

Abstract: A technique for fabricating an image sensor including a pixel circuitry region and a peripheral circuitry region includes fabricating front side components on a front side of the image sensor. A dopant layer is implanted on a backside of the image sensor. A anti-reflection layer is formed on the backside and covers a first portion of the dopant layer under the pixel circuitry region while exposing a second portion of the dopant layer under the peripheral circuitry region. The first portion of the dopant layer is laser annealed from the backside of the image sensor through the anti-reflection layer. The anti-reflection layer increases a temperature of the first portion of the dopant layer during the laser annealing.

Abstract: An optical semiconductor device is disclosed including an active region including an active layer and a diffraction grating having a ?/4 phase shift; passive waveguide regions each including a passive waveguide and a diffraction grating, disposed on the side of an emission facet and on the side of a rear facet sandwiching the active region between the passive waveguide regions, respectively; and an anti-reflection coating applied on the emission facet, wherein the passive waveguide region on the side of the emission facet has a length shorter than a length of the passive waveguide region on the side of the rear facet side.

Abstract: A color filter composition is provided. The color filter composition according to an exemplary embodiment includes a colorant A including a pigment or a dye, a binder resin B, an initiator C, and an assistance colorant D, wherein the initiator absorbs light of an ultraviolet wavelength, and the assistance colorant has a transmittance of more than 60% between about wavelengths 300 nm to 400 nm.

Abstract: A method of fabricating an image sensor and an image sensor thereof are provided. The method comprises: providing a mask; utilizing the mask at a first position to form a first group of micro-lenses having a first height on a first group of color filters of a color filter array on a pixel array; shifting the mask from the first position to a second position, wherein a distance between the first position and the second position is substantially equal to a width of a pixel of the pixel array; and utilizing the mask at the second position to form a second group of micro-lenses having a second height, different from the first height, on a second group of color filters of the color filter array.

Abstract: An optical sensor and a method for manufacturing the same are provided. The optical sensor includes a first photosensitive layer, a first charge carrier collecting element, a second photosensitive layer and a second charge carrier collecting element. The first photosensitive layer has a first light incident surface. The first charge carrier collecting element is disposed on a surface of the first photosensitive layer opposite to the first light incident surface of the first photosensitive layer. The second photosensitive layer is adjacent to the first photosensitive layer and has a second light incident surface. The second charge carrier collecting element is disposed on a surface of the second photosensitive layer opposite to the second light incident surface of the second photosensitive layer.

Abstract: A solar cell includes a base substrate having a first surface and a second surface opposite the first surface, the base substrate including a crystalline semiconductor and being configured to have solar light incident on the first surface, a doping pattern on a first portion of the second surface, the doping pattern including a first dopant, a first doping layer on a second portion of the second surface, the first doping layer including a second dopant, and the first and second portions of the second surface being different from each other, a first electrode on the first doping layer, and a second electrode on the doping pattern.

Abstract: An image sensor having a wave guide includes a semiconductor substrate formed with a photodiode and a peripheral circuit region; an anti-reflective layer formed on the semiconductor substrate; an insulation layer formed on the anti-reflective layer; a wiring layer formed on the insulation layer and connected to the semiconductor substrate; at least one interlayer dielectric stacked on the wiring layer; and a wave guide connected to the insulation layer by passing through the interlayer dielectric and the wiring layer which are formed over the photodiode.

Abstract: The absorption coefficient of silicon for infrared light is very low and most solar cells absorb very little of the infrared light energy in sunlight. Very thick cells of crystalline silicon can be used to increase the absorption of infrared light energy but the cost of thick crystalline cells is prohibitive. The present invention relates to the use of less expensive microcrystalline silicon solar cells and the use of backside texturing with diffusive scattering to give a very large increase in the absorption of infrared light. Backside texturing comprises a plurality of cusped features providing diffusive scattering. Constructing the solar cell with a smooth front surface results in multiple internal reflections, light trapping, and a large enhancement of the absorption of infrared solar energy.

Abstract: An entry slit panel for a push-broom hyperspectral camera is formed at least partly from a silicon wafer on which at least one companion sensor is fabricated, whereby the companion sensor is co-planar with the slit and detects light imaged on the panel but not on the slit. In embodiments, the companion sensor is a panchromatic sensor or a sensor that detects light outside the wavelength range of the camera. At least a region of the wafer is back-thinned to a thickness appropriate for a diffraction slit. The slit can be etched or laser cut through the thinned region, or formed between the wafer and another wafer or a conventional blade. The wafer can be back-coated or metalized to ensure its opacity across the camera's wavelength range. The companion sensor can be located relative to the slit to detect scene features immediately before or after the hyperspectral camera.

Abstract: A semiconductor device includes a device substrate having a front side and a back side corresponding to a front side and a back side of the semiconductor device, a metal feature formed on the front side of the device substrate, a bonding pad disposed on the back side of the semiconductor device and in electrical communication with the metal feature, and a shield structure disposed on the back side of the device substrate in which the shield structure and the bonding pad have different thicknesses relative to each other.

Abstract: Hybrid integration of vertical cavity surface emitting lasers (VCSELs) and/or other optical device components with silicon-based integrated circuits. A multitude of individual VCSELs or optical devices are processed on the surface of a compound semiconductor wafer and then transferred to a silicon-based integrated circuit. A specific sacrificial or removable separation layer is employed between the optical components and the mother semiconductor substrate. The transfer of the optical components to a carrier substrate is followed by the elimination of the sacrificial or separation layer and simultaneous removal of the mother substrate. This is followed by the attachment and interconnection of the optical components to the surface of, or embedded within the upper layers of, an integrated circuit, followed by the release of the components from the carrier substrate.

Abstract: According to one embodiment, a solid-state imaging device includes a semiconductor substrate of a first conductive type having a diffusion layer region provided on a surface thereof, a diffusion layer of the first conductive type for a pixel separation whose bottom portion is formed at the deepest position of the diffusion layer region in a pixel region, and a first deep diffusion layer of the first conductive type provided at the deepest position of the diffusion layer region in a first peripheral logic region for electrically connecting the semiconductor substrate and the first peripheral logic region and having a first concentration gradient equal to that of the diffusion layer for pixel separation.

Abstract: An integrated circuit for use, for example, in a backside illuminated imager device includes circuitry provided on a first side of a substrate, a first conductive pad connected to the circuitry and spaced from the first side of the substrate, a second conductive pad spaced from a second side of the substrate, an electrically conductive interconnect formed through the substrate to interconnect the first and second conductive pads, and a dielectric surrounding the second conductive pad and at least a portion of the interconnect. Methods of forming the integrated circuit are also described.

Abstract: It is possible to provide a camera module manufacturing method and a camera model which can improve performance of a camera module without complicating the manufacturing method. A light shield is formed on the side surface of each lens body (11) and a lens support member (12). Thus it is possible to obtain the diaphragm function for regulating the incident light flux transmission area and the function for suppressing the intrusion of stray light without using a separate diaphragm or a light shielding member.

Abstract: A semiconductor package includes: a sheet-like thin plate on which a semiconductor chip is secured; and a substrate including a wiring layer, disposed on the thin plate to extend over a part of a region surrounding the region where the semiconductor chip is secured or over the entire surrounding region, wherein the semiconductor chip and the substrate are electrically connected.

Abstract: A solid-state imaging device includes light receiving sections which are arranged in an image area on a semiconductor substrate at the same pitch and which light exiting from an imaging optical system enters, condensing lenses respectively arranged above the light receiving sections, and light shielding sections each of which is provided at one end of each of the light receiving sections. The condensing lenses are arranged in a peripheral portion in a first direction in the image area at a first pitch, and arranged in a peripheral portion in a second direction opposite the first direction at a second pitch which is smaller than the first pitch.

Abstract: A semiconductor device is provided which has a semiconductor element having an element forming surface at which a sensor element is formed, a back surface on the opposite side of the element forming surface, and a light transmissive protective member laminated over the element forming surface via an adhering portion. The semiconductor device includes a region exposed from the protective member at the outer peripheral end portion of the semiconductor element, when viewed from the protecting member in a laminating direction.

Abstract: A method for manufacturing a back contact solar cell according to the present invention comprises the following steps: preparing a p-type silicon substrate having a via hole; performing a diffusion process to form an emitter layer all over the surface of the substrate; forming an etching mask on the front surface and back surface of the substrate so as to selectively expose a portion of the substrate; etching a portion of the thickness of the substrate in the region exposed to the etching mask so as to remove an emitter layer in the relevant region; forming an anti-reflection film on the front surface of the substrate; and forming a grid electrode on the front surface of the substrate, and forming an n-electrode and a p-electrode on the back surface of the substrate.

Abstract: This description relates to a method for reducing CMOS Image Sensor (CIS) contact resistance, the CIS having a pixel array and a periphery. The method includes performing Physical Vapor Deposition (PVD) at a pixel contact hole area, annealing for silicide formation at the pixel contact hole area and performing contact filling. This description also relates to a method for reducing CMOS Image Sensor (CIS) contact resistance, the CIS having a pixel array and a periphery. The method includes implanting N+ or P+ for pixel contact plugs at a pixel contact hole area, performing Physical Vapor Deposition (PVD) at pixel contact hole area, annealing for silicide formation at the pixel contact hole area, performing contact filling and depositing a first metal film layer, wherein the first metal film layer links contact holes for a source, a drain, or a poly gate of a CMOS device.

Abstract: A solid-state imaging device includes: a photoelectric conversion device; a wire grid polarizer provided on the photoelectric conversion device; and a conductive film electrically connecting conductive layers provided in the photoelectric conversion device to the wire grid polarizer.

Abstract: A unit pixel of a CMOS image sensor include a photodiode that transforms light to an electric charge, and accumulates the electric charge, and a plurality of transistors that generate an electric signal based on the accumulated electric charge. The photodiode has a slope shape based on incident angle of the light in a semiconductor substrate.

Abstract: Optoelectronic device modules, arrays optoelectronic device modules and methods for fabricating optoelectronic device modules are disclosed. The device modules are made using a starting substrate having an insulator layer sandwiched between a bottom electrode made of a flexible bulk conductor and a conductive back plane. An active layer is disposed between the bottom electrode and a transparent conducting layer. One or more electrical contacts between the transparent conducting layer and the back plane are formed through the transparent conducting layer, the active layer, the flexible bulk conductor and the insulating layer. The electrical contacts are electrically isolated from the active layer, the bottom electrode and the insulating layer.

Abstract: A method for forming a chalcogenide semiconductor film and a photovoltaic device using the chalcogenide semiconductor film are disclosed. The method includes steps of coating a precursor solution to form a layer on a substrate and annealing the layer to form the chalcogenide semiconductor film. The precursor solution includes a solvent, metal chalcogenide nanoparticles and at least one of metal ions and metal complex ions which are distributed on surfaces of the metal chalcogenide nanoparticles. The metals of the metal chalcogenide nanoparticles, the metal ions and the metal complex ions are selected from a group consisted of group I, group II, group III and group IV elements of periodic table and include all metal elements of a chalcogenide semiconductor material.

Abstract: A method of forming contacts on a surface emitter of a silicon solar cell is provided. In the method an n-type diffusion of a surface is performed to form a doped emitter surface layer that has a sheet resistance of 10-40 ?/?. The emitter surface layer is then etched back to increase the sheet resistance of the emitter surface layer. Finally the surface is selectively plated. A method of fabrication of a silicon solar cell includes performing a front surface emitter diffusion of n-type dopant and then performing a dielectric deposition on the front surface by PECVD. The dielectric deposition comprises: a. growth of a thin silicon oxide; b. PECVD deposition of silicon nitride to achieve a silicon nitride. The silicon is then annealed to drive hydrogen from the silicon nitride layer into the silicon to passivate the silicon.

Abstract: Provided is a waveguide photodetector that may improve an operation speed and increase or maximize productivity. The waveguide photodetector includes a waveguide layer extending in a first direction, an absorption layer disposed on the waveguide layer, a first electrode disposed on the absorption layer, a second electrode disposed on the waveguide layer, the second electrode being spaced from the first electrode and the absorption layer in a second direction crossing the first direction, and at least one bridge electrically connecting the absorption layer to the second electrode.

Abstract: Double pass back side image (BSI) sensor systems and methods are disclosed. The BSI sensor may include a substrate, pixel reflectors formed on the substrate, and pixel photodiodes fabricated in the substrate, each pixel photodiode positioned over a respective one of the pixel reflectors. Micro-lenses may be formed over each photodiode and an image filter may be formed between the photodiodes and the micro-lenses. The pixels reflectors, photodiodes, micro-lenses, and filter may be formed using CMOS fabrication.

Abstract: Optically sensitive devices include a device comprising a first contact and a second contact, each having a work function, and an optically sensitive material between the first contact and the second contact. The optically sensitive material comprises a p-type semiconductor, and the optically sensitive material has a work function. Circuitry applies a bias voltage between the first contact and the second contact. The optically sensitive material has an electron lifetime that is greater than the electron transit time from the first contact to the second contact when the bias is applied between the first contact and the second contact. The first contact provides injection of electrons and blocking the extraction of holes. The interface between the first contact and the optically sensitive material provides a surface recombination velocity less than 1 cm/s.

Abstract: A method for fabricating a back-side illumination image sensor includes: implanting a first type of dopant into an epitaxial layer disposed over a first side of a substrate layer to form a first dopant layer in a first side of the epitaxial layer; adhering a carry layer over the first dopant layer for carrying the substrate layer; grinding a second side of the substrate layer for exposing a second side of the epitaxial layer; implanting the first type of dopant into the epitaxial layer from the second side of the epitaxial layer to form a second dopant layer in the second side of the epitaxial layer; forming at least one metal layer over the second dopant layer after forming the second dopant layer in the second side of the epitaxial layer; removing the carry layer; and forming a color filtering module over the first dopant layer.

Abstract: A photovoltaic element for conversion of electromagnetic radiation to electrical energy, having at least one first electrode, at least one n-semiconductive metal oxide, at least one dye for absorption of electromagnetic radiation, at least one organic hole conductor material, and at least one second electrode. The organic hole conductor material has an absorption spectrum which has a maximum in the ultraviolet or blue spectral region and, toward higher wavelengths, an absorption edge declining with wavelength and having a characteristic wavelength ?HTL. A decadic absorbance of the hole conductor material at a wavelength ?HTL within the declining absorption edge is 0.3. The photovoltaic element includes a longpass filter, which has a transmission edge rising with wavelength and having a characteristic wavelength ?LP. A transmission of the longpass filter at ?LP is 50% of a maximum transmission of the longpass filter, where ?HTL?30 nm??LP??HTL+30 nm.

Abstract: The present disclosure provides various embodiments of an image sensor device. An exemplary image sensor device includes an image sensing region disposed in a substrate; a multilayer interconnection structure disposed over the substrate; and a color filter formed in the multilayer interconnection structure and aligned with the image sensing region. The color filter has a length and a width, where the length is greater than the width.

Abstract: According to embodiments of the present invention, a photodetector is provided. The photodetector includes a substrate, a waveguide formed on a surface of the substrate, a first metal layer formed on a first side of the waveguide, wherein a first interface is defined between the waveguide and the first metal layer, and a silicide layer formed on a second side of the waveguide, wherein a second interface is defined between the waveguide and the silicide layer, and wherein the second side is opposite to the first side, and wherein at least one of the first interface and the second interface is at least substantially perpendicular to the surface of the substrate. Various embodiments further provide a method of forming the photodetector.

Abstract: An infrared (IR) radiation sensor device (27) includes an integrated circuit radiation sensor chip (1A) including first (7) and second (8) temperature-sensitive elements connected within a dielectric stack (3) of the chip, the first temperature-sensitive element (7) being more thermally insulated from a substrate (2) than the second temperature-sensitive element (8). Bonding pads (28A) on the chip (1) are coupled to the first and second temperature-sensitive elements. Bump conductors (28) are bonded to the bonding pads (28A), respectively, for physically and electrically connecting the radiation sensor chip (1) to corresponding mounting conductors (23A). A diffractive optical element (21,22,23,31,32 or 34) is integrated with a back surface (25) of the radiation sensor chip (1) to direct IR radiation toward the first temperature-sensitive element (7).

Abstract: A CMOS image sensor, in which an implantation process is performed on substrate under isolation structures each disposed between two adjacent photosensor cell structures. The implantation process is a destructive implantation to form lattice effects/trap centers. No defect repair process is carried out after the implantation process is performed. The implants can reside at the isolation structures or in the substrate under the isolation structures. Dark leakage and crosstalk are thus suppressed.

Abstract: Systems and methods for image sensing are disclosed. An image sensor includes a pixel having an active region and a plurality of reflective interfaces. The active region is configured to convert light absorbed by the pixel into an electrical signal. The plurality of reflective interfaces cause the light absorbed by the pixel to resonate within the active region. A method for converting absorbed light into an electrical signal with an image sensor includes absorbing light with the pixel of the image sensor, and reflecting the absorbed light with a plurality of reflective interfaces embedded in the pixel to generate a resonance within the active region.

Abstract: A semiconductor light-receiving includes: a substrate; a semiconductor light-receiving element that is provided on the substrate and has a first conductivity region and a second conductivity region; a first electrode electrically coupled to the first conductivity region; a second electrode electrically coupled to the second conductivity region; an insulating layer located on the second conductivity region; and a wiring that is located on the insulating layer and is electrically coupled to the first electrode, the wiring being elongated from the first electrode to a peripheral region of the semiconductor light-receiving element, the wiring having a region of first width and a region of second width narrower than the first width, the region of second width of the wiring being located on the second conductivity region.

Abstract: Disclosed herein is a stacked chip package including an image sensor including a recess formed on a surface thereof, and a digital signal processor chip that is positioned within the recess. Also disclosed herein is a method of fabricating a stacked chip package including the steps of forming a recess on a surface of an image sensor and positioning a digital signal processor in the recess of the image sensor.

Abstract: Pixel arrays are provided for image sensors that have barriers between color filters in an array of color filters. Color filter barriers may be formed from a transparent or semi-transparent material. Color filter barriers may be formed from a low refractive index material. Color filters may be etched and color filter barrier material may be formed in the etched regions of the color filters. If desired, a layer of color filter barrier material may be etched to form open regions and color filter material may be formed in the open regions of the color filter barrier material. An image sensor may be a front-side illuminated image sensor or a back-side illuminated image sensor.

Abstract: A solar cell module includes lower and upper substrates that are spaced apart from each other, a plurality of spaced apart solar cells, a plurality of gratings, and a light-transmissive encapsulant disposed between the lower and upper substrates to encapsulate the solar cells and the gratings. Each of the gratings has a grating center, and four reflecting regions formed around the grating center. Each of the reflecting regions has a light entrance face that has a plurality of valleys and peaks. The valleys and peaks alternate with each other along a direction from the grating center to a corresponding one of the corners of a corresponding one of the four adjacent solar cells.

Abstract: A solar cell includes a substrate layer and a plurality of nanowires grown outwardly from the substrate layer, at least two of the nanowires including a plurality of sub-cells. The solar cell also includes one or more light guiding layers formed of a transparent, light scattering material and filling the area between the plurality of nanowires.

Abstract: An image sensor includes: a substrate having a plurality of unit pixel region; a light receiving element formed in the substrate at the unit pixel region; an interlayer dielectric layer formed over the substrate; a lightguide formed in the interlayer dielectric layer for the light receiving element; a light focusing pattern formed over the interlayer dielectric layer at the pixel region; a planarization layer formed over the substrate and covering the light focusing pattern; and a lens formed over the planarization layer at the pixel region.

Abstract: According to one embodiment, a solid-state imaging device includes a semiconductor layer including first and second regions, a pixel portion provided in the first region, electrodes provided in the second region and configured to penetrate the semiconductor layer, and a guard ring provided in the second region and configured to penetrate the semiconductor layer and electrically isolate the pixel portion from the electrodes. An upper surface of the semiconductor layer in the second region is lower than an upper surface of the semiconductor layer in the first region.

Abstract: The finding that with a reasonable effort a layer thickness and/or refractive index variation may be acquired which realizes different internal optical path lengths for impinging radiation whereby fluctuation of spectral sensitivity of the photodetector is reduced is used to provide image sensors with a less fluctuating spectral sensitivity with respect to different wavelengths, or photodetectors with a small fluctuation of the spectral sensitivity from photodetector to photodetector with respect to defined wavelengths, with a reasonable effort.

Abstract: An electronic imager includes a pixel sensor array, a plurality elements of a color filter array containing pigments forming multiple color filter patterns on the pixel sensor array and a silylating agent formed between at least first and second elements of the multiple color filter patterns. A method for forming a color filter array on a pixel sensor array of an electronic imager includes forming a pixel sensor array on a substrate, forming a first color filter pattern on the pixel sensor array, depositing a silylating agent on the first color filter pattern, disposing elements of a second color filter pattern on the silylating agent between respective elements of the first color filter pattern and disposing elements of a third color filter pattern on the silylating agent between respective elements of the first color filter pattern.

Abstract: A method of fabricating a semiconductor optoelectronic structure is provided. First, a substrate is provided, and a waveguide is formed therein, and then a plurality of dielectric layers is formed on the waveguide. Next, a contact pad and a passivation layer are provided on the dielectric layers and a patterned mask layer is formed thereon. Last, an etching process is provided by using the patterned mask layer to expose the contact pad and remove a portion of the passivation layer and the dielectric layers to form a transformer.

Abstract: An image sensor pixel that includes a photoelectric conversion unit supported by a substrate and an insulator adjacent to the substrate. The pixel includes a cascaded light guide that is located within an opening of the insulator and extends above the insulator such that a portion of the cascaded light guide has an air interface. The air interface improves the internal reflection of the cascaded light guide. The cascaded light guide may include a self-aligned color filter having air-gaps between adjacent color filters. These characteristics of the light guide eliminate the need for a microlens. Additionally, an anti-reflection stack is interposed between the substrate and the light guide to reduce backward reflection from the image sensor. Two pixels of having different color filters may have a difference in the thickness of an anti-reflection film within the anti-reflection stack.

Abstract: A multilayer wafer structure containing a silicon layer that contains at least one waveguide, an insulating layer and a layer that is lattice compatible with Group III-V compounds, with the lattice compatible layer in contact with one face of the insulating layer, and the face of the insulating layer opposite the lattice compatible layer is in contact with the silicon layer. The silicon and insulating layers contain either or both of at least one continuous cavity filled with materials such as to constitute a photodetector zone, or at least one continuous cavity filled with materials such as to constitute a light source zone.

Abstract: A photoelectric conversion device is provided which is capable of improving the light condensation efficiency without substantially decreasing the sensitivity. The photoelectric conversion device has a first pattern provided above an element isolation region formed between adjacent two photoelectric conversion elements, a second pattern provided above the element isolation region and above the first pattern, and microlenses provided above the photoelectric conversion elements with the first and the second patterns provided therebetween. The photoelectric conversion device further has convex-shaped interlayer lenses in optical paths between the photoelectric conversion elements and the microlenses, the peak of each convex shape projecting in the direction from the electro-optical element to the microlens.