Abstract: Methods for forming a photovoltaic device include forming a buffer layer between a transparent electrode and a p-type layer. The buffer layer includes a work function that falls substantially in a middle of a barrier formed between the transparent electrode and the p-type layer to provide a greater resistance to light induced degradation. An intrinsic layer and an n-type layer are formed over the p-type layer.

Abstract: Methods for forming a photovoltaic device include adjusting a deposition power for depositing a buffer layer including germanium on a transparent electrode. The deposition power is configured to improve device efficiency. A p-type layer is formed on the buffer layer. An intrinsic layer and an n-type layer are formed over the p-type layer.

Abstract: In accordance with at least some embodiments of the present disclosure, a process for fabricating a light pipe (LP) is described. The process may be configured to construct a semiconductor structure having an etch-stop layer above a photodiode region and a first dielectric layer above the etch-stop layer. The process may be configured to etch a LP funnel through the first dielectric layer. And the process may be further configured to stop the etching of the LP funnel upon reaching and removing of the etch-stop layer.

Abstract: A backside illuminated imaging sensor includes a vertical stacked sensor that reduces cross talk by using different silicon layers to form photodiodes at separate levels within a stack (or separate stacks) to detect different colors. Blue light-, green light-, and red light-detection silicon layers are formed, with the blue light detection layer positioned closest to the backside of the sensor and the red light detection layer positioned farthest from the backside of the sensor. An anti-reflective coating (ARC) layer can be inserted in between the red and green light detection layers to reduce the optical cross talk captured by the red light detection layer. Amorphous polysilicon can be used to form the red light detection layer to boost the efficiency of detecting red light.

Abstract: An image sensor and a method of manufacturing the same are disclosed. A passivation layer on an interlayer dielectric layer has different thicknesses for neighboring pixels. Consequently, a phase of light incident on a pixel is out of phase with light incident on an adjacent pixel before it reaches a photodiode. As a result, diffraction of the incident light results in destructive interference between the pixels. Thus, cross talk between adjacent pixels can be prevented.

Abstract: A device includes a semiconductor substrate, which has a front side and a backside. A photo-sensitive device is disposed on the front side of the semiconductor substrate. A first and a second grid line are parallel to each other, and are disposed on the backside of, and overlying, the semiconductor substrate. A stacked layer includes an adhesion layer, a metal layer over the adhesion layer, and a high-refractive index layer over the metal layer. The adhesion layer, the metal layer, and the high-refractive index layer are substantially conformal, and extend on top surfaces and sidewalls of the first and the second grid lines.

Abstract: An image sensor having an array of pixels disposed in a substrate. The array of pixels includes photosensitive elements, a color filters, and waveguide walls. The waveguide walls are disposed in the color filters and surround portions of the color filters to form waveguides through the color filters. In some embodiments, metal walls may be coupled to the waveguide walls.

Abstract: In a semiconductor device, optical signal transfer capabilities are implemented on the basis of silicon-based monolithic opto-electronic components in combination with an appropriate waveguide. Thus, in complex circuitries, such as microprocessors and the like, superior performance may be obtained in terms of signal propagation delay, while at the same time thermal requirements may be less critical.

Abstract: A backside-illuminated active pixel sensor array in which crosstalk between adjacent pixels is prevented, a method of manufacturing the backside-illuminated active pixel sensor array, and a backside-illuminated image sensor including the backside-illuminated active pixel sensor array are provided. The backside-illuminated active pixel sensor array includes a semiconductor substrate of a first conductive type that comprises a front surface and a rear surface, light-receiving devices for generating charges in response to light incident via the rear surface, and one or more pixel isolating layers for forming boundaries between pixels by being disposed between the adjacent light-receiving devices, a wiring layer disposed on the front surface of the semiconductor substrate, and a light filter layer disposed on the rear surface of the semiconductor substrate, wherein a thickness of the one or more pixel isolating layers decreases from a point in the semiconductor substrate toward the rear surface.

Abstract: An image sensing device for receiving an incident light having an incident angle and photo signals formed thereby is provided. The image sensing device includes a micro prism and a micro lens for adjusting the incident angle and converging the incident light, respectively, a photo sensor for converting the photo signals into electronic signals, and an IC stacking layer for processing the electronic signals.

Abstract: A method for fabricating a backside-illuminated sensor includes providing a thin film semiconductor lamina having a first conductivity, and forming a doped region having a second conductivity within the lamina and at a front surface of the lamina. The lamina may be provided as a free-standing lamina, or may be provided as a semiconductor donor body from which the lamina is cleaved. An electrical connection is formed to the doped region. A temporary carrier is contacted to the back surface of the semiconductor and later removed. A backside-illuminated sensor is fabricated from the semiconductor lamina, in which the thickness of the semiconductor lamina remains substantially unchanged during the fabrication process.

Abstract: An apparatus includes a semiconductor layer, a dielectric layer, and a light prevention structure. The semiconductor layer has a front surface and a backside surface. The semiconductor layer includes a light sensing element and a periphery circuit region containing a light emitting element and not containing the light sensing element. The dielectric layer contacts at least a portion of the backside surface of the semiconductor layer. At least a portion of the light prevention structure is disposed between the light sensing element and the light emitting element. The light prevention structure is positioned to prevent light emitted by the light emitting element from reaching the light sensing element.

Abstract: An integrated circuit includes a substrate having a bonding pad region and a non-bonding pad region. A relatively large via, called a “big via,” is formed on the substrate in the bonding region. The big via has a first dimension in a top view toward the substrate. The integrated circuit also includes a plurality of vias formed on the substrate in the non-bonding region. The plurality of vias each have a second dimension in the top view, the second dimension being substantially less than the first dimension.

Abstract: Disclosed is an image sensor including a photo-sensing device, a color filter positioned on the photo-sensing device, a microlens positioned on the color filter, and an insulation layer positioned between the photo-sensing device and the color filter, and including a trench exposing the photo-sensing device and a filler filled in the trench. The filler has light transmittance of about 85% or more at a visible ray region, and a higher refractive index than the insulation layer. A method of manufacturing the image sensor is also provided.

Abstract: An improved reflectivity optical grid for image sensors. In an embodiment, a backside illuminated CIS device includes a semiconductor substrate having a pixel array area comprising a plurality of photosensors formed on a front side surface of the semiconductor substrate, each of the photosensors forming a pixel in the pixel array area; an optical grid material disposed over a backside surface of the semiconductor substrate, the optical grid material patterned to form an optical grid that bounds each of the pixels in the pixel array area and extending above the semiconductor substrate, the optical grid having sidewalls and a top portion; and a highly reflective coating formed over the optical grid, comprising a pure metal coating of a metal that is at least 99% pure, and a high-k dielectric coating over the pure metal coating that has a refractive index of greater than about 2.0. Methods are also disclosed.

Abstract: A method for reducing dark current in image sensors comprises providing a backside illuminated image sensor wafer, depositing a first passivation layer on a backside of the backside illuminated image sensor wafer, depositing a plasma enhanced passivation layer on the first passivation layer and depositing a second passivation layer on the plasma enhanced passivation layer.

Abstract: A method of an embodiment comprises forming a dielectric layer on a first side of an image sensor substrate, and exposing the dielectric layer to ultraviolet (UV) radiation. The image sensor substrate comprises a photo diode. A structure of an embodiment comprises a substrate and a charge-less dielectric. The substrate comprises a photo diode. The charge-less dielectric layer is on a first side of the substrate, and a total charge of the charge-less dielectric results in an average voltage drop of less than 0.2 V across the charge-less dielectric layer.

Abstract: A backside illuminated CMOS image sensor comprises an extended photo active region formed over a substrate using a first high energy ion implantation process and an isolation region formed over the substrate using a second high energy ion implantation process. The extended photo active region is enclosed by the isolation region, which has a same depth as the extended photo active region. The extended photo active region helps to increase the number of photons converted into electrons so as to improve quantum efficiency.

Abstract: A solid-state imaging device includes: a substrate; a wiring layer formed on a front side of the substrate in which pixels are formed; a surface electrode pad section formed in the wiring layer; a light-shielding film formed on a rear side of the substrate; a pad section base layer formed in the same layer as the light-shielding film; an on-chip lens layer formed over the light-shielding film and the pad section base layer in a side opposite from the substrate side; a back electrode pad section formed above the on-chip lens layer; a through-hole formed to penetrate the on-chip lens layer, the pad section base layer, and the substrate so as to expose the surface electrode pad section; and a through-electrode layer which is formed in the through-hole and connects the surface electrode pad section and the back electrode pad section.

Abstract: According to one embodiment, an image sensor, which may form part of a solid-state imaging device, such as a camera, comprises a photoelectric conversion element array, a light collection optical array, and a mirror unit that separates colors according to wavelength. Of the light that enters the image sensor, the colors are separated and at least a first colored ray is transmitted by the mirror unit to a dedicated photoelectric conversion element. The mirror unit reflects at least a second and third colored ray toward a laminate photoelectric conversion element for the second and third colored ray.

Abstract: According to one embodiment, an image sensor, which is a solid imaging device, includes a photoelectric conversion element array, a condensing optical element array, filter and reflector units, and a reflective unit. The reflective unit further reflects a light reflected by the filter and reflector units. The condensing optical element is arranged so that it contains a first photoelectric conversion element and a portion of a second or a third photoelectric conversion element, which are adjacent to the first photoelectric conversion element. The arrangement of the photoelectric conversion elements may comprise a cell. The reflective unit includes at least a first reflective surface and a second reflective surface. The first reflective surface is opposite to the filter and reflector units. The second reflective surface surrounds the filter and reflector units and the first reflective surface for each cell.

Abstract: According to one embodiment, a method for manufacturing a semiconductor device includes implanting impurity ions to a semiconductor layer in which an electrode is embedded; forming a light absorption film which absorbs laser light at a side of the electrode to which the laser light is irradiated; and activating the impurity ions by irradiating laser light to the semiconductor layer at which the light absorption film is formed in the forming.

Abstract: A semiconductor package includes a light transmissive cover having a conductive pattern, a substrate having a cavity, a semiconductor chip in the cavity of the substrate and electrically connected to the conductive pattern arranged on the light transmissive cover, and a blocking pattern between the light transmissive cover and the substrate.

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 device including a semiconductor substrate having a first surface and a second surface, the second surface being opposite to the first surface; a first passivation layer on the first surface; and a second passivation layer on the second surface, wherein each of the first passivation layer and the second passivation layer comprises an aluminum-based compound, is disclosed. A method of preparing a photovoltaic device, the method including: forming a semiconductor substrate to have a first surface and a second surface, the second surface being opposite to the first surface; forming an emitter region and a back surface field (BSF) region at the second surface; and forming a first passivation layer on the first surface and a second passivation layer on the second surface, wherein the first passivation layer and the second passivation layer are formed concurrently, is also disclosed.

Abstract: This description relates to a sensing product formed using a substrate with a plurality of epi-layers. At least a first epi-layer has a different composition than the composition of a second epi-layer. The sensing product optionally includes at least one radiation sensing element in the second epi-layer and optionally an interconnect structure over the second epi-layer. The sensing product is formed by removing the substrate and all epi-layers other than the second epi-layer. A light incident surface of the second epi-layer has a total thickness variation of less than about 0.15 ?m.

Abstract: A light receiving element comprises: a photodiode including an optical waveguide, an end surface of the optical waveguide being a light receiving surface of the photodiode; a signal electrode and a bias electrode on a common surface of the photodiode, the signal electrode being connected to an anode of the photodiode, the bias electrode being connected to a cathode of the photodiode; an insulating film on the bias electrode; and a metal electrode on the insulating film.

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: A chip module package structure applied to an optical input device includes a cover body, a first chip module, and a second chip module. The first chip module and the second chip module are respectively combined with the cover body, the first chip module has an optical source, and the second chip module has an optical sensor. Further, the optical source and the optical sensor form a preset relative spatial position relation, such that a part of light emitted by the optical source is received by the optical sensor after at least one reflection.

Abstract: A manufacturing method of a molded image sensor packaging structure with a predetermined focal length and the structure using the same are disclosed. The manufacturing method includes: providing a substrate; providing a sensor chip disposed on the substrate; providing a lens module set over the sensing area of the chip to form a semi-finished component; providing a mold that has an upper mold member with a buffer layer; disposing the semi-finished component into the mold to form a mold cavity therebetween; injecting a molding compound into the mold cavity; and after transfer molding the molding compound, opening the mold and performing a post mold cure process to cure the molding compound. The buffer layer can fill the air gap between the upper surface of the lens module and the upper mold member, thereby preventing the upper surface of the lens module from being polluted by the molding compound.

Abstract: The disclosure discloses a method for modifying the light absorption layer, including: (a) providing a substrate; (b) forming a light absorption layer on the substrate, wherein the light absorption layer includes a Group IB element, Group IIIA element and Group VIA element; (c) forming a slurry on the light absorption layer, wherein the slurry includes a Group VIA element; and (d) conducting a thermal process for the light absorption layer with the slurry.

Abstract: An image sensor device (and method of making same) that includes a substrate with front and back opposing surfaces, a plurality of photo detectors formed at the front surface, and a plurality of contact pads formed at the front surface which are electrically coupled to the photo detectors. A cavity is formed into the back surface. A plurality of secondary cavities are formed into a bottom surface of the cavity such that each secondary cavity is disposed over one of the photo detectors. Absorption compensation material having light absorption characteristics that differ from those of the substrate is disposed in the secondary cavities. A plurality of color filters are each disposed in the cavity or in one of the secondary cavities and over one of the photo detectors. The plurality of photo detectors are configured to produce electronic signals in response to light incident through the color filters.

Abstract: A solar cell system making method includes steps of making a round P-N junction preform by (a) stacking a P-type silicon layer and a N-type silicon layer on top of each other, and (b) forming a P-N junction near an interface between the P-type silicon layer and the N-type silicon layer; stacking the plurality of P-N junction preforms along a first direction and forming an electrode layer between each adjacent two of the plurality of P-N junction preforms; and forming a first collection electrode on a first of the plurality of P-N junction preforms and forming a second collection electrode on a last of the plurality of P-N junction preforms to form a cylindrical solar cell system. Further, a step of cutting the cylindrical solar cell system can be performed.

Abstract: A solid-state imaging device includes an imaging element, an external terminal, an insulating film, a through-electrode and a first electrode. The imaging element is formed on a first major surface of a semiconductor substrate. The external terminal is formed on a second major surface opposing the first major surface of the semiconductor substrate. The insulating film is formed in a through-hole formed in the semiconductor substrate. The through-electrode is formed on the insulating film in the through-hole and electrically connected to the external terminal. The first electrode is formed on the through-electrode on the first major surface of the semiconductor substrate. When viewed from a direction perpendicular to the first major surface of the semiconductor substrate, an outer shape with which the insulating film and the semiconductor substrate are in contact is larger than an outer shape of the first electrode.

Abstract: Embodiments provide a chip device package and a method for fabricating thereof. A semiconductor chip has a substrate. A supporting brick is separated from the substrate by a certain distance. A bonding pad having a surface is disposed across the substrate and the supporting brick. A bonding wire is electrically connected to the bonding pad.

Abstract: A solid-state imaging element includes a semiconductor substrate that has a light reception portion performing a photoelectric conversion of an incident light; an oxide layer that is formed on a surface of the semiconductor substrate; a light shielding layer that is formed on an upper layer further than the oxide layer via an adhesion layer; and an oxygen supply layer that is disposed between the oxide layer and the adhesion layer and is formed of a material which shows an oxidation enthalpy smaller than that of a material forming the oxide layer.

Abstract: A very high transmittance, back-illuminated, silicon-on-thin sapphire-on-fused silica wafer substrate design is presented for enabling high quantum efficiency and high resolution, silicon or silicon-germanium avalanche photodiode detector arrays with improved indirect optical crosstalk suppression. The wafer substrate incorporates a stacked antireflective bilayer between the sapphire and silicon, comprised of single crystal aluminum nitride (AlN) and non-stoichiometric, silicon rich, amorphous silicon nitride (a-SiNX<1.33), as well as a one quarter wavelength, magnesium fluoride (?/4-MgF2) back-side antireflective layer which is bonded to a fused silica wafer. The fused silica provides mechanical support, allowing the sapphire to be thinned to optimal thickness below 50 ?m, for improved optical transmittance and in conjunction with monolithic sapphire microlenses, suppression of indirect optical crosstalk from multiple reflections of APD emitted light.

Abstract: According to one embodiment, there is provided a solid-state image sensor including a photoelectric conversion layer, and a multilayer interference filter. The multilayer interference filter is arranged to conduct light of a particular color, of incident light, selectively to the photoelectric conversion layer. The multilayer interference filter has a laminate structure in which a first layer having a first refraction index and a second layer having a second refraction index are repeatedly laminated, and a third layer which is in contact with a lower surface of the laminate structure and has a third refraction index. A lowermost layer of the laminate structure is the second layer. The third refraction index is not equal to the first refraction index and is higher than the second refraction index.

Abstract: Embodiments of the invention are directed to integrated resonance detectors and arrays of integrated resonance detectors and to methods for making and using the integrated resonance detectors and arrays. Integrated resonance detectors comprise a substrate, a conducting mirror layer, an active layer, and a patterned conducting layer. Electromagnetic radiation is detected by transducing a specific resonance-induced field enhancement in the active layer to a detection current that is proportional to the incident irradiance.

Abstract: A semiconductor package and a method for manufacturing the same are provided. The semiconductor package includes a semiconductor chip having a first surface, a second surface and a pixel area, first adhesion patterns disposed on the first surface, second adhesion patterns disposed between the first adhesion patterns and the pixel area and disposed on the first surface, and external connection terminals disposed on the second surface, wherein the second adhesion patterns and the external connection terminals are disposed to overlap each other.

Abstract: A backside-illuminated image sensor and a fabricating method thereof are provided. The fabricating method includes the following steps. Firstly, a first substrate having a first side and a second side is provided, wherein a sensing structure is formed on the first side of the first substrate, and the sensing structure includes an alignment mark. Then, a second substrate is provided and bonded to the first side of the first substrate. Then, a light-transmissible structure is formed on the second side of the first substrate at a location corresponding to the alignment mark. Afterwards, an optical structure is positioned on the second side of the first substrate by referring to the light-transmissible structure and the alignment mark.

Abstract: In a photoelectric conversion apparatus including a charge holding portion, a part of an element isolation region contacting with a semiconductor region constituting the charge holding portion extends from a reference surface including the light receiving surface of a photoelectric conversion element into a semiconductor substrate at a level equal to or deeper than the depth of the semiconductor region in comparison with the semiconductor region.

Abstract: Provided is a high-speed and highly efficient semiconductor light-receiving element with small dependence on an incident light polarization direction. A semiconductor light-receiving element according to one aspect of the present invention includes a semiconductor layer including a light-absorbing layer 4, an MSM electrode 1 that is provided over the semiconductor layer, forms a Schottky junction with the semiconductor layer, and includes a slit-like opening, an anti-reflective film 2 formed over the semiconductor layer and the MSM electrode 1, and a Bragg reflection multilayer film 6 provided to a lower part of the semiconductor layer. The MSM electrode 1 includes a period capable of exciting surface plasmon to incident light of TM polarization, and obtains sufficient transmittance to the incident light of TE polarization.

Abstract: A system and method for image sensing is disclosed. An embodiment comprises a substrate with a pixel region, the substrate having a front side and a backside. A co-implant process is performed along the backside of the substrate opposing a photosensitive element positioned along the front side of the substrate. The co-implant process utilizes a first pre-amorphization implant process that creates a pre-amorphization region. A dopant is then implanted wherein the pre-amorphization region retards or reduces the diffusion or tailing of the dopants into the photosensitive region. An anti-reflective layer, a color filter, and a microlens may also be formed over the co-implant region.

Abstract: A backside illuminated CMOS image sensor comprises a photo active region formed over a substrate using a front side ion implantation process and an extended photo active region formed adjacent to the photo active region, wherein the extended photo active region is formed by using a backside ion implantation process. The backside illuminated CMOS image sensor may further comprise a laser annealed layer on the backside of the substrate. The extended photo active region helps to increase the number of photons converted into electrons so as to improve quantum efficiency.

Abstract: Methods of forming photo detectors are provided. The method includes providing a semiconductor layer on a substrate, forming a trench in the semiconductor layer, forming a first single crystalline layer and a second single crystalline layer using a selective single crystalline growth process in the trench, and patterning the first and second single crystalline layers and the semiconductor layer to form a first single crystalline pattern, a second single crystalline pattern and an optical waveguide.

Abstract: A photovoltaic device and a method of manufacturing the same, the device including a semiconductor substrate having a first surface and a second surface opposite to the first surface; a silicon nitride gap insulation layer on the first surface of the semiconductor substrate, a portion of the gap insulation layer proximate to the semiconductor substrate having a silicon:nitrogen ratio different from a silicon:nitrogen ratio in a portion of the gap insulation layer distal to the semiconductor substrate; a semiconductor structure on the first surface of the semiconductor substrate; and an electrode on the semiconductor structure.

Abstract: According to at least one embodiment of the semiconductor arrangement, the latter comprises a mounting side, at least one optoelectronic semiconductor chip with mutually opposing chip top and bottom, and at least one at least partially radiation-transmissive body with a body bottom, on which the semiconductor chip is mounted such that the chip top faces the body bottom. Moreover, the semiconductor arrangement comprises at least two electrical connection points for electrical contacting of the optoelectronic semiconductor chip, wherein the connection points do not project laterally beyond the body and with their side remote from the semiconductor chip delimit the semiconductor arrangement on the mounting side thereof.

Abstract: Implementations of a pixel including a substrate having a front side, a back side, and a photosensitive region formed on or near the front side, a dielectric layer formed on the front side, and a metal stack having a bottom side and a top side, the bottom side being on the dielectric layer. A light guide is formed in the dielectric layer and the metal stack and extending from the front side of the substrate to the top side of the metal stack, the light guide having a refractive index equal to or greater than the refractive index of the substrate. Other implementations are disclosed and claimed.

Abstract: An image sensor according to example embodiments may include a plurality of light-sensitive transparent oxide semiconductor layers as light-sensing layers. The light-sensing layers may be stacked in one unit pixel region.