Abstract: A photoelectric conversion device in accordance with an aspect of the present invention includes a thin-film transistor formed on a substrate, and a photo diode electrically connected to the thin-film transistor, wherein the photo diode includes a lower electrode connected to a drain electrode of the thin-film transistor, a photoelectric conversion layer formed on the lower electrode, an upper electrode formed from a transparent conductive film on the photoelectric conversion layer, the upper electrode being formed so as to be contained within an upper surface of the photoelectric conversion layer as viewed from a top, and a protective film (compound layer or the like) formed so as to protect a part of an upper surface of the photoelectric conversion layer located outside the upper electrode.

Abstract: A light receiving element 1 has a semiconductor substrate 101; a first mesa 11 provided over the semiconductor substrate 101, and having an active region and a first electrode (p-side electrode 111) provided over the active region; a second mesa 12 provided over the semiconductor substrate 101, and having a semiconductor layer and a second electrode (n-side electrode 121) provided over the semiconductor layer; and a third mesa 13 provided over the semiconductor substrate 101, and having a semiconductor layer, wherein the third mesa 13 is arranged so as to surround the first mesa 11.

Abstract: Methods for making a recessed color filter array for a semiconductor imager employing a sidewall spacer for reducing an edge effect from the array are disclosed. In one embodiment, a substrate is provided having an upper surface. Then, a recess is formed into the upper surface of the substrate. The recess has a bottom and a sidewall. Subsequently, a sidewall spacer is formed on the sidewall of the recess. A color resist is deposited into the recess after forming the sidewall spacer. In the embodiment, the sidewall spacer is formed of a material having a surface energy lower than that of a material defining the bottom of the recess. The color resist adheres less to the sidewall than to the bottom of the recess. Thus, the color resist does not conform to a shape of an edge portion of the recess, thereby reducing the edge effect.

Abstract: A method of manufacturing a backside illuminated image sensor includes providing a start material that has a layer of semiconductor material on a substrate. The layer of semiconductor material has a first face and a second, backside, face. The layer of semiconductor material is processed to form semiconductor devices in the layer adjacent the first face. At least a part of the substrate is removed to leave an exposed face. A passivation layer is formed on the exposed face, the passivation layer having negative fixed charges. The passivation layer can be Al2O3 (Sapphire). The passivation layer can have a thickness less than 5 ?m, advantageously less than 1 ?m, and more advantageously in the range 1 nm-150 nm. Another layer, or layers, can be provided on the passivation layer, including: an anti-reflective layer, a layer to improve passivation, a layer including a color filter pattern, a layer comprising a microlens.

Abstract: A method of manufacturing a solid state image pickup device including photoelectric conversion elements which are two-dimensionally arranged in a semiconductor substrate, and a color filter having a plurality of color filter patterns differing in color from each other and disposed on a surface of the semiconductor substrate according to the photoelectric conversion elements. The method includes successively subjecting a plurality of filter layers differing in color from each other to a patterning process to form the plurality of color filter patterns. At least one color filter pattern to be formed at first among the plurality of color filter patterns is formed by dry etching, and the rest of the plurality of the color filter pattern is formed by photolithography.

Abstract: The method for manufacturing a CMOS image sensor is employed to prevent bridge phenomenon between adjacent microlenses by employing openings between the microlenses. The method includes the steps of: preparing a semiconductor substrate including isolation regions and photodiodes therein obtained by a predetermined process; forming an interlayer dielectric (ILD), metal interconnections and a passivation layer formed on the semiconductor substrate in sequence; forming a color filter array having a plurality of color filters on the passivation layer; forming an over-coating layer (OCL) on the color filter array by using a positive photoresist or a negative photoresist; forming openings in the OCL by patterning the OCL by using a predetermined mask; and forming dome-typed microlenses on a patterned OCL.

Abstract: A color filter structure includes a substrate, in which a number of first pixel regions, a number of second pixel regions, and a number of third pixel regions are defined on the substrate. Each first pixel region includes a first stack layer; each second pixel region includes a second stack layer; and each third pixel region includes the first stack layer and the second stack layer.

Abstract: A method and device is disclosed for reducing noises in CMOS image sensors. An improved CMOS image sensor includes a light sensing structure surrounded by a support feature section. An active section of the light sensing structure is covered by no more than optically transparent materials. A light blocking portion includes a black light filter layer and an opaque layer covering the support feature section. The light blocking portion may also cover a peripheral portion of the light sensing structure. The method for forming the CMOS image sensors includes using film patterning and etching processes to selectively form the opaque layer where the light blocking portion is desired but not over the active section.

Abstract: In one embodiment, a method for manufacturing a semiconductor device includes following steps. An aperture is formed in an interlayer insulating film formed on a semiconductor wafer apart from an integrated circuit portion by etching process. The interlayer insulating film has a dielectric constant smaller than a silicon oxide film (SiO2), and the width of the aperture is larger than a dicing region. A resin layer is embedded in the aperture. An adhesive layer is formed on the interlayer insulating film and the resin layer. The semiconductor wafer is attached to a glass substrate using the adhesive layer by Face Down method. The semiconductor wafer, the resin layer, and the adhesive layer on a dicing region are cut by blade dicing. The semiconductor wafer and the glass substrate adhered to the semiconductor wafer are cut into pieces by the blade dicing of the glass substrate under the dicing region.

Abstract: An image sensor structure and a method for making the image sensor structure, for avoiding or mitigating lens shading effect. The image sensor structure includes a substrate, a sensor array disposed at the surface of the substrate, a dielectric layer covering the sensor array, wherein the dielectric layer includes a top surface having a dishing structure, an under layer filled into the dishing structure and having a refraction index greater than that of the dielectric layer, a filter array disposed on the under layer corresponding to the sensor array, and a microlens array disposed above the filter array. A top layer may be additionally disposed to cover the filter array and the microlens array is disposed on the top layer.

Abstract: A method for fabricating an optical device includes providing a semiconductor substrate having an element region and a peripheral region. The element region has an element array comprised of semiconductor elements formed therein. The peripheral region has at least a bonding pad electrically connected to the element array. A dielectric layer with an opening exposing the bonding pad is formed over the semiconductor substrate. A filter array and a planarizing layer are sequentially formed on the dielectric layer, and an organic layer is filled into the opening. An inorganic layer is formed on the planarizing layer and covers the organic layer. A portion of the inorganic layer and the organic layer are sequentially removed until the bonding pad is exposed. The organic layer protects the bonding pad from corrosion during the step removing the inorganic layer, and thus the fabrication yield is improved.

Abstract: There are provided a semiconductor device including a photo receiving region having high photosensitivity by forming an antireflection film capable of both decreasing a reflectance and lowering a surface level density, and a manufacturing method of the semiconductor device. The semiconductor device includes an antireflection film 8 comprised of a laminated film including a first insulating film 6 formed on the surface of a silicon substrate 1 and a second insulating film 7 having a refractive index different from that of the first insulating film 6 formed above the first insulating film in a light-receiving area 10 of a semiconductor photo receiving region PD, and in which the first insulating film 6 is comprised of a silicon oxide film formed by oxidizing silicon on the surface of the semiconductor photo receiving region PD. Further, the semiconductor photo receiving region PD has a configuration such that it may receive light having a wavelength 500 nm or less.

Abstract: A solid state imaging device includes: an imaging device substrate with an imaging device section formed on a first major surface side thereof; a backside interconnect electrode provided on a second major surface side of the imaging device substrate and electrically connected to the imaging device section, the second major surface being on the opposite side of the first major surface; a circuit substrate provided with a circuit substrate electrode opposed to the second major surface; a connecting portion electrically connecting the backside interconnect electrode to the circuit substrate electrode; and a light shielding layer provided coplanar with the backside interconnect electrode or on the circuit substrate side of the backside interconnect electrode.

Abstract: Image sensor devices and methods for fabricating the same are provided. An exemplary embodiment of an image sensor device comprises a support substrate. A passivation structure is formed over the support substrate. An interconnect structure is formed over the passivation structure. A first semiconductor layer is formed over the interconnect structure, having a first and second surfaces, wherein the first and second surfaces are opposing surfaces. At least one light-sensing device is formed over/in the first semiconductor layer from a first surface thereof. A color filter layer is formed over the first semiconductor layer from a second surface thereof. At least one micro lens is formed over the color filter layer.

Abstract: An imager having layers of light trapping material to reduce optical crosstalk and a method of forming the same.

Abstract: A photo detector device comprising a first layer comprising a first material, and a second layer arranged adjacent to the first layer, the second layer comprising strained silicon, wherein the second layer further comprises a light absorption region located substantially within the strained silicon, wherein the first or the second layer is arranged on a substrate.

Abstract: An image sensor includes a semiconductor layer, and first and second photoelectric converting units including first and second impurity regions in the semiconductor layer that are spaced apart from each other and that are at about an equal depth in the semiconductor layer, each of the impurity regions including an upper region and a lower region. A width of the lower region of the first impurity region may be larger than a width of the lower region of the second impurity region, and widths of upper regions of the first and second impurity regions are equal.

Abstract: An image sensor and a method for manufacturing the same are provided. The image sensor comprises at least one unit pixel, an interlayer dielectric, a color filter, a planarization layer, and a microlens. The microlens has a smooth surface after performing a plasma treatment process.

Abstract: An analytical system-on-a-chip can be used as an analytical imaging device, for example, for detecting the presence of a chemical compound. A layer of analytical material is formed on a transparent layer overlying a solid state image sensor. The analytical material can react in known ways with at least one reactant to block light or to allow light to pass through to the array. The underlying sensor array, in turn, can process the presence, absence or amount of light into a digitized signal output. The system-on-a-chip may also include software that can detect and analyze the output signals of the device.

Abstract: A solid state imaging device having a back-illuminated type structure in which a lens is formed on the back side of a silicon layer with a light-receiving sensor portion being formed thereon. Insulating layers are buried into the silicon layer around an image pickup region, with the insulating layer being buried around a contact layer that connects an electrode layer of a pad portion and an interconnection layer of the surface side. A method of manufacturing such a solid-state imaging device is also provided.

Abstract: A two-color radiation detector includes a mesa-type multi-layered mercury-cadmium-telluride detector structure monolithically integrated on a substrate. The detector is responsive to two discrete wavelength ranges separated by a wavelength range to which the detector is not responsive. The detector further includes two contact points deposited on the layer disposed furthest away from the entry point of the radiation, the contact points being isolated with respect to each other by a trench disposed within the layer.

Abstract: An active pixel sensor in a p-type semiconductor body includes an n-type common node formed below a pinning region. A plurality of n-type blue detectors more lightly doped than the common node are disposed below pinning regions and are spaced apart from the common node forming channels below blue color-select gates. A buried green photocollector is coupled to the surface through a first deep contact spaced apart from the common node forming a channel below a green color-select gate. A red photocollector buried deeper than the green photocollector is coupled to the surface through a second deep contact spaced apart from the common node forming a channel below a red color-select gate. A reset-transistor has a source disposed over and in contact with the common node. A source-follower transistor has gate coupled to the common node, a drain coupled to a power-supply node, and a source forming a pixel-sensor output.

Abstract: An image sensor formed using a method for manufacturing a planar layer in a process for forming microlenses may be used in a complementary metal oxide semiconductor (CMOS) image sensor. Embodiments provide a planar layer that can improve the operation performance of an image sensor, a manufacturing method thereof, and the image sensor including the planar layer. Embodiments relate to a planar layer located under microlenses, the planar layer including valleys of patterns having a predetermined size, which may eliminate optical cross talk between adjacent pixels.

Abstract: An object is to provide a photoelectric conversion element having a side surface with different taper angles by conducting etching of a photoelectric conversion layer step-by-step. A pin photodiode has a high response speed compared with a pn photodiode but has a disadvantage of large dark current. One cause of the dark current is considered to be conduction through an etching residue which is generated in etching and deposited on a side surface of the photoelectric conversion layer. Leakage current of the photoelectric conversion element is reduced by forming a structure in which a side surface has two different tapered shapes, which conventionally has a uniform surface, so that the photoelectric conversion layer has a side surface of a p-layer and a side surface of an n-layer, which are not in the same plane.

Abstract: Provision of a solid-state imaging device of a planarized structure with reduced dark currents, allowing for high sensitivities over a wide wavelength band ranging from visible wavelengths to near-infrared wavelengths, and a fabrication method of the same.

Abstract: A backside illuminated image sensor includes an isolation structure passing through a substrate, a sensor element formed overlying the front surface of the substrate, and a color filter formed overlying the back surface of the substrate.

Abstract: A method for forming a color filter is provided. A substrate having a passivation layer thereon is provided. The passivation layer has at least one trench therein within a peripheral region of the substrate. A first color filter layer is formed over the passivation layer to fill the trench by performing a first spin-on coating process with a first spin rate. Thereafter, the first color filter layer is patterned so as to form a plurality of first color filter blocks in a display region of the substrate and expose a portion of the passivation layer. A second color filter layer is formed over the passivation layer by performing a second spin-on coating process with a second spin rate, which is larger than the first spin rate. Next, the second color filter layer is patterned to form a plurality of second color filter blocks between the first color filter blocks respectively.

Abstract: A semiconductor device, includes: a semiconductor substrate including a first surface and a second surface which are opposite to one another; a light receiving portion provided at the first surface of the semiconductor substrate; and an optical transparent protective member so as to cover and to be adjacent to the first surface or the second surface of the semiconductor substrate; wherein a plurality of depressed portions are formed at the optical transparent protective member so as to be opposite to the light receiving portion.

Abstract: A light emitting diode package structure having a heat-resistant cover and a method of manufacturing the same include a base, a light emitting diode chip, a plastic shell, and a packaging material. The plastic shell is in the shape of a bowl and has an injection hole thereon. After the light emitting diode chip is installed onto the base, the plastic shell is covered onto the base to fully and air-tightly seal the light emitting diode chip, and the packaging material is injected into the plastic shell through the injection hole until the plastic shell is filled up with the packaging material to form a packaging cover, and finally the plastic shell is removed to complete the LED package structure.

Abstract: Provided is a method of fabricating a semiconductor device. The method includes providing a device substrate having a front side, a back side, and a first edge portion, forming a material layer over a portion of the front side of the device substrate, trimming the first edge portion, removing the material layer, bonding the front side of the device substrate to a carrier substrate, thinning the device substrate from the back side, and trimming a second edge portion of the thinned device substrate.

Abstract: Embodiments relate to a semiconductor device for an image sensor method of fabricating a semiconductor device for an image sensor having a micro lens. According to embodiments, the method may include forming a lower insulating film having cavities on a substrate, forming an upper insulating film having cavities on the lower insulating film, forming a protective insulating film having metal films on the upper insulating film, forming a number of color filters having a specified pattern on the protective insulating film, forming a planarization layer having a specified curvature on the color filters to bury the color filters in the planarization layer, and forming a number of micro lenses on the planarization layer at respective positions corresponding to the color filters.

Abstract: The present disclosure provides an image sensor semiconductor device. The semiconductor device includes a sensor element disposed in a semiconductor substrate; an inter-level dielectric (ILD) disposed on the semiconductor substrate; and a trench disposed in the ILD, overlying and enclosing the sensor element, and filled with a first dielectric material.

Abstract: Provided is a solid-state CMOS image sensor, specifically a CMOS image sensor pixel that has stacked photo-sites, high sensitivity, and low dark current. In an image sensor including an array of pixels, each pixel includes: a standard photo-sensing and charge storage region formed in a first region under a surface portion of a substrate and collecting photo-generated carriers; a second charge storage region formed adjacent to the surface portion of the substrate and separated from the standard photo-sensing and charge storage region; and a potential barrier formed between the first region and a second region underneath the first region and diverting the photo-generated carriers from the second region to the second charge storage region.

Abstract: A solid-state imaging element includes a semiconductor substrate formed with a valid pixel section including a plurality of photodetector sections, spacers formed on the valid pixel section, a transparent adhesive filling gaps among the spacers, and a transparent substrate which is bonded onto the spacers using the transparent adhesive and covers the valid pixel section when viewed in plan. Electrode pad sections are formed in a region of the semiconductor substrate located outside the valid pixel section.

Abstract: A method for manufacturing a color image pickup device including a pixel group in which a plurality of pixels each having a photoelectric conversion element and a color filter are arranged includes the steps of generating a random array pattern in which color filters of at least one color component are randomly arranged for an arbitrary pixel position, so that the occurrence frequency of color filters of a color component in a region having a predetermined size including the arbitrary pixel position is within a desired error range, generating a regular array pattern in which color filters of at least one color component are regularly arranged, and generating a color filter pattern by compositing in a regular manner the random array pattern generated in the random array generating step and the regular array pattern generated in the regular array generating step.

Abstract: A photoelectric conversion device comprises a semiconductor substrate and a multilayer wiring structure, wherein the multilayer wiring structure includes a first wiring layer which serves as a top wiring layer in an effective region and contains aluminum as a principal component, a first insulation film arranged in the effective region and an light-shielded region so as to cover the first wiring layer, and a second wiring layer which serves as a top wiring layer arranged on the first insulation film in the light-shielded region and contains aluminum as a principal component, and wherein the first insulation film has, in the effective region, a first portion which is positioned above the photoelectric conversion unit, and the first portion functions as at least a part of an interlayer lens.

Abstract: A solid-state imaging device includes: photoelectric conversion elements disposed on an imaging surface of a substrate, receiving light incident on a light receiving surface and performing photoelectric conversion to produce a signal charge; electrodes interposed between the photoelectric conversion elements; and light blocking portions provided above the electrodes and interposed between the photoelectric conversion elements. The light blocking portions include an electrode light blocking portion formed to cover the corresponding electrode, and a pixel isolation and light blocking portion protruding convexly from the upper surface of the electrode light blocking portion. The photoelectric conversion elements are arranged at first pitches on the imaging surface. The electrode light blocking portions and the pixel isolation and light blocking portions in the light blocking portions are arranged at second and third pitches, respectively, on the imaging surface.

Abstract: In a solid-state imaging device including an on-chip microlens and a light-receiving part to receive incident light condensed by the on-chip microlens, an optical waveguide extending from an undersurface part of the microlens to the light-receiving part and for guiding the incident light condensed by the microlens to the light-receiving part is formed to be integrated with the microlens. By this, since the incident light condensed by the microlens is incident on the light-receiving part with little loss, the sensitivity is improved.

Abstract: A package structure is described. A light emitting element and a light sensing element are disposed on a substrate, and are both wrapped by a package layer. Meanwhile, the light emitting element and the light sensing element are separated by a trench of the package layer, such that lights generated by the light emitting element are blocked, thereby reducing the noise interference on the light sensing element and improving the sensing precision of the light sensing element.

Abstract: A solid-state imaging device includes a color filter that selectively transmits incoming light. The color filter includes two ?/4 multilayer films, and an insulation layer sandwiched between the two ?/4 multilayer films. Here, each of the ?/4 multilayer films is constituted by a plurality of dielectric layers, and the optical thickness of the insulation layer is not ?/4. Since this color filter has a smaller thickness, the solid-state imaging device has a smaller size.

Abstract: An optical device according to an aspect of the present invention includes: a semiconductor substrate layer including a plurality of elements; at least one optical component which is formed at the first principal surface side of the semiconductor substrate layer and transmits incident light of desired wavelength; and an interconnect layer formed on second principal surface of the semiconductor substrate layer. In the semiconductor substrate layer, (i) a photoelectric conversion element region is formed at a position corresponding to the at least one optical component, and (ii) at least one element among the plurality of elements is formed near the second principal surface. At least a part of the at least one optical component is formed as a part of the semiconductor substrate layer, and the interconnect layer includes the conductive material electrically connected to the photoelectric conversion element region and the at least one element.

Abstract: A graded order-sorting filter for hyperspectral imagers and methods of making the same are provided. The graded order-sorting filter includes a substrate wafer having a first side and a second side and is formed of a material that is substantially transparent to light photons. The graded order-sorting filter also includes an absorption filter deposited outwardly from the first side of the substrate wafer. The absorption filter is tapered along a taper direction and formed of a graded composition semiconductor material with a bandgap graded to decrease outwardly from the substrate wafer and/or graded along the taper direction. The graded composition semiconductor material is substantially transparent to the light photons for photon energies substantially less than the bandgap. The above filter can also be aligned to a two-dimensional array of pixels to form a hyperspectral imager.

Abstract: A back side illumination image sensor according to an embodiment includes: a photosensitive device and a readout circuit on the front side of a first substrate; an interlayer dielectric layer on the front side of the first substrate; a metal line on the interlayer dielectric layer; a pad having a step on the interlayer dielectric layer; and a second substrate bonded with the front side of the first substrate over the interlayer dielectric layer, metal line, and pad.

Abstract: Provided are a CMOS image sensor and a fabricating method thereof. The CMOS image sensor includes a device isolation layer, a plurality of photodiode regions, an interlayer insulating layer, a refracting layer, a planarizing layer, a color filter layer, and a plurality of microlenses. The refracting layer, with a higher refractive index than that of the interlayer insulating layer, is formed through the interlayer insulating layer on portions of the device isolation layer, to divide the interlayer insulating layer and give the divided portions thereof the characteristics of a waveguide.

Abstract: An image sensor includes one or more ultraviolet (UV) light filter layers disposed between an insulating layer and a color filter array (CFA) layer. The one or more UV light filter layers reflect or absorb UV light while transmitting visible light.

Abstract: A CMOS image sensor and a method for manufacturing the same improve light-receiving efficiency and maintain a margin in the design of a metal line. The CMOS image sensor includes a transparent substrate including an active area having a photodiode region and a transistor region and a field area for isolation of the active area, a p-type semiconductor layer on the transparent substrate, a photodiode in the p-type semiconductor layer corresponding to the photodiode region, and a plurality of transistors in the p-type semiconductor layer corresponding to the transistor region.

Abstract: A method for forming microlenses of different curvatures is described, wherein a substrate having at least a first and a second areas different in height is provided. A transparent photosensitive layer having a planar surface is formed on the substrate and then patterned into at least two islands of different thicknesses respectively over the first area and the second area. The at least two islands are heated and softened to form at least two microlenses of different curvatures respectively over the first area and the second area, wherein the higher an area is, the smaller the curvature of the corresponding microlens is.

Abstract: Provided is an image sensor including an overcoating layer and at least two micro lenses formed on the overcoating layer. The image sensor is characterized in that the overcoating layer positioned below a clearance between the micro lenses is etched such that curved surfaces of the micro lenses extend to the etched overcoating layer, and a contamination in the bonding pad can be prevented.

Abstract: A CMOS image sensor and fabricating method thereof enhances a light-receiving capability of an image sensor by preventing poor light-refraction characteristics at the peripheral part of a microlens. The CMOS image sensor includes at least one microlens formed by anistropic etching to have a focusing centerline, a central lens portion, and a peripheral lens portion, wherein the focusing centerline passes through the central lens portion and wherein the peripheral lens portion surrounds the central lens portion. The central lens portion has a first convex curvature based on a first radius and the peripheral lens portion has second convex curvature based on a second radius, wherein the second radius is greater than the first radius.

Abstract: An imager pixel array capable of separating and detecting the spectral components of an incident light without the use of a color filter array. The imager pixel array employs a grating layer which allows one or more spectral components of incident light to be transmitted therethrough, but diffracts other spectral components of the incident light. Both the transmitted and diffracted spectral components can be sensed by photosensors in the imager pixel array and used in subsequent data processing, thereby improving the quantum efficiency of the imager device. The grating layer can be formed of first and second materials each having a refractive index which are substantially the same at a predetermined wavelength.