Abstract: A semiconductor photodiode device includes a semiconductor substrate, a first buffer layer containing a material different from that of the semiconductor substrate in a portion thereof, a first semiconductor layer formed above the buffer layer and having a lattice constant different from that of the semiconductor substrate, a second buffer layer formed above the first semiconductor layer and containing an element identical with that of the first semiconductor layer in a portion thereof, and a second semiconductor layer formed above the buffer layer in which a portion of the first semiconductor layer is formed of a plurality of island shape portions each surrounded with an insulating film, and the second buffer layer allows adjacent islands of the first semiconductor layer to coalesce with each other and is in contact with the insulating film.

Abstract: An organic light emitting display device. The organic light emitting display device includes a substrate having a pixel region in which pixels are formed and a non-pixel region in which a light sensor is formed, an insulating film formed on the substrate, a first electrode formed on the insulating film and formed of a reflective material reflecting light, the first electrode being formed on the entire surface of the insulating film except for a region between the pixels and a region over the light sensor, a pixel defining film exposing a region of the first electrode and formed on the insulating film, an organic light emitting layer formed on the exposed region of the first electrode, and a second electrode formed on the organic light emitting layer. The first electrode is formed to have a greater area than that of the organic light emitting layer.

Abstract: A method and apparatus for operating an imager pixel that includes the act of applying a relatively small first polarity voltage and a plurality of pulses of a second polarity voltage on the gate of a transfer transistor during a charge integration period.

Abstract: A device separation insulating film and a device separation semiconductor layer are provided for a device separation section for separating adjacent devices from each other, end portions of the device separation insulating film and end portions of the device separation semiconductor layer are provided to overlap each other in order to surround two sides of an outer-periphery of the voltage conversion section and also to surround a channel section of the charge transfer device and the light receiving devices and an end portion of the device separation insulating film facing an end face of the light receiving device is arranged inwardly below a control electrode with respect to an end face of the control electrode on the light receiving device side.

Abstract: A photodiode device and methods of manufacturing the same are provided. The photodiode device comprises a light absorption layer defining a light-facing side and a back-light side; a via passing through the absorption layer, the via defining a side wall and a bottom surface; a conformal isolation layer covering the side wall and the bottom surface; a first patterned conductive layer disposed on the back-light side, the first patterned conductive layer having a first portion covering a first portion of the conformation isolation layer; a second patterned conductive layer disposed on the light-facing side of the absorption layer; and an opening through the conformal isolation layer, wherein the opening is filled with the second patterned conductive layer such that the second patterned conductive layer is connected with the first portion of the first patterned conductive layer.

Abstract: An n-type region as a charge storage region of a photodiode is buried in a substrate. The interface between silicon and a silicon oxide film is covered with a high concentration p-layer and a lower concentration p-layer is formed only in the portion immediately below a floating electrode for signal extraction. Electrons generated by light are stored in the charge storage region, thereby changing the potential of the portion of the p-layer at the surface of the semiconductor region. The change is transmitted through a thin insulating film to the floating electrode by capacitive coupling and read out by a buffer transistor. Initialization of charges is executed by adding a positive high voltage to the gate electrode of a first transfer transistor such that the electrons stored in the charge storage region are transferred to the n+ region and generation of reset noise is protected.

Abstract: A first photoelectric conversion element, which detects light and converts the light into photoelectrons has: one MOS diode having an electrode formed on a semiconductor base body with an insulator therebetween; and a plurality of embedded photodiodes formed in the semiconductor base body. The electrode of the MOS diode has, when viewed from the upper surface, a comb-like shape wherein a plurality of branch portions are branched from one electrode portion. Each of the embedded photodiodes is disposed to nest between the branch portions of the electrode when viewed from the upper surface.

Abstract: A solid-state image pickup device includes: a photoelectric conversion portion formed on a substrate and composed of a photodiode; an image pickup area in which plural pixels each including a reading-out electrode for reading out signal electric charges generated and accumulated in the photoelectric conversion portion are formed; and a light blocking film having an opening portion right above the photoelectric conversion portion in an effective pixel area of the image pickup area, and light-blocking said photoelectric conversion portion in an OB pixel area of the image pickup area, in which a film deposited between the light blocking film and the substrate right above the photoelectric conversion portion in the OB pixel area is composed of only a silicon oxide film.

Abstract: Photodetector arrays, image sensors, and other apparatus are disclosed. In one aspect, an apparatus may include a surface to receive light, a plurality of photosensitive regions disposed within a substrate, and a material coupled between the surface and the plurality of photosensitive regions. The material may receive the light. At least some of the light may free electrons in the material. The apparatus may also include a plurality of discrete electron repulsive elements. The discrete electron repulsive elements may be coupled between the surface and the material. Each of the discrete electron repulsive elements may correspond to a different photosensitive region. Each of the discrete electron repulsive elements may repel electrons in the material toward a corresponding photosensitive region. Other apparatus are also disclosed, as are methods of use, methods of fabrication, and systems incorporating such apparatus.

Abstract: A CMOS active pixel sensor (APS) cell structure includes at least one transfer gate device and method of operation. A first transfer gate device comprises a diodic or split transfer gate conductor structure having a first doped region of first conductivity type material and a second doped region of a second conductivity type material. A photosensing device is formed adjacent the first doped region for collecting charge carriers in response to light incident thereto, and, a diffusion region of a second conductivity type material is formed at or below the substrate surface adjacent the second doped region of the transfer gate device for receiving charges transferred from the photosensing device while preventing spillback of charges to the photosensing device upon timed voltage bias to the diodic or split transfer gate conductor structure.

Abstract: The semiconductor light receiving element 1 includes a semiconductor substrate 101, and a semiconductor layer having a photo-absorption layer 105 disposed on the top of the semiconductor substrate 101. The semiconductor layer of the semiconductor light receiving element 1 containing at least the photo-absorption layer 105 has a mesa structure, and a side wall of the mesa is provided with a protective film 113 covering the side wall. The protective film 113 is a silicon nitride film containing hydrogen, and a hydrogen concentration in one surface of the protective film 113 located at the side of the mesa side wall is lower than a hydrogen concentration in the other surface of the protective film 113 located at the side that is opposite to the side of the mesa side wall.

Abstract: The present disclosure provides systems and methods for configuring and constructing a single photo detector or array of photo detectors with all fabrications circuitry on a single side of the device. Both the anode and the cathode contacts of the diode are placed on a single side, while a layer of laser treated semiconductor is placed on the opposite side for enhanced cost-effectiveness, photon detection, and fill factor.

Abstract: A photoelectric conversion device includes: a first substrate of which end portions are cut off so as to slope or with a groove shape; a photodiode and an amplifier circuit over the first substrate; a first electrode electrically connected to the photodiode and provided over one end portion of the first substrate; a second electrode electrically connected to the amplifier circuit and provided over an another end portion of the first substrate; and a second substrate having third and fourth electrodes thereon. The first and second electrodes are attached to the third and fourth electrodes, respectively, with a conductive material provided not only at the surfaces of the first, second, third, and fourth electrodes facing each other but also at the side surfaces of the first and second electrodes to increase the adhesiveness between a photoelectric conversion device and a member on which the photoelectric conversion device is mounted.

Abstract: It is an object to form a high-quality crystalline semiconductor layer directly over a large-sized substrate with high productivity without reducing the deposition rate and to provide a photoelectric conversion device in which the crystalline semiconductor layer is used as a photoelectric conversion layer. A photoelectric conversion layer formed of a semi-amorphous semiconductor is formed over a substrate as follows: a reaction gas is introduced into a treatment chamber where the substrate is placed; and a microwave is introduced into the treatment chamber through a slit provided for a waveguide that is disposed in approximately parallel to and opposed to the substrate, thereby generating plasma. By forming a photoelectric conversion layer using such a semi-amorphous semiconductor, a rate of deterioration in characteristics by light deterioration is decreased from one-fifth to one-tenth, and thus a photoelectric conversion device that has almost no problems for practical use can be obtained.

Abstract: An image sensor and a method for fabricating the same are provided. The image sensor includes a first conductive type substrate including a trench formed in a predetermined portion of the first conductive type substrate, a second conductive type impurity region for use in a photodiode, formed below a bottom surface of the trench in the first conductive type substrate, and a first conductive type epitaxial layer for use in the photodiode, buried in the trench.

Abstract: A solid-state imaging device that includes: a pixel array section configured by an array of a unit pixel, including an optoelectronic conversion section that subjects an incoming light to optoelectronic conversion and stores therein a signal charge, a transfer transistor that transfers the signal charge stored in the optoelectronic conversion section, a charge-voltage conversion section that converts the signal charge provided by the transfer transistor into a signal voltage, and a reset transistor that resets a potential of the charge-voltage conversion section; and voltage setting means for setting a voltage of a well of the charge-voltage conversion section to be negative.

Abstract: A microlens, an image sensor including the microlens, a method of forming the microlens and a method of manufacturing the image sensor are provided. The microlens includes a polysilicon pattern, having a cylindrical shape, formed on a substrate, and a round-type shell portion enclosing the polysilicon pattern. The microlens may further include a filler material filling an interior of the shell portion, or a second shell portion covering the first shell portion. The method of forming a microlens includes forming a silicon pattern on a semiconductor substrate having a lower structure, forming a capping film on the semiconductor substrate over the silicon pattern, annealing the silicon pattern and the capping film altering the silicon pattern to a polysilicon pattern having a cylindrical shape and the capping film to a shell portion for a round-type microlens, and filling an interior of the shell portion with a lens material through an opening between the semiconductor substrate and an edge of the shell portion.

Abstract: To provide an amplification type solid state image pickup device enabling lower noise, higher gain, and higher sensitivity than any conventional amplification type solid state image pickup device.

Abstract: An image sensor having shield structures and methods of forming the same are provided. Generally, the image sensor includes: (i) substrate having at least one photosensitive element formed therein; (ii) a dielectric layer overlying the substrate and the photosensitive element; and (iii) an annular reflective waveguide disposed in the dielectric layer above the photosensitive element to reduce cross-talk between adjacent elements of the sensor while increasing sensitivity of the sensor. In certain embodiments, the sensor further includes a photoshield disposed in the dielectric above the photosensitive element and about the waveguide to further reduce the possibility of cross-talk. Other embodiments are also disclosed.

Abstract: A MOS-type solid-state image pickup device, on a semiconductor substrate, includes a photoelectric conversion unit having a first semiconductor region of a first conductivity type, a second semiconductor region of a second conductivity type, a third semiconductor region of the first conductivity type, and a transfer MOS transistor having a gate electrode disposed on an insulation film and transferring a charge carrier from a fourth semiconductor region. In addition, an amplifying MOS transistor having a gate electrode is connected to the fourth semiconductor region, and a fifth semiconductor region of the second conductivity type is continuously disposed to the second semiconductor region and under the gate electrode, and is disposed apart from the insulation film under the gate electrode of the transfer MOS transistor.

Abstract: To provide a solid-state image pickup apparatus with little or no difference in the dark currents between adjacent photoelectric conversion elements and providing a high sensitivity and a low dark current even in a high-speed readout operation. A well 302 is formed on a wafer 301, and semiconductor layers 101a, 101b are formed in the well to constitute photodiodes. A well contact 306 is formed between the semiconductor layers 101a, 101b. Element isolation regions 303b, 303a are provided between the well contact and the semiconductor layers, and channel stop layers 307b, 307a are provided under the element isolation regions 303b, 303a. A conductive layer 304 is provided on the element isolation region 303b, and a side wall 308 is provided on a side face of the conductive layer 304. A distance a between an end of the element isolation region 303b and the conductive layer 304, a width b of the side wall 308 and a device isolation width c satisfy a relation c>a?b.

Abstract: A semiconductor device includes a first MIS transistor, and a second MIS transistor having a threshold voltage higher than that of the first MIS transistor. The first MIS transistor includes a first gate insulating film made of a high-k insulating film formed on a first channel region, and a first gate electrode having a first conductive portion provided on and contacting the first gate insulating film and a second conductive portion. The second MIS transistor includes a second gate insulating film made of the high-k insulating film formed on a second channel region, and a second gate electrode having a third conductive portion provided on and contacting the second gate insulating film and a fourth conductive portion. The third conductive portion has a film thickness smaller than that of the first conductive portion, and is made of the same composition material as that of the first conductive portion.

Abstract: A semiconductor device includes: a semiconductor substrate 1; a through electrode 7 extending through the semiconductor substrate 1; a diffusion layer 24 formed in a region of an upper portion of the semiconductor substrate 1 located on a side of the through electrode 7; and a diffusion layer 22 formed in an upper portion of the diffusion layer 24. A portion of the side surface of the through electrode 7 facing the diffusion layer 24 is curved, and a portion of the surface of the diffusion layer 24 facing the through electrode 7 is curved.

Abstract: A solid-state imaging device, a line sensor and an optical sensor for enhancing a wide dynamic range while keeping high sensitivity with a high S/N ratio, and a method of operating a solid-state imaging device for enhancing a wide dynamic range while keeping high sensitivity with a high S/N ratio are provided. The solid-state imaging device comprises an integrated array of a plurality of pixels, each of which comprises a photodiode PD for receiving light and generating photoelectric charges, a transfer transistor Tr1 for transferring the photoelectric charges, and a storage capacitor element C connected to the photodiode PD at least through the transfer transistor Tr1 for accumulating, at least through the transfer transistor Tr1, the photoelectric charge overflowing from the photodiode PD during accumulating operation.

Abstract: A method of fabricating multi-spectral photo-sensors including photo-diodes incorporating stacked epitaxial superlattices monolithically integrated with CMOS devices on a common semiconductor substrate.

Abstract: The present invention is directed to novel front side illuminated, back side contact photodiodes and arrays thereof. In one embodiment, the photodiode has a substrate with at least a first and a second side and a plurality of electrical contacts physically confined to the second side. The electrical contacts are in electrical communication with the first side through a doped region of a first type and a doped region of a second type, each of the regions substantially extending from the first side through to the second side. In another embodiment, the photodiode comprises a wafer with at least a first and a second side; and a plurality of electrical contacts physically confined to the second side, where the electrical contacts are in electrical communication with the first side through a diffusion of a p+ region through the wafer and a diffusion of an n+ region through the wafer.

Abstract: A stratified photodiode for high resolution CMOS image sensors implemented with STI technology is provided. The photodiode includes a semi-conductive layer of a first conductivity type, multiple doping regions of a second conductivity type, multiple doping regions of the first conductivity type, and a pinning layer. The multiple doping regions of the second conductivity type are formed to different depths in the semi-conductive layer. The multiple doping regions of the first conductivity type are disposed between the multiple doping regions of the second conductivity type and form multiple junction capacitances without full depletion. In particular, the stratified doping arrangement allows the photodiode to have a small size, high charge storage capacity, low dark current, and low operation voltages.

Abstract: In a back-illuminated solid-state imaging device, a multilayer interconnect layer, a semiconductor substrate, a plurality of color filters, and a plurality of microlenses are provided in this order. A p-type region is formed so as to partition a lower portion of the semiconductor substrate into a plurality of regions, and an insulating member illustratively made of BSG is buried immediately above the p-type region. PD regions are isolated from each other by the p-type region and the insulating member. Moreover, a high-concentration region is formed in a lower portion of the PD region, and an upper portion is served as a low-concentration region.

Abstract: An image sensor includes a trench formed in a semiconductor substrate, a first reflection part formed in the trench and having an inclined, curved surface, a second reflection part formed on the first reflection part such that a remaining space of the trench is filled with the second reflection part, and a vertical type photodiode formed on a region of the substrate between trenches. A method for forming the image sensor includes forming a trench in a semiconductor substrate, forming a first reflection part having an inclined, curved surface in the trench, forming a second reflection part on the first reflection part such that a remaining space of the trench is filled with the second reflection part, and forming a vertical type photodiode on a region of the substrate between trenches.

Abstract: A solid-state image pickup element comprises a first-conductive type planar semiconductor layer formed on a second-conductive type planar semiconductor layer, a hole portion formed in the first-conductive type planar semiconductor layer to define a hole therein, and a first-conductive type high-concentration impurity region formed in a bottom wall of the hole portion. The solid-state image pickup element also includes a first-conductive type high-concentration impurity-doped element isolation region, a second-conductive type photoelectric conversion region, a transfer electrode formed on the sidewall of the hole portion through a gate dielectric film, a second-conductive type CCD channel region, and a read channel formed in a region of the first-conductive type planar semiconductor layer sandwiched between the second-conductive type photoelectric conversion region and the second-conductive type CCD channel region.

Abstract: An image sensor having shield structures and methods of forming the same are provided. Generally, the image sensor includes: (i) substrate having at least one photosensitive element formed therein; (ii) a dielectric layer overlying the substrate and the photosensitive element; and (iii) an annular reflective waveguide disposed in the dielectric layer above the photosensitive element to reduce cross-talk between adjacent elements of the sensor while increasing sensitivity of the sensor. In certain embodiments, the sensor further includes a photoshield disposed in the dielectric above the photosensitive element and about the waveguide to further reduce the possibility of cross-talk. Other embodiments are also disclosed.

Abstract: A full color complementary metal oxide semiconductor (CMOS) imaging circuit is provided. The imaging circuit is made up of an array of photodiodes including a plurality of pixel groups. Each pixel group supplies 3 electrical color signals, corresponding to 3 detectable colors. A color filter array overlies the photodiode array employing less than 3 separate filter colors. Each pixel group may be enabled as a dual-pixel including a single photodiode (PD) to supply a first color signal and stacked PDs to supply a second and third color signal. In one aspect, the color filter array employs 1 filter color per pixel group. In another aspect, the color filter array employees 2 filter colors per pixel group. In either aspect, the color filter array forms a checkerboard pattern of color filter pixels. For example, a magenta color filter may overlie the stacked PDs of each dual-pixel, to name one variation.

Abstract: An image sensor with an enlarged outward appearance of a microlens and a method for fabricating the same are provided. The image sensor includes: a plurality of microlenses formed on a semiconductor substrate with a certain spacing distance; and a protection layer formed over the microlenses, wherein the protection layer includes a first oxide layer which is formed by a plasma enhanced chemical vapor deposition (PECVD) method and a second oxide layer which is formed by a spin on glass (SOG) method over the first oxide layer to maintain sufficient step coverage over chasms between the microlenses.

Abstract: A solid-state image capturing apparatus has a plurality of light receiving sections for performing photoelectric conversion on incident light to generate a signal charge, a charge transfer section provided along a light receiving section arranged in a column direction among the plurality of light receiving sections, for transferring signal charges generated in the light receiving section arranged in the column direction to a predetermined direction, and at least two layers of charge transfer electrodes provided on the charge transfer section via an insulation film, where a plane view width readable from the light receiving section is 50% to the whole edge of the edge of the light receiving section on the charge transfer section side.

Abstract: A solid-state image pickup device includes a semiconductor substrate within which a pixel comprised of a photodiode and a transistor is formed. The transistor is formed at a surface of the semiconductor substrate, a pn junction portion formed between high concentration regions of the photodiode is provided within the semiconductor substrate and a part of the pn junction portion of the photodiode is extended to a lower portion of the transistor formed at the surface of the semiconductor substrate.

Abstract: Embodiments relate to an image sensor. According to embodiments, an image sensor may include a metal interconnection, readout circuitry, a first substrate, an image sensing device, and a second conduction type interfacial layer. The metal interconnection and the readout circuitry may be formed on and/or over the first substrate. The image sensing device may include a first conduction type conduction layer and a second conduction type conduction layer and may be electrically connected to the metal interconnection. The second conduction type interfacial layer may be formed in a pixel interface of the image sensing device.

Abstract: A semiconductor device of the present invention includes a semiconductor substrate, a semiconductor element formed in the semiconductor substrate, a surface layer formed on the semiconductor substrate, and a capacitance type sensor formed on the surface layer. The surface layer has a planar portion whose surface is planar. The capacitance type sensor includes a lower thin film parallelly opposed to the surface of the planar portion and an upper thin film opposed to the lower thin film at a prescribed interval on the side opposite to the surface layer.

Abstract: An image sensor according to embodiments may include a semiconductor substrate, photodiodes disposed over the semiconductor substrate, a dielectric layer formed over the photodiodes, a color filter layer formed over the dielectric layer, a planarization layer formed over the color filter layer, a phase change material formed over the planarization layer, and a plurality of microlenses formed over the planarization layer, wherein the phase change material is positioned in the microlens. Further, a method for manufacturing an image sensor according to embodiments may include forming a dielectric layer over a semiconductor substrate with a plurality of photodiodes, sequentially forming a color filter layer and a planarization layer over the dielectric layer, forming a phase change material over the planarization layer, forming a patterned phase change material by partially etching the phase change material, and forming microlenses over the planarization layer and the phase change material.

Abstract: An organic light emitting display includes an organic light emitting diode formed on a substrate, coupled to a transistor; a photodiode formed on the substrate and including a semiconductor layer including a high-concentration P doping region, an intrinsic region with defects and a high-concentration N doping region; and a controller that uniformly controls the luminance of light emitted from the organic light emitting diode by controlling a voltage applied to the first electrode and the second electrode according to the voltage outputted from the photodiode.

Abstract: A CMOS image sensor for improving light sensitivity and peripheral brightness ratio, and a method for fabricating the same. The CMOS image sensor includes a substrate on which a light sensor and device isolating insulation films are formed, in which the top of the substrate is coated with a plurality of metal layers and oxide films; a plurality of reflective layers formed inside the metal layers, each being spaced apart; a color filter embedded in a groove formed by etching the oxide films inside the reflective layers by a predetermined thickness; a plurality of protrusions formed on both sides of the top of the color filter, each arranged at a predetermined distance from one another; a flat layer formed on the top of the protrusions and the oxide films; and a micro-lens formed on the top of the flat layer. The reflective layer disposed at the top of the photodiode is made of a material having a high reflectance and low absorptivity.

Abstract: The invention is directed to providing a smaller semiconductor device formed as an optical sensor including a light receiving portion and a light emitting portion. A light receiving portion and a light emitting portion are disposed on a front surface of a semiconductor substrate for forming a semiconductor die, and a supporting body is attached to these so as to face these with an adhesive being interposed therebetween. A first opening exposing the light receiving portion from the front side of the supporting body is provided, and in a separated position therefrom, a second opening exposing the light emitting portion from the front side of the supporting body is provided. A first electrode and a second electrode are further disposed on the front surface of the semiconductor substrate, and bump electrodes electrically connected to these are disposed on the back surface of the semiconductor substrate.

Abstract: The present invention relates to a design structure for a pixel sensor cell. The pixel sensor cell approximately doubles the available signal for a given quanta of light. A design structure for a pixel sensor cell having reduced complexity includes an n-type collection well region formed beneath a surface of a substrate for collecting electrons generated by electromagnetic radiation impinging on the pixel sensor cell and a p-type collection well region formed beneath the surface of the substrate for collecting holes generated by the impinging photons. A circuit structure having a first input is coupled to the n-type collection well region and a second input is coupled to the p-type collection well region, wherein an output signal of the pixel sensor cell is the magnitude of the difference of a signal of the first input and a signal of the second input.

Abstract: A solid state image sensing device in which many pixels are disposed in a matrix on a two-dimensional plane comprises a plurality of light receiving devices disposed in such a way that a center interval may periodically change in a column direction and/or a row direction, and a plurality of micro-lenses, for collecting an incident light of each light receiving device, wherein a center interval periodically changes in accordance with the periodic change of the center interval of the light receiving device.

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

Abstract: A photo-detecting apparatus includes a photodiode that coverts light into electricity, a reverse-voltage switching unit that switches a reverse voltage to be applied to the photodiode, a current-difference detecting unit that detects a change in an output current of the photodiode occurring due to switching of the reverse voltage as a current difference, a correspondence retaining unit that retains a correspondence between the current difference and a dark current, a dark-current calculating unit that calculates a dark current by referring to the correspondence based on the current difference detected by the current-difference detecting unit, and a dark-current correcting unit that corrects the output current of the photodiode based on the dark current to find a photocurrent obtained through photoelectric conversion.

Abstract: A method and apparatus for operating an imager pixel that includes the act of applying a relatively small first polarity voltage and a plurality of pulses of a second polarity voltage on the gate of a transfer transistor during a charge integration period.

Abstract: Provided are embodiments of an image sensor. The image sensor can comprise a first substrate including a transistor circuit, a lower interconnection layer, an upper interconnection layer, and a second substrate including a vertical stacked photodiode. The lower interconnection layer is disposed on the first substrate and comprises a lower interconnection connected to the transistor circuit. The upper interconnection layer is disposed on the lower interconnection layer and comprises an upper interconnection connected with the lower interconnection. The vertical stacked photodiode can be disposed on the upper interconnection layer and connected with the upper interconnection through, for example, a single plug connecting a blue, green, and red photodiode of the vertical stack or a corresponding plug for each of the blue, green, and red photodiode of the vertical stack.

Abstract: An image sensor capable of overcoming a decrease in photo sensitivity resulted from using a single crystal silicon substrate, and a method for fabricating the same are provided. An image sensor includes a single crystal silicon substrate, an amorphous silicon layer formed inside the substrate, a photodiode formed in the amorphous silicon layer, and a transfer gate formed over the substrate adjacent to the photodiode and transferring photoelectrons received from the photodiode.

Abstract: A complementary metal-oxide-semiconductor (CMOS) image sensor (CIS) includes a semiconductor substrate including a photodiode therein as a light sensing unit. A floating diffusion region of a first conductivity type is provided in the semiconductor substrate, and is configured to receive charges generated in the photodiode. A power supply voltage region of the first conductivity type is also provided in the semiconductor substrate. A reset transistor including a reset gate electrode on a surface of the substrate between the floating diffusion region and a power supply voltage region is configured to discharge charges stored in the floating diffusion region in response to a reset control signal. The reset transistor includes a channel region in the substrate extending between the floating diffusion region and the power supply voltage region such that the floating diffusion region and the power supply voltage regions define source/drain regions for the reset transistor.

Abstract: A method is disclosed for attaching a bonding pad to the ohmic contact of a diode while reducing the complexity of the photolithography steps. The method includes the steps of forming a blanket passivation layer over the epitaxial layers and ohmic contacts of a diode, depositing a photoresist layer over the blanket passivation layer, opening a via through the photoresist above the ohmic contacts and on the blanket passivation layer, removing the portion of the blanket passivation layer defined by the via to expose the surface of the ohmic contact, depositing a metal layer on the remaining photoresist, and on the exposed portion of the ohmic contact defined by the via, and removing the remaining photoresist to thereby concurrently remove any metal on the photoresist and to thereby establish a metal bond pad on the ohmic contact in the via.