Abstract: A charge transfer device formed in a semiconductor substrate and including an array of electrodes forming rows and columns, wherein: the electrodes extend, in rows, in successive grooves with insulated walls, disposed in the substrate thickness and parallel to the charge transfer direction.

Abstract: A solid-state imaging device includes: a semiconductor substrate having a plurality of vertical transfer channel regions and a plurality of photoelectric conversion regions arranged in a matrix; a plurality of vertical transfer electrodes, each constructed of a gate electrode and a first metal light-shielding film, formed via a gate insulating film; a transparent insulating film formed in gaps existing between the vertical transfer electrodes above the vertical transfer channel regions; and a second metal light-shielding film formed via a first interlayer insulating film to cover at least the vertical transfer channel regions.

Abstract: A charge-coupled unit formed in a semiconductor substrate and including an array of identical electrodes forming rows and columns, wherein: each electrode extends in a cavity with insulated walls formed of a groove, oriented along a row, dug into the substrate thickness, and including, at one of its ends, a protrusion extending towards at least one adjacent row.

Abstract: A lens forming method according to the present invention for forming lenses capable of focusing light on a plurality of respective photoelectric conversion sections constituting of a semiconductor apparatus is described. The method includes a lens forming step of processing a lens forming material, in which an average gradient of a ? curve indicating a residual film thickness with respect to the amount of irradiation light is between ?15 and ?0.8 nm·cm2/mJ within the range of a residual film ratio of 10 to 50% or within the range of the amount of irradiation light of 55 to 137 mJ/cm2 into a lens surface shape, using a photomask with an optical transmittance that is varied according to a lens surface shape, as an exposure mask.

Abstract: A light detecting device includes a well region, a first holding region disposed in a surface portion of the well region, a second holding region and a third holding region disposed in a surface portion of the first holding region, an insulating layer disposed on the second holding region and the third holding region, a first electrode disposed on the second holding region through the insulating layer, and the second electrode disposed on the third holding region through the insulating layer. The first holding region is configured to hold a first carrier generated in the well region. Each of the second holding region and the third holding region is configured to hold a second carrier generated in the well region. The first carrier is one of an electron and a hole, and the second carrier is the other one of the electron and the hole.

Abstract: Disclosed is a metal optical filter capable of a photo-lithography process and an image sensor including the same, and more particularly, a metal optical filter capable of a photo-lithography process, which can quite freely adjust the transmission band and transmittance thereof, even with a small number of metal layers, and simultaneously, can be actually applied in a CMOS process because it is possible to achieve nanoscale patterning by the photo-lithography process, and an image sensor including the metal optical filter. The metal optical filter capable of a photo-lithography process includes a plurality of metal rods arranged in parallel with each other at an equal nanoscale interval; and an insulation material formed between the plurality of metal rods and on upper and lower surfaces of the plurality of metal rods, wherein the metal rod is formed to comprise an upper Ti layer, an Al layer, and a lower TiN layer.

Abstract: An image sensor according to the present invention includes a second conductivity type first impurity region provided on a surface of a first conductivity type semiconductor substrate for constituting a transfer channel for signal charges, a charge increasing portion provided on the first impurity region for increasing the amount of signal charges by impact ionization, an increasing electrode provided on the side of the surface of the semiconductor substrate for applying a voltage to the charge increasing portion, and a second conductivity type second impurity region opposed to the first impurity region through a prescribed region of the semiconductor substrate and suppliable with charges.

Abstract: CMOS image sensor pixel sensor cells, methods for fabricating the pixel sensor cells and design structures for fabricating the pixel sensor cells are designed to allow for back side illumination in global shutter mode by providing light shielding from back side illumination of at least one transistor within the pixel sensor cells. In a first particular generalized embodiment, a light shielding layer is located and formed interposed between a first semiconductor layer that includes a photoactive region and a second semiconductor layer that includes the at least a second transistor, or a floating diffusion, that is shielded by the light blocking layer.

Abstract: A noise generated by a constitution of widening an incident aperture of light of a photoelectric conversion element is reduced. In a manufacturing method of a photoelectric conversion device, first electroconductor arranged in a first hole arranged in the first interlayer insulation layer electrically connects a first semiconductor region to a gate electrode of an amplifying MOS transistor not through wirings included in a wiring layer. Moreover, a second electroconductor electrically connects a second semiconductor region different from the first semiconductor region to a wiring. In a constitution of that second electroconductor, a third electroconductor arranged in a second hole arranged in the first interlayer insulation layer and a fourth electroconductor arranged in a third hole arranged in the second interlayer insulation layer are stacked and electrically connected to each other.

Abstract: A solid-state imaging device includes a semiconductor substrate and a plurality of photoelectric conversion elements provided in the semiconductor substrate, wherein the plurality of photoelectric conversion elements include: effective photoelectric conversion elements which are photoelectric conversion elements for obtaining an imaging signal corresponding to light from a subject; and OB photoelectric conversion elements which are photoelectric conversion elements for obtaining a reference signal of an optical black level, and the solid-state imaging device further includes a first shielding layer provided at least over the effective pixel area as defined herein and having an opening provided at least over a part of the effective photoelectric conversion elements, and a second shielding layer provided over the OB pixel area as defined herein and electrically separated from the first shielding layer.

Abstract: A backside illumination semiconductor image sensor, wherein each photodetection cell includes a semiconductor body of a first conductivity type of a first doping level delimited by an insulation wall, electron-hole pairs being capable in said body after a backside illumination; on the front surface side of said body, a ring-shaped well of the second conductivity type, this well delimiting a substantially central region having its upper portion of the first conductivity type of a second doping level greater than the first doping level; and means for controlling the transfer of charge carriers from said body to said upper portion.

Abstract: The pixel for use in an image sensor comprises a low-doped semiconductor substrate (A). On the substrate (A), an arrangement of a plurality of floating areas, e.g., floating gates (FG2-FG6), is provided. Neighboring floating gates are electrically isolated from each other yet capacitively coupled to each other. By applying a voltage (V2?V1) to two contact areas (FG1, FG7), a lateral steplike electric field is generated. Photogenerated charge carriers move along the electric-field lines to the point of highest potential energy, where a floating diffusion (D) accumulate the photocharges. The charges accumulated in the various pixels are sequentially read out with a suitable circuit known from image-sensor literature, such as a source follower or a charge amplifier with row and column select mechanisms. The pixel of offers at the same time a large sensing area, a high photocharge-detection sensitivity and a high response speed, without any static current consumption.

Abstract: A solid-state image pick-up device and a method of reading out a pixel signal thereof are provided, and the solid-state image pick-up device provides a large dynamic range without an increase in the area of a pixel. Plural pixels are arranged therein.

Abstract: Disclosed is a solid-state image sensor including a photoelectric converter, a charge detector, and a transfer transistor. The photoelectric converter stores a signal charge that is subjected to photoelectric conversion. The charge detector detects the signal charge. The transfer transistor transfers the signal charge from the photoelectric converter to the charge detector. In the solid-state image sensor, the transfer transistor includes a gate insulating film, a gate electrode formed on the gate insulating film, a first spacer formed on a sidewall of the gate electrode on a side of the photoelectric converter, and a second spacer formed on another sidewall of the gate electrode on a side of the charge detector. The first spacer is longer than the second spacer.

Abstract: A solid-state imaging device includes: an imaging region including a plurality of light-receiving parts; a first transfer section provided on the imaging region and transferring, in a first direction, signals generated by the light-receiving parts; a second transfer section provided at a first side of the imaging region and transferring, in a second direction intersecting the first direction, the signals transferred from the first transfer section; an output circuit for outputting the signals; and bonding pads provided at the first side of the imaging region with the second transfer section sandwiched between the imaging region and the bonding pads. The bonding pads are arranged in a plurality of rows each extending in the second direction. Each of the bonding pads in one of the rows at least partially overlaps one of the bonding pads in another one of the rows when viewed in the first direction.

Abstract: A solid-state image pickup element includes: (A) a light receiving/charge accumulating region formed in a semiconductor layer and formed by laminating M (where M?2) light receiving/charge accumulating layers; (B) a charge outputting region formed in the semiconductor layer; (C) a depletion layer forming region formed of a part of the semiconductor layer, the part of the semiconductor layer being situated between the light receiving/charge accumulating region and the charge outputting region; and (D) a control electrode region for controlling a state of formation of a depletion layer in the depletion layer forming region, wherein the solid-state image pickup element further includes a light receiving/charge accumulating layer extending section extending from each light receiving/charge accumulating layer to the depletion layer forming region.

Abstract: A photoelectric conversion device includes a photoelectric conversion unit which is arranged in a semiconductor substrate, a charge holding portion which is arranged in the semiconductor substrate and temporarily holds a charge generated by the photoelectric conversion unit, a first transfer electrode which is arranged at a position above the semiconductor substrate to transfer a charge generated by the photoelectric conversion unit to the charge holding portion, a charge-voltage converter which is arranged in the semiconductor substrate and converts a charge into a voltage, and a second transfer electrode which is arranged at a position above the semiconductor substrate to transfer a charge held by the charge holding portion to the charge-voltage converter, and the first transfer electrode is arranged to cover the charge holding portion, and not to overlap the second transfer electrode when viewed from a direction perpendicular to the upper surface of the semiconductor substrate.

Abstract: A CCD type solid-state imaging device includes: a photoelectric conversion element (n layer 2, p layer 3) formed in a semiconductor substrate 1; a charge transfer channel 5 that transfers electric charges generated in the photoelectric conversion element; a charge read region 6 that reads out the electric charges accumulated in the photoelectric conversion element into the charge transfer channel 5; and a charge read electrode 8 formed above the charge read region 6 with a gate insulating film 10 disposed therebetween. The charge read electrode 8 controls the reading out of the electric charges into the charge transfer channel 5. A gap is formed between the photoelectric conversion element and the charge read electrode 8 in plan view.

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: A solid-state imaging device includes a substrate having a first surface and a second surface, light being incident on the second surface side; a wiring layer disposed on the first surface side; a photodetector formed in the substrate and including a first region of a first conductivity type; a transfer gate disposed on the first surface of the substrate and adjacent to the photodetector, the transfer gate transferring a signal charge accumulated in the photodetector; and at least one control gate disposed on the first surface of the substrate and superposed on the photodetector, the control gate controlling the potential of the photodetector in the vicinity of the first surface.

Abstract: A photodetector capable of improving dynamic range for input signals is provided. This photodetector includes a photoelectric converting portion, a charge separating portion, a charge accumulating portion, a barrier electrode formed the charge separating portion and the charge accumulating portion, and a barrier-height adjusting portion electrically connected to the barrier electrode. Undesired electric charges such as generated when environment light is incident on the photoelectric converting portion are removed by the charge separating portion. A potential barrier with an appropriate height is formed under the barrier electrode by applying a voltage to the barrier electrode according to an electric charge amount supplied from the charge separating portion to the barrier-height adjusting portion. Electric charges flowing from the charge separating portion into the charge accumulating portion over the potential barrier are provided as an output of the photodetector.

Abstract: Disclosed herein is a solid-state imaging device including a first transfer electrode portion and a second transfer electrode portion having a pattern area rate higher than that of the first transfer electrode portion. The first transfer electrode portion includes a plurality of first transfer electrodes having a single-layer structure of metal material. The second transfer electrode portion includes a plurality of second transfer electrodes having a single-layer structure of polycrystalline silicon or amorphous silicon.

Abstract: Forming an impurity region 6 and an impurity region 5 having a lower concentration than the impurity region 6 in a lower layer region of a gate electrode close to the boundary with a signal electron-voltage conversion section of a horizontal CCD outlet makes it possible to smooth a potential distribution at the time of transfer, improve the transfer efficiency, increase the number of saturated electrons and reduce variations in the transfer efficiency and variations in saturation.

Abstract: A solid-state imaging apparatus includes a plurality of photoelectric conversion units configured to generate signal charge from light received at light-receiving surfaces thereof, the plurality of photoelectric conversion units being provided in the image-sensing area of a substrate; a charge reading unit configured to read signal charge generated by the photoelectric conversion units, a charge readout channel area thereof being provided in the image-sensing area of the substrate; a transfer register unit configured to transfer signal charge read from the plurality of photoelectric conversion units by the charge reading unit, a charge transfer channel area thereof being provided in the image-sensing area of the substrate; and a light-shielding unit that is provided in the image-sensing area of the substrate and that has an opening through which light is transmitted formed in an area corresponding to a light-receiving surface of a respective photoelectric conversion unit.

Abstract: A pixel sensor cell having a semiconductor substrate having a surface; a photosensitive element formed in a substrate having a non-laterally disposed charge collection region entirely isolated from a physical boundary including the substrate surface. The photosensitive element comprises a trench having sidewalls formed in the substrate of a first conductivity type material; a first doped layer of a second conductivity type material formed adjacent to at least one of the sidewalls; and a second doped layer of the first conductivity type material formed between the first doped layer and the at least one trench sidewall and formed at a surface of the substrate, the second doped layer isolating the first doped layer from the at least one trench sidewall and the substrate surface.

Abstract: An image pickup device is characterized by including a plurality of pixels having a plurality of photoelectric conversion units, convex interlayer lenses with respect to incident light, the convex interlayer lenses being arranged correspondingly to a photoelectric conversion devices and color filters being arranged for each color on the interlayer lenses correspondingly to the photoelectric conversion devices, wherein the color filter is formed to match the shape of the interlayer lens and the top surface thereof is substantially flat. This configuration reduces the amount of light which is incident on the gaps between adjacent microlenses and passes through the color filters at the boundary of pixels, decreasing color mixture of camera image.

Abstract: A producing method of producing a solid state pickup device is provided. Imaging elements are formed on a wafer in a matrix form. Each of the imaging elements has a light receiving surface and plural contact points. Receiving surface border portions are formed on a glass plate to protrude therefrom in a matrix form by etching. The receiving surface border portions are attached to the wafer to surround the light receiving surface in each of the receiving surface border portions. The light receiving surface is spaced from the glass plate. The glass plate is diced outside respectively the receiving surface border portions, to form shield glass for covering the light receiving surface. The wafer is diced for each of the imaging elements, to obtain the solid state pickup device having the shield glass and one of the imaging elements.

Abstract: In a photoelectric conversion apparatus having a plurality of unit cells, wherein each of the unit cells has a photoelectric conversion element, a transfer transistor and a floating diffusion region, a light shielding portion arranged on an upper portion of the floating diffusion region is included. The respective light shielding portions are separated from one another, and are in a floating state without being electrically connected to the floating diffusion region.

Abstract: A demodulation pixel architecture allows for demodulating an incoming modulated electromagnetic wave, normally visible or infrared light. It is based on a charge coupled device (CCD) line connected to a drift field structure. The drift field is exposed to the incoming light. It collects the generated charge and forces it to move to the pick-up point. At this pick-up point, the CCD element samples the charge for a given time and then shifts the charge packets further on in the daisy chain. After a certain amount of shifts, the multiple charge packets are stored in so-called integration gates, in a preferred embodiment. The number of integration gates gives the number of simultaneously available taps. When the cycle is repeated several times, the charge is accumulated in the integration gates and thus the signal-to-noise ratio increases. The architecture is flexible in the number of taps. A dump node can be attached to the CCD line for dumping charge with the same speed as the samples are taken.

Abstract: Driving is performed so that a transition start time point ta of drive pulse signals ?H1 and ?H2 which are applied to transfer electrodes of a charge transfer section on an upstream side of a branch section is within transition period B or C of drive pulse signals ?HP1 and ?HP2 which are applied to transfer electrodes of the charge transfer section on a downstream side.

Abstract: A reset transistor includes a floating diffusion region for detecting a charge, a junction region for draining the charge, a gate for controlling a transfer of the charge from the floating diffusion region to the junction region upon receipt of a reset signal, and a potential well incorporated underneath the gate.

Abstract: It is an object to provide solid-state imaging device, which can easily be manufactured and has a high reliability, and a method of manufacturing the solid-state imaging device. In the present invention, a manufacturing method comprises the steps of forming a plurality of IT-CCDs on a surface of a semiconductor substrate, bonding a translucent member to the surface of the semiconductor substrate in order to have a gap opposite to each light receiving region of the IT-CCD, and isolating a bonded member obtained at the bonding step for each of the IT-CCDs.

Abstract: A wafer for backside illumination type solid imaging device has a plurality of pixels inclusive of a photoelectric conversion device and a charge transfer transistor at its front surface side and a light receiving surface at its back surface side, wherein said wafer is a SOI wafer obtained by forming a given active layer on a support substrate made of C-containing n-type semiconductor material through a chemical oxide film having a thickness of not more than 1 nm.

Abstract: This image sensor includes a charge increasing portion for increasing the quantity of charges, a first electrode for applying a voltage regulating a region adjacent to the charge increasing portion to a prescribed potential, a second electrode provided adjacently to the first electrode for applying another voltage increasing the quantity of charges in the charge increasing portion, a first wire formed on a prescribed layer for supplying a signal to the first electrode and a second wire formed on a layer different from the prescribed layer for supplying another signal to the second electrode.

Abstract: A producing method of producing a solid state pickup device is provided. Imaging elements are formed on a wafer in a matrix form. Each of the imaging elements has a light receiving surface and plural contact points. Receiving surface border portions are formed on a glass plate to protrude therefrom in a matrix form by etching. The receiving surface border portions are attached to the wafer to surround the light receiving surface in each of the receiving surface border portions. The light receiving surface is spaced from the glass plate. The glass plate is diced outside respectively the receiving surface border portions, to form shield glass for covering the light receiving surface. The wafer is diced for each of the imaging elements, to obtain the solid state pickup device having the shield glass and one of the imaging elements.

Abstract: A solid state imaging device improving and stabilizing imaging characteristic by optimizing a location of a positive hole accumulation layer to an electrode at the periphery of a light receiving portion, and having light receiving portions formed on a substrate and electrodes formed on the substrate at the periphery of the light receiving portion, each electrode including at least a first electrode to which a positive voltage is applied and a second electrode to which only 0 volt or a negative polarity voltage is applied, each light receiving portion having a signal charge accumulation region formed on the substrate and a positive hole accumulation region formed in a surface layer portion of the signal charge accumulation region, each positive hole accumulation region arranged at a distance from the first electrode and arranged so as. to overlap the second electrode, and method of producing the same and a camera.

Abstract: An image sensor includes a substrate having a plurality of photosensitive areas, a light shield positioned spanning the photosensitive areas in which light shield a plurality of apertures are formed, and a plurality of microlens each disposed centered on one of the apertures such that a focal point of the incident light through each microlens is substantially extended into the substrate to a point where a portion of the incident light directed onto the periphery of each microlens is blocked by a light shield.

Abstract: A method for reducing dark current within a charge-coupled device, the method includes each gate phase n having a capacitance Cn, voltage change on the gate phase n given by ?Vn such ? n ? C n ? ? ? ? V n ? 0 ; for the first time period, maintaining a set of first gate phases holding charge in the accumulated state and maintaining a set of second gate phases not holding charge in the depleted state; for a second time period, clocking the charge into a set of third gate phases in the depleted state and clocking the second set of gate phases not holding charge into the accumulated state; for a third time period, clocking the third set of gate phases holding the charge into the accumulated state and clocking a fourth set of gates not holding the charge into the depletion state; wherein the second time period is shorter than the first and third time periods.

Abstract: A solid-state image pickup apparatus includes an image pickup pixel unit in which a plurality of pixels each including a photoelectric conversion element and a field-effect transistor are arranged on a semiconductor substrate so that a light-receiving surface is disposed at a first surface side of the semiconductor substrate; a peripheral circuit unit provided at a periphery of the image pickup pixel unit of the semiconductor substrate; and a multilayered wiring layer in which a plurality of wiring layers for driving the field-effect transistor of the image pickup pixel unit are laminated at a second surface side of the semiconductor substrate, wherein a wiring in each of the wiring layers constituting the multilayered wiring layer is disposed so that a coverage of the wiring located at least in the image pickup pixel unit of the semiconductor substrate reaches 100%, viewed from the second surface side.

Abstract: A solid state imaging device includes a transfer transistor for transferring signal charges generated by photoelectric conversion to a floating diffusion layer, a reset transistor for resetting a potential of the floating diffusion layer, and an amplifying transistor for outputting a signal corresponding to the potential of the floating diffusion layer. A low concentration impurity region having an impurity concentration lower than that of the first conductivity type semiconductor region is formed in part of a surface portion of the first conductivity type semiconductor region which is located below a gate electrode of the amplifying transistor and serves as a well region of the amplifying transistor.

Abstract: It is an object to provide a CCD solid-state image sensor, in which an area of a read channel is reduced and a rate of a surface area of a light receiving portion (photodiode) to an area of one pixel is increased.

Abstract: In a solid state imaging device, and a method of manufacture thereof, the efficiency of the transfer of available photons to the photo-receiving elements is increased beyond that which is currently available. Enhanced anti-reflection layer configurations, and methods of manufacture thereof, are provided that allow for such increased efficiency. They are applicable to contemporary imaging devices, such as charge-coupled devices (CCDs) and CMOS image sensors (CISs). In one embodiment, a photosensitive device is formed in a semiconductor substrate. The photosensitive device includes a photosensitive region. An anti-reflection layer comprising silicon oxynitride is formed on the photosensitive region. The silicon oxynitride layer is heat treated to increase a refractive index of the silicon oxynitride layer, and to thereby decrease reflectivity of incident light at the junction of the photosensitive region.

Abstract: A solid image pick-up element comprises: a photoelectric converting portion; a charge transmitting portion comprising a charge transmitting electrode that transmits a charge generated by the photoelectric converting portion; and a peripheral circuit portion connected to the charge transmitting portion, wherein a surface level of a field oxide film provided at the peripheral circuit portion and the charge transmitting portion to surround an effective image pick-up region of the photoelectric converting portion is to a degree the same as a surface level of the photoelectric converting portion.

Abstract: An HCCD includes a channel 21 that transfers electric charges in an X direction, a channel 25 that transfers the electric charges in a Z1 direction, a channel 23 that transfers the electric charges in a Z2 direction, and a channel 22 that connects the channels 23, 25 to the channel 21. The following relation is satisfied in impurity concentration of the channels: channel 21 channel 22 channel 23, 25. A fixed DC voltage is applied to branch electrodes 12a, 12b above the channel 22. The channel 22 has protrusion portions 19 that protrude inward from an outer circumference, which connects T1 and T2, and an outer circumference, which connects T3 and T4. The protrusion portions 19 causes charges below the transfer electrode 11b to move near the center of the channel 22 in a Y direction. Thereby, the travel distance of the charges in the channel 22 is reduced.

Abstract: A light detecting element 1 including an element formation layer 22 which contains a well region 31. A surface electrode 25 is formed on the layer 22 through an insulating layer 24. The region 31 contains an electron holding region 32. The region 32 contains a hole holding region 33. The layer 24 contains a control electrode 26 facing the region 33 through the layer 24. Electrons and holes are generated at the layer 22. There are two selected states. In one state, by controlling each electric potential applied to the electrodes 25, 26, electrons are gathered at the region 32, while holes are held at the region 33. In another state, recombination is stimulated between the electrons and the holes. After the recombination, the remaining electrons are picked out as received light output.

Abstract: A solid state imaging device has a plurality of photodetector parts 11 arranged in matrix, a plurality of vertical charge transfer electrodes 13 that read out signal charge from the photodetector parts and transfer the signal charge in the vertical direction, and a first light-shielding film 5 that shields the plural vertical charge transfer parts from incident light. Each of the vertical charge transfer electrodes includes: a transfer channel 12 provided along the vertical array of the plural photodetector parts, a plurality of first transfer electrodes 3a that are formed on the transfer channel so as to traverse the transfer channel and that is coupled in the horizontal direction in spacing between the photodetector parts; and second transfer electrodes 3b provided on the transfer channel and arranged between the first transfer electrodes. The first light-shielding film is formed continuously in the horizontal direction and has openings formed on the photodetector parts.

Abstract: Provided are a doping mask and methods of manufacturing a charge transfer image device and a microelectronic device using the same. The method includes forming a photoresist film on an entire surface of a substrate or sub-substrate having a peripheral circuit region and a pixel region, removing the photoresist film on an upper surface of the substrate intended for the peripheral circuit region and patterning the photoresist film on an upper surface of the substrate intended for the pixel region to form a photoresist pattern having an array of openings with a predetermined pitch, implanting ions at the same concentration level into the entire surface of the substrate using the photoresist pattern as a doping mask, and diffusing the implanted ions by annealing. The pitch is determined so that ions implanted through each opening diffuse toward those implanted through an adjacent one to form wells.

Abstract: A part of a semiconductor layer directly under a light-receiving gate electrode functions as a charge generation region, and electrons generated in the charge generation region are injected into a part of a surface buried region directly above the charge generation region. The surface buried region directly under a first transfer gate electrode functions as a first transfer channel, and the surface buried region directly under a second transfer gate electrode functions as a second transfer channel. Signal charges are alternately transferred to an n-type first floating drain region and a second floating drain region through the first and second floating transfer channels.

Abstract: Provided is a CMOS image sensor with an asymmetric well structure of a source follower. The CMOS image sensor includes: a well disposed in an active region of a substrate; a drive transistor having one terminal connected to a power voltage and a first gate electrode disposed to cross the well; and a select transistor having a drain-source junction between another terminal of the drive transistor and an output node, and a second gate electrode disposed in parallel to the drive transistor. A drain region of the drive transistor and a source region of the select transistor are asymmetrically arranged.

Abstract: A solid-state imaging device includes an N-type semiconductor substrate, an N-type impurity region provided in the surficial portion of the N-type semiconductor substrate, a photo-electric conversion unit formed in the N-type impurity region, a charge accumulation unit formed in the N-type impurity region so as to contact with the photo-electric conversion unit, and temporarily accumulating charge generated in the photo-electric conversion unit, a charge hold region (barrier unit) formed in the N-type impurity region so as to contact with the charge accumulation unit, and allowing the charge accumulation unit to accumulate the charge, and a charge accumulating electrode provided to the charge accumulation unit. The charge accumulation unit and the charge hold region are formed to be N?-type.