Abstract: A pixel of a semiconductor-based image detector includes a photodetector, at least one switching device serially connected to the photodetector and a bypass device interposed between the photodetector and a power supply voltage. Accordingly, even though excess charges may be generated in the photodetector, the excess charges flow into the power supply through the bypass device. Blooming can thereby be reduced or suppressed.

Abstract: A charge separation heterojunction structure which uses a fullerene polymer film as a part of its constituent materials and which may be used to produce a solar cellor a light emitting diode superior in durability, physical properties of electrons and economic merits. The heterojunction structure is such a structure in which an electron-donating electrically conductive high-polymer film and an electron-accepting fullerene polymer film are layered between a pair of electrodes at least one of which is light transmitting. In forming the layers, the fullerene polymer film is identified using in particular the Raman and Nexafs methods in combination so that upper layers are formed after identifying the polymer film.

Abstract: More complete charge transfer is achieved in a CMOS or CCD imager by reducing the spacing in the gaps between gates in each pixel cell, and/or by providing a lightly doped region between adjacent gates in each pixel cell, and particularly at least between the charge collecting gate and the gate downstream to the charge collecting gate. To reduce the gaps between gates, an insulator cap with spacers on its sidewalls is formed for each gate over a conductive layer. The gates are then etched from the conductive layer using the insulator caps and spacers as hard masks, enabling the gates to be formed significantly closer together than previously possible, which, in turn increases charge transfer efficiency. By providing a lightly doped region on between adjacent gates, a more complete charge transfer is effected from the charge collecting gate.

Abstract: Method of fabricating an optical semiconductor package and optical semiconductor package containing an integrated circuit chip having on a front face an optical sensor and electrical connection regions distributed around this sensor, in which a transparent patch (6) lies in front of the front face of the chip without covering the electrical connection regions of this chip, plates (2, 7) defining between them a cavity (10) in which the said chip and the said patch are stacked and which have annular assembly faces (2a, 7a), electrical connection pads (15) are placed between the said electrical connection regions and one face (12) of the said cavity, electrical connection tracks (14) are carried by a plate (7) and lie on the said face (12) of the cavity in order to be in contact with the said pads, an adhesive layer (18) flying between the said assembly faces (2a, 7a), the said tracks (14) protruding in order to pass between the assembly faces of the said plates with a view to external connections and the plate

Abstract: Spaces in a nanostructure can be filled with an organic material while in the solid state below Tm (without heating) by exposing the organic material to solvent vapor while on or mixed with the nanostructured material. The exposure to solvent vapor results in intimate contact between the organic material and the nanostructured material without having to expose them to possibly detrimental heat to melt in the organic material. Solution processing methods need only to be employed to create bulk films while organic material infiltration can take place in the solid state after depositing the film.

Abstract: A method of making a shallow trench-type pixel for a CMOS image sensor is disclosed. The disclosed pixel-fabricating method can increase the active area of a pixel by forming a photodiode in the shape of a shallow trench. In one example, a disclosed method includes forming a CMOS image sensor on an epitaxial wafer, forming a first photoresist layer over said structure, patterning so as to form a shallow trench on a pixel area, and, then, etching, removing said first photoresist layer, forming a second photoresist layer over said structure, pattering so as to form a photodiode junction, and, then, conducting ion-implanting process; and removing said second photoresist layer and conducting a thermal treatment process.

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: An active pixel image sensor is formed on a P-type epitaxial layer on a P-type substrate. An active pixel array is in the P-type epitaxial layer. Each pixel includes an N-well functioning as a collection node, and a P-well adjacent the N-well. The P-well includes only NMOS transistors functioning as active elements. The in-pixel transistors cooperate with off-pixel PMOS transistors to form A-D converters.

Abstract: There is described a back thinned sensor in which a material is added on the front surface to extend the wavelength of the sensor into wavelengths it normally does not reach. In the preferred embodiment, the back-thinned layer comprises silicon and is the base for a CMOS device or a CCD. The photocathode in a night vision device comprises in the preferred unit GaAs.

Abstract: There are provided a semiconductor substrate 101 on which solid-state imaging devices are formed, and a translucent member 201 provided onto a surface of the semiconductor substrate such that spaces are provided to oppose to light receiving areas of the solid-state imaging devices, wherein external connecting terminals are arranged on an opposing surface of the semiconductor substrate 101 to a solid-state imaging device forming surface, and the external connecting terminals are connected to the solid-state imaging devices via through-holes provided in the semiconductor substrate 101.

Abstract: A second conductivity type well is formed in a first conductivity type semiconductor substrate. Vertical CCD channels of the first conductivity type are formed in the second conductivity type well. Vertical transfer electrodes are formed above the vertical CCD channels to form vertical CCDs along with the vertical CCD channels. A first impurity diffusion layer is formed in the well by implanting first conductivity type impurities along a first direction crossing the normal direction of the semiconductor substrate. A second impurity diffusion layer is formed in the well by implanting first conductivity type impurities along a second direction crossing the normal direction of the semiconductor substrate. A third impurity diffusion layer of the second conductivity type is formed between the first and second impurity diffusion layer. A fourth impurity diffusion layer of the second conductivity type is formed in the well above the first to third impurity diffusion layers.

Abstract: Disclosed is a method for fabricating a solid-state imaging device including a semiconductor substrate of a first conductivity type, a plurality of light-receiving sections provided at a distance in the surface region of the semiconductor substrate, and channel stop regions of a second conductivity type provided between the adjacent light-receiving sections in the surface region and in the internal region of the semiconductor substrate. The method includes the steps of forming a first photoresist layer having openings corresponding to positions at which the channel stop regions are formed; ion-implanting an impurity of a second conductivity type into the semiconductor substrate at a first energy through the first photoresist layer as a mask; forming a second photoresist layer having openings; and ion-implanting an impurity of a second conductivity type into the semiconductor substrate at a second energy through the second photoresist layer as a mask.

Abstract: An image sensor includes a substrate containing photosensitive areas; an insulator spanning the substrate; and a first and second layer of a multi-layer metalization structure wherein the first layer forms the light shield regions over portions of the photosensitive area as well as forming circuit interconnections and barrier regions to prevent spiking into the substrate or gates at contacts in the non-imaging area, and the second layer spanning the interconnections and barrier regions of the first layer only over the non-imaging area.

Abstract: A retrograde well structure for a CMOS imager that improves the quantum efficiency and signal-to-noise ratio of the imager. The retrograde well comprises a doped region with a vertically graded dopant concentration that is lowest at the substrate surface, and highest at the bottom of the well. A single retrograde well may have a single pixel sensor cell, multiple pixel sensor cells, or even an entire array of pixel sensor cells formed therein. The highly concentrated region at the bottom of the retrograde well repels signal carriers from the photosensor so that they are not lost to the substrate, and prevents noise carriers from the substrate from diffusing up into the photosensor. Also disclosed are methods for forming the retrograde well.

Abstract: An image sensor element includes a vertical overflow drain structure to eliminate substrate charge diffusion causing CMOS image sensor noise. An extra chemical mechanical polish step used to shorten the micro-lens to silicon surface distance in order to reduce optical cross talking. One embodiment uses N type substrate material with P? epitaxial layer to form a vertical overflow drain. Deep P well implantation is introduced to the standard CMOS process to prevent latch-up between an N well to an N type substrate. A photo diode is realized by stacked N well/Deep N well and stacked P well/Deep P well to improve performance.

Abstract: A frame transfer-type solid imaging device is provided, which can be operated without reducing the transfer efficiency or the transfer charge quantity. A plurality of N-type regions 5 constituting photoelectric conversion regions and a plurality of P+-type regions 6 constituting channel stop regions are formed on a P-type silicon substrate 4, and a transparent electrode 1 is further formed through an insulating film 7 on the substrate 4. The thickness of the transparent electrode at a portion above the photoelectric conversion region is made thinner than the thickness of the other part of the transparent electrode 1, and an antireflection film 8 is formed above the photoelectric conversion region 2.

Abstract: A solid-state imaging device of the present invention includes a vertical charge transfer portion and a horizontal charge transfer portion that is connected to at least one end of the vertical charge transfer portion. The vertical charge transfer portion includes a vertical transfer channel region and a plurality of vertical transfer electrodes formed on the vertical transfer channel region. The horizontal charge transfer portion includes a horizontal transfer channel region, a plurality of first horizontal transfer electrodes formed on the horizontal transfer channel region, and a plurality of second horizontal transfer electrodes arranged between the plurality of first horizontal transfer electrodes. A potential below the first horizontal transfer electrode is higher than a potential below the second horizontal transfer electrode that is arranged adjacent to the first horizontal transfer electrode and backward along a transfer direction with respect to the first horizontal transfer electrode.

Abstract: A method capable of removing dangling bonds generated on a surface of a photodiode is disclosed herein. The method includes steps of providing a semiconductor substrate having a light sensing area and removing dangling bonds at a surface of the light sensing area by diffusing hydrogen ions to the surface of the light sensing area.

Abstract: In order to make a charge couple device including an interconnect layer to contact active areas, a first layer of a first titanium nitride layer on the active areas, and then a series of alternating titanium and titanium nitride layers are deposited to form a composite sandwich structure. This structure is less prone flaking while able to withstand high temperature treatment during fabrication of backside illuminated sensors to improve quantum efficiency and reduce dark current.

Abstract: The invention relates to very small-sized color image sensors.

Abstract: An active pixel cell includes electronic shuttering capability. The cell can be “shuttered” to prevent additional charge accumulation. One mode transfers the current charge to a storage node that is blocked against accumulation of optical radiation. The charge is sampled from a floating node. Since the charge is stored, the node can be sampled at the beginning and the end of every cycle. Another aspect allows charge to spill out of the well whenever the charge amount gets higher than some amount, thereby providing anti blooming.

Abstract: A transmittance overcoat with effectively planar top surface and specified optical and materials properties is applied above a microlens layer to extend the focal length and enhance the performance of long focal length microlenses for semiconductor array color imaging devices. The geometrical optics design factors and microelectronic fabrication sequence to achieve optimized long focal length microlens performance are disclosed. The principal advantages of the adaptive process taught in the present invention is shown to enable real-time compensation adjustments for process and material variations. The overcoat process enables simplified single-layer integrated microlens optics for lowcost, high volume manufacturing of CMOS and CCD color video cameras.

Abstract: In a semiconductor device using a silicon carbide substrate (1), the object of the present invention is to provide a method of manufacturing a semiconductor device that is a buried channel region type transistor having hot-carrier resistance, high punch-through resistance and high channel mobility. This is achieved by using a method of manufacturing a buried channel type transistor using a P-type silicon carbide substrate that includes a step of forming a buried channel region, a source region and a drain region, a step of forming a gate insulation layer after the step of forming the buried channel region, source region and drain region, and a step of exposing the gate insulation layer to an atmosphere containing water vapor at a temperature of 500° C. or more after the step of forming the gate insulation layer. The gate insulation layer is formed by a thermal oxidation method using dry oxygen.

Abstract: A charge coupled device of the present invention includes a charge transfer region layer and a gate insulation film that are formed in the stated order on a semiconductor substrate, first gate electrodes formed at predetermined spaces on the gate insulation film, and second gate electrodes arranged between the first gate electrodes with at least silicon oxide films being interposed therebetween. Each silicon oxide film has constricted portions where the silicon oxide film is in contact with the gate insulation film, and electric insulation films are formed on the constricted portions so as to form sidewalls. This configuration decreases the charge transfer efficiency and increases a dielectric breakdown voltage between gate electrodes. Thus, a charge coupled device having high performance and high dielectric strength is provided.

Abstract: A method for creating a lateral overflow drain, anti-blooming structure in a charge-coupled device, the method includes the steps of providing a substrate of a first conductivity type; providing a layer of silicon dioxide on the substrate; providing a layer of silicon nitride on the silicon dioxide layer; providing a first masking layer on the silicon nitride layer and having an opening in the first masking layer of a dimension which substantially equals a dimension of a subsequently implanted channel stop of the first conductivity type; etching away the exposed silicon nitride within the opening in the first masking layer; implanting ions of the first conductivity type through the first masking layer and into the substrate for creating the channel stop and removing the first masking layer; growing the silicon dioxide layer so that the channel stop is spanned by a thickest field silicon dioxide layer in the etched away portion; patterning a second masking layer having an opening adjacent the channel stop with

Abstract: A color linear image sensor device has a shutter function for selectively draining charges stored in a photodetector circuit. The color linear image sensor device includes first, second, and third linear image sensors having different sensitivities with respect to incident light and arranged successively in sensitivity decreasing order from the outermost, and a shutter gate and a shutter drain for adjusting an amount of exposure to the linear image sensor which has the highest sensitivity to incident light.

Abstract: A process for producing a solid-state imaging device which includes the steps of forming a light-receiving portion of a pixel in a surface region on the substrate, forming above the light receiving portion an inter-layer dielectric having a depression in its surface, forming on the inter-layer dielectric a light transmitting film having in its surface a concave conforming to the depression, forming at the position that covers the concave on the light transmitting film a mask layer with a convexly curved surface, and etching the mask layer and the light transmitting film all together, thereby making the light transmitting film into a shape of convex lens with an upwardly curved surface.

Abstract: A solid-state image pickup device includes: a plurality of light receiving portions arranged in a matrix, and a vertical transfer register which is four-phase driven by first, second, third and fourth transfer electrodes of a three-layer structure. The vertical transfer register is provided for each of columns of said light receiving portions. The first and third transfer electrodes of the first layer are alternately arranged in a charge transfer direction, and the adjacent two of the first and third transfer electrodes extend in parallel to each other between the light receiving portions. With this solid-state image pickup device, the accumulated charge capacity of each transfer region composed of the adjacent transfer electrodes for two-phases is equalized and the area of the light receiving portion is increased irrespective of variations in processed dimension between the transfer electrodes.

Abstract: In a solid state image sensor, tranfer electrodes are formed by selectively etch-removing a single layer of conducting electrode material at a plurality of first regions which divide the single layer of conducting electrode material in a row direction for each one pixel. A patterned mask is formed to cover the first regions and the single layer of conducting electrode material but to expose the single layer of conducting electrode material at a second region above each of the photoelectric conversion sections, and the single layer of conducting electrode material is selectively etch-removed using the patterned mask as a mask. Thereafter, a first conductivity type impurity and a second conductivity type impurity are ion-implanted using the patterned mask and the single layer of conducting electrode material as a mask, to form the photoelectric conversion section at the second region.

Abstract: A multiple-trench photosensor for use in a CMOS imager having an improved charge capacity. The multi-trench photosensor may be either a photogate or photodiode structure. The multi-trench photosensor provides the photosensitive element With an increased surface area compared to a flat photosensor occupying a comparable area on a substrate. The multi-trench photosensor also exhibits a higher charge capacity, improved dynamic range, and a better signal-to-noise ratio. Also disclosed are processes for forming the multi-trench photosensor.

Abstract: White defects caused by a dark-current of a solid-state imaging device is reduced by effectively bringing out gettering capability of a buried getter sink layer. A buried getter sink layer is formed by introducing to the semiconductor substrate a substance of a second element which is a congener of a first element composing a semiconductor substrate, a crystal growth layer is formed by crystal growing a substance of the first element on a surface of the semiconductor substrate, and a solid-state imaging element is formed inside and on the crystal growth layer at a lower temperature than that in the case of forming an extrinsic getter sink layer by introducing a substance of a third element of a different group from the first element on a back surface of the semiconductor substrate.

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 method of planarizing an image sensor substrate is disclosed. The method comprises depositing a first polymer layer over the image sensor substrate. The first polymer layer is patterned to form pillars. Then, a second polymer layer is deposited over the pillars. Optionally, the second polymer layer is etched back.

Abstract: A retrograde and periphery well structure for a CMOS imager is disclosed which improves the quantum efficiency and signal-to-noise ratio of the photosensing portion imager. The retrograde well comprises a doped region with a vertically graded dopant concentration that is lowest at the substrate surface, and highest at the bottom of the well. A single retrograde well may have a single pixel sensor cell, multiple pixel sensor cells, or even an entire array of pixel sensor cells formed therein. The highly concentrated region at the bottom of the retrograde well repels signal carriers from the photosensor so that they are not lost to the substrate, and prevents noise carriers from the substrate from diffusing up into the photosensor. The periphery well contains peripheral logic circuitry for the imager. By providing retrograde and peripheral wells, circuitry in each can be optimized. Also disclosed are methods for forming the retrograde and peripheral well.

Abstract: Generally, and in one form of the invention, a monolithic solid state image-sensing device is disclosed. The device utilizes only a single layer of polysilicon deposition in its fabrication process that is split into two or more phases by very narrow gaps. The single polysilicon layer makes the fabrication process simpler and more compatible with modern semiconductor manufacturing technology. The device also incorporates a lateral anti-blooming drain structure that is formed by a self-aligned diffusion process and does not need a polysilicon gate for its proper function.

Abstract: Methods are disclosed for fabricating any of various semiconductor devices that include a reinforcing substrate bonded to a device substrate, wherein stresses between the two substrates are reduced compared to conventional devices. In the context of a back-surface-incidence (BSI) CCD light sensor, one or more pixels of a light-sensing array are formed on the surface of a “CCD” or “device” substrate. A layer of a curable resin adhesive is applied to the upper surface of the device substrate. A reinforcing substrate (e.g., glass) is placed on the layer of uncured adhesive, and the adhesive is cured. After curing the resin adhesive has a hardness of no greater than 40 (as measured by the JIS-A standard). With such an adhesive, when the resin adhesive cures, no stress is applied to the device substrate even a difference exists in the thermal expansion coefficients of the cured adhesive and the device substrate.

Abstract: Methods of fabricating an image sensor equipped with a lens are disclosed. The disclosed methods can attach a lens directly onto a device without fabricating a separate lens module in a fabrication process of an image sensor device by forming a concave groove on the bottom surface of the lens and coupling the device and the lens by alignment marks after forming a metal convex portion around a pixel array and forming a lens from a mobile material in the final step of device fabrication prior to performing a packaging process.

Abstract: A process for forming a portion of a charge coupled device (CCD) is described. More particularly, wells (105) are formed self-aligned under gate stacks (132, 134). By forming wells (105) self-aligned to respective first and second gates (107, 207) of gate stacks (132, 134), potential for misalignment is reduced. First gates (107) of gate stacks (132) may be coupled together, and second gates (207) of gate stacks (134) may be coupled together, and these first and second gates (107, 207) may be coupled to respective signal sources (23, 24) to form a two-phase CCD.

Abstract: The present invention is a structure for a fast-dump gate (FDG) and a fast-dump drain (FDD) for a charge coupled device. It is envisioned that the charge coupled device be a horizontal readout register of a solid-state image sensor. This structure uses a third layer of polysilicon (or other suitable gate material) to form the fast-dump gate which is in addition to the other two layers of gate material used to form the gates in the horizontal readout register. This allows the channel region under the fast-dump gate (FDG) to form without the use of highly-doped channel stop regions thereby eliminating any potential wells or barriers that may result in transfer inefficiency often time found with other structures.

Abstract: A readout gate electrode is selectively formed on a silicon substrate. An N-type drain region is formed at one end of the readout gate electrode, and an N-type signal storage region is formed at the other end thereof. A P+-type surface shield region is selectively epitaxial-grown on the signal storage region, and a silicide block layer is formed on the surface shield region to cover at least part of the signal storage region. A Ti silicide film is selective epitaxial-grown on the drain region.

Abstract: A fast frame-rate imaging device is produced by a attaching a fiberoptic block to an otherwise ordinary and inexpensive CCD. A part of the fiberoptic block is occluded so as to darken a majority of the active imaging photocells. The CCD imaging device is operated at near its maximum horizontal and vertical clock rates, but multiple image frames are defined within the one previous active photocell array field. The added dark areas in the optical field protect the recent frames still in transit within the active array area from being double exposed and thus corrupted. The serial output of the thus-modified CCD imaging device is reinterpreted to include more frames than originally at a multiple equal to the original array dimension divided by the new array dimension (m·n/m′·n′). Such a modified CCD array uses only one-fourth of the original active area, and is operable at a multiple of the original frame rate.

Abstract: A charge storing layer of a photodiode having an N-type conductivity includes an N+-type additional implant area in the vicinity of a junction between the charge storing layer and an isolation region. The additional implant area provides an increase of stored charge and suppression of increase of the pulse voltage for a substrate shutter, and can be made to have a smaller width within a current design rule.

Abstract: A retrograde well structure for a CMOS imager that improves the quantum efficiency and signal-to-noise ratio of the imager. The retrograde well comprises a doped region with a vertically graded dopant concentration that is lowest at the substrate surface, and highest at the bottom of the well. A single retrograde well may have a single pixel sensor cell, multiple pixel sensor cells, or even an entire array of pixel sensor cells formed therein. The highly concentrated region at the bottom of the retrograde well repels signal carriers from the photosensor so that they are not lost to the substrate, and prevents noise carriers from the substrate from diff-using up into the photosensor. Also disclosed are methods for forming the retrograde well.

Abstract: White defects caused by a dark-current of a solid-state imaging device is reduced by effectively bringing out gettering capability of a buried getter sink layer. A buried getter sink layer is formed by introducing to the semiconductor substrate a substance of a second element which is a congener of a first element composing a semiconductor substrate, a crystal growth layer is formed by crystal growing a substance of the first element on a surface of the semiconductor substrate, and a solid-state imaging element is formed inside and on the crystal growth layer at a lower temperature than that in the case of forming an extrinsic getter sink layer by introducing a substance of a third element of a different group from the first element on a back surface of the semiconductor substrate.

Abstract: The present invention relates to a CMOS image sensor and a fabrication method thereof. The sensor has a photo diode region being extended to a lower portion of an active region in which a transfer gate, sensing gate and reset gate are formed and therefrom the sensitivity of the CMOS image sensor is enhanced. The sensor of the present invention includes a unit cell region having a first region and a second region adjacent to the first region, a PDN region having a first PDN region which is extended from the surface in the first region into the bulk in a direction perpendicular to the surface in an accompanying drawing and a second PDN region which is extended from the lower portion of the first PDN region into the lower portion of the second region in a horizontal direction in the accompanying drawing, and a floating diffusion region and a reset region which are formed in a surface of the second region above the second PDN region.

Abstract: The invention relates to a color solid-state pickup element and a method for producing the same, which can improve the sensitivity by efficiently utilizing light received by the element surface and has an excellent color reappearance property, wherein, in a solid-state pickup element having light receptive elements arrayed and formed on the surface side of a substrate, a light polarizing prism that polarizes light he that has entered from the surface side of the substrate, distributes and irradiates spectral light ha of specified wavelength bands onto a plurality of light receptive areas is provided on the substrate in which the light receptive areas are arrayed and formed; the second light condensing lens that condenses light he irradiated on the surface side of the substrate is provided on the light polarizing prism; an in-layer lens that makes the light hc condensed by the second light condensing lens into a parallel beam hb and causes it to enter the light polarizing prism is provided between the second l

Abstract: The present invention relates to a method for micro-fabricating a pixelless thermal imaging device. The imaging device up-converts a sensed 2-dimensional M/FIR image into a 2-dimensional image in the NIR to visible spectrum in dependence thereupon. A plurality of layers forming an integrated QWIP-LED wafer are crystallographically grown on a surface of a first substrate. The layers comprise an etch stop layer, a bottom contact layer, a plurality of layers forming a QWIP and a LED, and a top contact layer. At the top of the QWIP-LED wafer an optical coupler such as a diffraction grating for coupling at least a portion of incident M/FIR light into modes having an electric field component perpendicular to quantum wells of the QWIP is provided. In following processing steps the first substrate and the etch stop layer are removed. Various different thermal imaging devices are manufactured by changing the order of manufacturing steps, omitting some steps or using different materials.

Abstract: A method of manufacturing a solid-state image sensing device in which a light-sensitive sensor part for photoelectric transfer is formed on the surface of a substrate and a light shielding film for preventing light from being incident on the substrate except the light-sensitive sensor part is formed is provided. First, a transfer electrode is formed on the substrate via an insulating film and after an interlayer insulating film for covering the transfer electrode is further formed, a planarized film for covering the interlayer insulating film is formed. Next, only the location of the planarized film to be a light shielding area for forming a light shielding film is selectively etched, a concave portion is formed and a groove deep enough to reach the vicinity of the surface of the substrate is formed by etching the planarized film over the periphery of the light-sensitive sensor part and near the side of the transfer electrode.

Abstract: In a method of manufacturing a solid-state image pickup device having a virtual gate structure, in a process of forming a profile of a sensor portion, when ion implantation to form a p+ type layer at a substrate surface side is carried out while the ion implantation direction is tilted with respect to the substrate surface, the ion implantation is divisively carried out at plural times and from multiple ion implantation directions so that the total dose amount is matched, whereby impurities can be implanted into any area of the sensor portion and thus no impurities-unformed area occurs.

Abstract: A photodiode for use in an imager having an improved charge leakage. The photodiode has a doped region that is spaced away from the field isolation to minimize charge leakage. A second embodiment of invention provides a second implant to improve charge leakage to the substrate. The photodiodes according to the invention provide improve charge leakage, improved reactions to dark current and an improved signal to noise ratio. Also disclosed are processes for forming the photodiode.