Abstract: A memory device or electronic system may include a memory cell body extending from a substrate, a self-aligned floating gate separated from the memory cell body by a tunneling dielectric film, and a control gate separated from the self-aligned floating gate by a blocking dielectric film. The floating gate is flanked by the memory cell body and the control gate to form a memory cell, and the self-aligned floating gate is at least as thick as the control gate. Methods for building such a memory device are also disclosed.

Abstract: An image pickup device according to the present invention is an image pickup device in which a plurality of pixel are arranged in a semiconductor substrate. Each of the plurality of pixels includes a photoelectric conversion element, a floating diffusion (FD) region, a transfer gate that transfers charges in the first semiconductor region to the FD region, and an amplification transistor whose gate is electrically connected to the FD region. The photoelectric conversion element has an outer edge which has a recessed portion in plan view, a source region and a drain region of the amplification transistor are located in the recessed portion, and the FD region is surrounded by the photoelectric conversion region or is located in the recessed portion in plan view.

Abstract: There is provided a solid-state imaging device including a pixel array unit in which pixels are arrayed in a two-dimensional manner, each of the pixels including a plurality of photoelectric conversion elements and a floating diffusion configured to accumulate an electric charge from the plurality of photoelectric conversion elements, wherein the floating diffusion is shared by at least two or more of the photoelectric conversion elements, and wherein one or more of the plurality of photoelectric conversion elements include a transfer gate configured to transfer an electric charge between the photoelectric conversion elements that are adjacent.

Abstract: A pixel element for an image sensor comprises a semiconductor substrate; a radiation-sensitive element configured to generate electric charges in response to incident radiation, and provided with a charge accumulation region configured to accumulate at least a portion of said electric charges; a passive potential barrier region; and a capacitive element operably connected to the charge-accumulation region of the radiation-sensitive element via the passive potential barrier region, the passive potential barrier region being configured to conduct charges from said charge accumulation region to the capacitive element when at least a predetermined amount of electrical charge has accumulated in said charge accumulation region.

Abstract: This is generally directed to systems and methods for reduced metal lines and control signals in an imaging system. For example, in some embodiments a pixel cell of an imaging system can operate without a row select transistor, and therefore can operate without a row select metal control line. As another example, in some embodiments a pixel cell can share its reset transistor control line with a transfer transistor control line of another pixel cell. In this manner, an imaging system can be created that averages a single metal line per pixel cell. In some embodiments, operation of such reduced-metal line imaging systems can use modified timing schemes of control signals.

Abstract: A complementary metal oxide semiconductor (CMOS) device including a substrate including a first active region and a second active region, wherein each of the first active region and second active region of the substrate are separated by from one another by an isolation region. A n-type semiconductor device is present on the first active region of the substrate, in which the n-type semiconductor device includes a first portion of a gate structure. A p-type semiconductor device is present on the second active region of the substrate, in which the p-type semiconductor device includes a second portion of the gate structure. A connecting gate portion provides electrical connectivity between the first portion of the gate structure and the second portion of the gate structure. Electrical contact to the connecting gate portion is over the isolation region, and is not over the first active region and/or the second active region.

Abstract: An electrically actuated device includes a first electrode, a second electrode, and an active region disposed between the first and second electrodes. The device further includes at least one of dopant initiators or dopants localized at an interface between i) the first electrode and the active region, or ii) the second electrode and the active region, or iii) the active region and each of the first and second electrodes.

Abstract: A device includes a Backside Illumination (BSI) image sensor chip, which includes an image sensor disposed on a front side of a first semiconductor substrate, and a first interconnect structure including a plurality of metal layers on the front side of the first semiconductor substrate. A device chip is bonded to the image sensor chip. The device chip includes an active device on a front side of a second semiconductor substrate, and a second interconnect structure including a plurality of metal layers on the front side of the second semiconductor substrate. A first via penetrates through the BSI image sensor chip to connect to a first metal pad in the second interconnect structure. A second via penetrates through a dielectric layer in the first interconnect structure to connect to a second metal pad in the first interconnect structure, wherein the first via and the second via are electrically connected.

Abstract: A solid-state imaging apparatus which performs a global exposure operation, in a determined imaging region, for performing exposure as matching respective start times and respective end times of all rows, comprises: plural unit pixels arranged in two-dimensional matrix and each comprising a photoelectric converting unit for generating a pixel signal by photoelectric conversion, a holding unit for holding the generated pixel signal, and a first gate for transferring the generated pixel signal to the holding unit; a first controlling line connected commonly to the first gates in the unit pixels on the same row; a vertical controlling circuit for resetting the unit pixel; and a first driving line connected to the first controlling line, and not connected to and thus independent of the vertical controlling circuit, thereby enabling to reduce a current flowing in a power supply of the vertical controlling circuit when driving electrodes of the holding units.

Abstract: In various embodiments, image sensors include photosensitive pixels, associated vertical CCDs, sense nodes each accepting charge from one or more of the vertical CCDs, and readout circuitry accepting signals from the sense nodes.

Abstract: A solid-state imaging apparatus which performs a global exposure operation, in a determined imaging region, for performing exposure as matching respective start times and respective end times of all rows, comprises: plural unit pixels arranged in two-dimensional matrix and each comprising a photoelectric converting unit for generating a pixel signal by photoelectric conversion, a holding unit for holding the generated pixel signal, and a first gate for transferring the generated pixel signal to the holding unit; a first controlling line connected commonly to the first gates in the unit pixels on the same row; a vertical controlling circuit for resetting the unit pixel; and a first driving line connected to the first controlling line, and not connected to and thus independent of the vertical controlling circuit, thereby enabling to reduce a current flowing in a power supply of the vertical controlling circuit when driving electrodes of the holding units.

Abstract: Image sensors are provided. The image sensors may include first and second stacked impurity regions having different conductivity types. The image sensors may also include a floating diffusion region in the first impurity region. The image sensors may further include a transfer gate electrode surrounding the floating diffusion region in the first impurity region. Also, the transfer gate electrode and the floating diffusion region may overlap the second impurity region.

Abstract: A solid-state image pickup device including: a photoelectric conversion section configured to convert incident light into a signal charge; a transfer transistor configured to read the signal charge from the photoelectric conversion section and transfer the signal charge; and an amplifying transistor configured to amplify the signal charge read by the transfer transistor, wherein a compressive stress film having a compressive stress is formed on the amplifying transistor.

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

Abstract: A CIS and a method of manufacturing the same, the CIS including a substrate having a first surface and second surface opposite thereto, the substrate including an APS array region including a photoelectric transformation element and a peripheral circuit region; an insulating interlayer on the first surface of the substrate and including metal wirings electrically connected to the photoelectric transformation element; a light blocking layer on the peripheral circuit region of the second surface of the substrate, exposing the APS array region, and including a plurality of metal wiring patterns spaced apart from one another to form at least one drainage path along a boundary region between the APS array region and the peripheral circuit region; a color filter layer on the second surface of the substrate covering the APS array region and the light blocking layer; and a microlens on the color filter layer on the APS array region.

Abstract: A nonvolatile charge trap memory device is described. The device includes a substrate having a channel region and a pair of source/drain regions. A gate stack is above the substrate over the channel region and between the pair of source/drain regions. The gate stack includes a multi-layer charge-trapping region having a first deuterated layer. The multi-layer charge-trapping region may further include a deuterium-free charge-trapping layer.

Abstract: According to one embodiment, a solid-state image sensing device manufacturing method includes forming a photoelectric converting element, a diffusion layer included in a floating diffusion, and a read transistor, in a photoelectric converting element formation region of a semiconductor substrate, a floating diffusion formation region, and a read transistor formation region located between the photoelectric converting element formation region and the floating diffusion formation region, respectively, and forming a semiconductor layer including a impurity on the diffusion layer on the semiconductor substrate.

Abstract: Provided are three-dimensional nonvolatile memory devices and methods of fabricating the same. The memory devices include semiconductor pillars penetrating interlayer insulating layers and conductive layers alternately stacked on a substrate and electrically connected to the substrate and floating gates selectively interposed between the semiconductor pillars and the conductive layers. The floating gates are formed in recesses in the conductive layers.

Abstract: A semiconductor die with integrated MOSFET and diode-connected enhancement mode JFET is disclosed. The MOSFET-JFET die includes common semiconductor substrate region (CSSR) of type-1 conductivity. A MOSFET device and a diode-connected enhancement mode JFET (DCE-JFET) device are located upon CSSR. The DCE-JFET device has the CSSR as its DCE-JFET drain. At least two DCE-JFET gate regions of type-2 conductivity located upon the DCE-JFET drain and laterally separated from each other with a DCE-JFET gate spacing. At least a DCE-JFET source of type-1 conductivity located upon the CSSR and between the DCE-JFET gates. A top DCE-JFET electrode, located atop and in contact with the DCE-JFET gate regions and DCE-JFET source regions. When properly configured, the DCE-JFET simultaneously exhibits a forward voltage Vf substantially lower than that of a PN junction diode while the reverse leakage current can be made comparable to that of a PN junction diode.

Abstract: A detector device and method of its fabrication are disclosed. Illustratively, an additional via is present through an insulator layer over a gate channel region which is on top of the channel region. The additional via is filled with conductor material. The conductor material is removed to form a chamber leading to one side of the gate channel region. Furthermore, a nanopore is etched from the chamber through the channel region.

Abstract: An image sensor includes a first device isolation layer separating a plurality of pixels from one another, and a second device isolation layer disposed along inner side surfaces of parts of the first device isolation layer that extend around the pixels. The second device isolation layer delimits an active region of the semiconductor substrate. Each pixel includes a photoelectric converter, a floating diffusion region, a ground region, and a gate of a transfer transistor. The gate extends into the active region of the semiconductor substrate. The ground region is electrically connected to a ground voltage terminal.

Abstract: A non-volatile memory is formed on a substrate. The non-volatile memory includes an isolation structure, a floating gate, and a gate dielectric layer. The isolation structure is disposed in the substrate to define an active area. The floating gate is disposed on the substrate and crosses over the active area. The gate dielectric layer is disposed between the floating gate and the substrate. The floating gate includes a first region and a second region. An energy band of the second region is lower than an energy band of the first region, so that charges stored in the floating gate are away from an overlap region of the floating gate and the gate dielectric layer.

Abstract: The present invention provides a high-speed charge-transfer photodiode encompassing a first conductivity type semiconductor layer (20) serving as a charge-generation region; and a second conductivity type surface-buried region (21a) serving as a charge-transfer region of charges generated by the charge-generation region, wherein a specified direction in the surface-buried region (21a) provided along a plane parallel to a surface of the semiconductor layer (20) is assigned as a charge-transfer direction of the charges, and at least one of a variation of widths of the surface-buried region (21a) measured in an orthogonal direction to the charge-transfer direction and a variation of impurity concentration distributions of the surface-buried region (21a), which are measured along the charge-transfer direction, is determined such that an electric field distribution in the charge-transfer direction is constant.

Abstract: A floating diffusion (331) is created substantially at center of the light-receiving surface of an embedded photodiode (31), with a gate electrode of a transfer transistor (32) surrounding the floating diffusion. The concentration (or depth) of impurities in a p+-type semiconductor region, n-type semiconductor region or p-well region is changed in an inclined form so that a potential gradient being inclined downwards from the circumference to the center is created when an appropriate bias voltage is applied to the pn junction. The photocharges produced by incident light are rapidly moved along the potential gradient toward the center. Even in the case where the photocharge storage time is short, the photocharges can be efficiently collected since the maximum moving distance from the circumference of the photodiode (31) to the floating diffusion (331). Thus, the photocharges produced by the photodiode (31) are efficiently utilized, whereby the detection sensitivity is improved.

Abstract: A gate driver circuit includes a driving section and a wiring section. The wiring section receives a plurality of signals from an external device. The driving section includes a plurality of stages providing a plurality of gate lines with a gate signal. The wiring section includes first and second signal wirings. The first signal wiring is disposed adjacent to a first side of the driving section, where the first side receives the signals from the wiring section. The second signal wiring is disposed adjacent to a portion that is disposed at an outer side of the driving section and the first signal wiring. Therefore, a signal applied to the first signal wiring is prevented from being delayed by the second signal wiring. Furthermore, a distortion of signal applied to the gate driver and a maloperation of the gate driver are prevented.

Abstract: A method for manufacturing Flash memory devices includes forming a well region in a substrate, depositing a gate dielectric layer overlying the well region, and depositing a first polysilicon layer overlying the gate dielectric layer. The method also includes depositing a dielectric layer overlying the first polysilicon layer and depositing a second polysilicon layer overlying the dielectric layer to form a stack layer. The method simultaneously patterns the stack layer to form a first flash memory cell, which includes a first portion of the second polysilicon layer overlying a first portion of the dielectric layer overlying a first portion of first polysilicon layer and to form a select device, which includes a second portion of second polysilicon layer overlying a second portion of dielectric layer overlying a second portion of first polysilicon layer. The method further includes forming source/drain regions using ion implant.

Abstract: According to one embodiment, a solid-state imaging device includes a semiconductor substrate, a photodiode provided in the semiconductor substrate and including a first conductivity type semiconductor layer, a shield layer provided on the photodiode, an upper portion or entirety of the shield layer being constituted of a second conductivity type semiconductor layer, and a transfer transistor provided on the semiconductor substrate to transfer charges stored in the photodiode to a floating diffusion region. An upper surface of the shield layer is higher than an upper surface of the semiconductor substrate.

Abstract: A data storage and a semiconductor memory device including the same are provided, the data storage including a lower electrode, a first discharge prevention layer stacked on the lower electrode, a phase-transition layer on the first discharge prevention layer, a second discharge prevention layer stacked on the phase-transition layer, and an upper electrode stacked on the second discharge prevention layer. The phase transition layer includes oxygen and exhibits two different resistance characteristics depending on whether an insulating property thereof changed. The first and second discharge prevention layers block discharge of the oxygen from the phase transition layer.

Abstract: An image pickup device according to the present invention is an image pickup device in which a plurality of pixel are arranged in a semiconductor substrate. Each of the plurality of pixels includes a photoelectric conversion element, a floating diffusion (FD) region, a transfer gate that transfers charges in the first semiconductor region to the FD region, and an amplification transistor whose gate is electrically connected to the FD region. The photoelectric conversion element has an outer edge which has a recessed portion in plan view, a source region and a drain region of the amplification transistor are located in the recessed portion, and the FD region is surrounded by the photoelectric conversion region or is located in the recessed portion in plan view.

Abstract: A memory device and a method of fabricating the same are provided. The memory device includes a tunneling dielectric layer on a substrate, a charge storage layer on the tunneling dielectric layer, a blocking dielectric layer on the charge storage layer, the blocking dielectric layer including a first dielectric layer having silicon oxide, a second dielectric layer on the first dielectric layer and having aluminum silicate, and a third dielectric layer formed on the second dielectric layer and having aluminum oxide, and an upper electrode on the blocking dielectric layer.

Abstract: A method of fabricating an MOS device is provided. First, gates and source/drain regions of transistors are formed on a substrate. A photodiode doped region and a floating node doped region are formed in the substrate. Thereafter, a spacer stacked layer including a bottom layer, an inter-layer and a top layer is formed to cover each gate of the transistors. Afterwards, a first mask layer having an opening exposing at least the photodiode doped region is formed on the substrate, and then the top layer exposed by the opening is removed. Next, the first mask layer is removed, and then a second mask layer is formed on a region correspondingly exposed by the opening. A portion of the top layer and the inter-layer exposed by the second mask layer is removed to form spacers on sidewalls of the gates.

Abstract: Non-volatile memory (NVM) devices are disclosed. In one aspect, a NVM device may include a substrate, and a field-effect transistor (FET). The FET may include a first doped region in the substrate and a second doped region in the substrate. The first and the second doped regions may define a channel region of the substrate between them. An insulating layer may overlie the channel region. A floating gate may overlie the insulating layer. Charge of an amount that encodes a value may be stored on the floating gate. The floating gate and the first and the second doped regions may be shaped such that the floating gate defines with the first doped region a first border of a first length, and the floating gate defines with the second doped region a second border of a second length that is less than 90% of the first length.

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: Provided are three-dimensional nonvolatile memory devices and methods of fabricating the same. The memory devices include semiconductor pillars penetrating interlayer insulating layers and conductive layers alternately stacked on a substrate and electrically connected to the substrate and floating gates selectively interposed between the semiconductor pillars and the conductive layers. The floating gates are formed in recesses in the conductive layers.

Abstract: According to an aspect of the invention, there is provided a semiconductor device including a plurality of memory cells, comprising a plurality of floating gate electrodes which are formed on a tunnel insulating film formed on a semiconductor substrate and have an upper portion which is narrower in a channel width direction than a lower portion, an interelectrode insulating film formed on the floating gate electrodes, and a control gate electrode which is formed on the interelectrode insulating film formed on the floating gate electrodes and partially buried between the floating gate electrodes opposing each other.

Abstract: An object of the present invention is to provide a photoelectric conversion device, wherein improvement of charge transfer properties when charge is output from a charge storage region and suppression of dark current generation during charge storage are compatible with each other. This object is achieved by forming a depletion voltage of a charge storage region in the range from zero to one half of a power source voltage (V), forming a gate voltage of a transfer MOS transistor during a charge transfer period in the range from one half of the power source voltage to the power source voltage (V) and forming a gate voltage of the transfer MOS transistor during a charge storage period in the range from minus one half of the power source voltage to zero (V).

Abstract: A semiconductor memory element is described, including a substrate including a source region, a drain region, and a channel region, a tunnel oxide over the channel region of the substrate, a charge storage layer over the tunnel oxide, a charge blocking layer over the charge storage layer, and a control gate over the charge blocking layer. The charge blocking layer further includes a first layer including a transition metal oxide, a second layer including a metal silicate, a third layer including the transition metal oxide of the first layer.

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 system and method employing at least one semiconductor device, or an arrangement of insulating and metal layers, having at least one detecting region which can include, for example, a recess or opening therein, for detecting a charge representative of a component of a polymer, such as a nucleic acid strand, proximate to the detecting region, and a method for manufacturing such a semiconductor device. The system and method can thus be used for sequencing individual nucleotides or bases of ribonucleic acid (RNA) or deoxyribonucleic acid (DNA). The semiconductor device includes at least two doped regions, such as two n-type regions implanted in a p-type semiconductor layer or two p-type regions implanted in an n-type semiconductor layer. The detecting region permits a current to pass between the two doped regions in response to the presence of the component of the polymer, such as a base of a DNA or RNA strand.

Abstract: A nonvolatile memory element which is provided with a floating gate electrode and a high withstand voltage transistor which is provided with a thick gate insulating film are formed over one substrate without increase in a driving voltage of the nonvolatile memory element. A stacked film of a first insulating film and a second insulating film is formed between an island-like semiconductor region and a floating gate electrode of the nonvolatile memory element and between an island-like semiconductor region and a gate electrode of the transistor. The first insulating film overlapping with the floating gate electrode is removed, and the insulating film between the island-like semiconductor region and the floating gate electrode is formed thinner than the gate insulating film of the transistor.

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 nonvolatile memory device using a resistance material and a method of fabricating the same are provided. The nonvolatile memory device includes a switching element, and a data storage part electrically connected to the switching element. In the data storage part, a lower electrode is connected to the switching element, and an insulating layer is formed on the lower electrode to a predetermined thickness. The insulating layer has a contact hole exposing the lower electrode. A data storage layer is filled in the contact hole and the data storage layer is formed of transition metal oxide. An upper electrode is formed on the insulating layer and the data storage layer.

Abstract: A semiconductor device formed on a semiconductor substrate may include a component formed in a contact trench located in an active cell region. The component may comprise a barrier metal deposited on a bottom and portions of sidewalls of the contact trench and a tungsten plug deposited in a remaining portion of the contact trench. The barrier metal may comprise first and second metal layers. The first metal layer may be proximate to the sidewall and the bottom of the contact trench. The first metal layer may include a nitride. The second metal layer may be between the first metal layer and the tungsten plug and between the tungsten plug and the sidewall. The second metal layer covers portions of the sidewalls of not covered by the first metal layer.

Abstract: A non-volatile memory device and a method for fabricating the same are provided. The method includes: forming a gate structure on a substrate, the gate structure including a first insulation layer, a first electrode layer for a floating gate and a second insulation layer; forming a third insulation layer on the gate structure covering predetermined regions of the substrate adjacent to the gate structure; and forming a second electrode layer for a control gate on the third insulation layer disposed on sidewalls of the gate structure and the predetermined regions of the substrate.

Abstract: An apparatus for and a method of operating an array of pixels of an image sensor, where each pixel includes at least a photosensor, an associated storage device and a floating diffusion region and the array of pixels is configured in a plurality of rows and columns. The photosensors associated with the pixels are reset and charges are accumulated in the photosensor. The accumulated charges are then globally transferred to storage devices associated with the pixels. A rolling double reset is used to reduce the deleterious effects on the accumulated charges stored in the storage devices. The accumulated charges stored in the storage devices are transferred to floating diffusion regions associated with the pixels and the charges residing in the floating diffusion region are read out. In a second embodiment the storage device is eliminated and the rolling double reset is used to reduce the deleterious effects on the accumulated charges stored in the floating diffusion region.

Abstract: In a non-volatile memory structure, the source/drain regions are surrounded by a nitrogen-doped region. As a result, an interface between the substrate and the charge trapping layer above the nitrogen-doped region is passivated by a plurality of nitrogen atoms. The nitrogen atoms can improve data retention, and performance of cycled non-volatile memory devices.

Abstract: According to an aspect of the invention, there is provided a semiconductor device including a plurality of memory cells, comprising a plurality of floating gate electrodes which are formed on a tunnel insulating film formed on a semiconductor substrate and have an upper portion which is narrower in a channel width direction than a lower portion, an interelectrode insulating film formed on the floating gate electrodes, and a control gate electrode which is formed on the interelectrode insulating film formed on the floating gate electrodes and partially buried between the floating gate electrodes opposing each other.

Abstract: Methods of forming and operating a back-side trap non-volatile memory cell. Method of forming a back-side trap non-volatile memory cell include forming a trapping material, forming two or more sub-layers of dielectric material on the trapping material, wherein a conduction band offset of each sub-layer of dielectric material is less than the conduction band offset of the material upon which it is formed, and forming a channel region on the two or more sub-layers of dielectric material. Methods of operating a back-side trap non-volatile memory cell include programming the memory cell via direct tunneling of carriers through an asymmetric band-gap tunnel insulator layer having two or more sub-layers formed beneath a channel region and having layers of material of increasing conduction band offset, and trapping the carriers in a trapping layer formed under the tunnel insulator layer.

Abstract: In designing a FLOTOX EEPROM of a dual cell type, a consideration should be given to the layout of cells for microminiaturization of the FLOTOX EEPROM. The FLOTOX EEPROM of the dual cell type includes two paired floating gates (25a, 25b), two tunnel windows (33a, 33b) a shared source (27), a shared control gate (26), select gates (29a, 29b), and a shared drain 28. Thus, a higher reliability design and a higher breakdown voltage design are achieved for the FLOTOX EEPROM of the dual cell type.

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.