Abstract: A photoelectric conversion apparatus includes a plurality of photoelectric conversion elements configured to convert incident light to electric carriers, an amplifier MOS transistor shared by the plurality of photoelectric conversion elements, a plurality of floating diffusions connected to the gate electrode of the amplifier MOS transistor, and a plurality of transfer MOS transistors arranged corresponding to the respective photoelectric conversion elements, each of the transfer MOS transistors transferring electric carriers from corresponding one of the photoelectric conversion elements to corresponding one of the floating diffusions. In such a photoelectric conversion apparatus, at least two of the floating diffusions are electrically connected to each other with a wiring line included in the same wiring layer as the gate electrode of the amplifier MOS transistor.

Abstract: According to one embodiment, a photodetector includes a substrate, a first semiconductor region, a second semiconductor region, a third semiconductor region, an insulating film, a first electrode, a second electrode, and a shield film. The first semiconductor region is provided on a major surface of the substrate. The second semiconductor region and the third semiconductor region are provided in a substantially identical plane to the first semiconductor region. The second semiconductor region is contacted with the first semiconductor region and has an impurity concentration higher than the first semiconductor region. The third semiconductor region is contacted with the second semiconductor region. The shield film is provided on the insulating film and electrically connected to the first electrode. A periphery of the shield film is disposed to cover an interface between the second semiconductor region and the third semiconductor region in a planar view.

Abstract: A transistor of a pixel cell for use in a CMOS imager with a low threshold voltage of less than about 0.4 V is disclosed. The transistor is provided with high dosage source and drain regions around the gate electrode and with the halo implanted regions and/or the lightly doped LDD regions and/or the enhancement implanted regions omitted from at least one side of the gate electrode. The low threshold transistor is electrically connected to a high voltage transistor with a high threshold voltage of about 0.7 V.

Abstract: A method of manufacturing a semiconductor device includes the steps of forming a gate electrode of a transistor on an insulator layer on a surface of a semiconductor substrate, forming an isolation region by performing ion implantation of an impurity of a first conductivity type into the semiconductor substrate, forming a lightly doped drain region by performing, after forming a mask pattern including an opening portion narrower than a width of the gate electrode on an upper layer of the gate electrode of the transistor, ion implantation of an impurity of a second conductivity type near the surface of the semiconductor substrate with the mask pattern as a mask, and forming a source region and a drain region of the transistor by performing ion implantation of an impurity of the second conductivity type into the semiconductor substrate after forming the gate electrode of the transistor.

Abstract: Image sensors include a second photoelectric conversion device disposed in a lower portion of a substrate and a first photoelectric conversion device extending between the secondary photoelectric conversion device and a light receiving surface of the substrate. Electrical isolation between the first and second photoelectric conversion devices is provided by a photoelectron barrier, which may be an optically transparent electrically insulating material. MOS transistors may be utilized to transfer photoelectrons generated within the first and second photoelectric conversion devices to a floating diffusion region within the image sensor. These transistors may represent one example of means for transferring photoelectrons generated in the first and second photoelectric conversion devices to a floating diffusion region in the substrate, in response to first and second gating signals, respectively. The first and second gating signals may be active during non-overlapping time intervals.

Abstract: An imaging device includes a read circuit having a bias circuit for biasing the signal currents output from a sensor array to correct variations of the sensor array. The bias current is determined so that the number of pixel data output from the read circuit which are below or above the threshold is equal to a specified number setting for the number of pixel data. A fixed pattern noise (FPN) correction circuit determines the full scale of the FPN correction current based on the bias current.

Abstract: A solid-state imaging device includes a photoelectric conversion portion that is provided above an imaging surface of a substrate, and a plurality of readout circuit portions that are provided below the photoelectric conversion portion on the imaging surface. The photoelectric conversion portion includes a photoelectric conversion film that receives incident light and produces a signal charge, and a first electrode and a second electrode that sandwich the photoelectric conversion film, and the first electrode, the photoelectric conversion film, and the second electrode are sequentially layered upward on the imaging surface. Further, each of the readout circuit portions includes a readout circuit that is electrically connected with the first electrode and reads out the signal charge produced by the photoelectric conversion portion, and a ground electrode that is grounded, and the ground electrode is interposed between the readout circuit and the first electrode on the imaging surface.

Abstract: CMOS image sensors and methods of fabricating the same. The CMOS image sensors include a pixel array region having an active pixel portion and an optical block pixel portion which encloses the active pixel portion. The optical block pixel portion includes an optical block metal pattern for blocking light. The optical block metal pattern may be connected to a ground portion.

Abstract: A pixel of an image sensor, the pixel including a plurality of photoelectric conversion elements arranged in a semiconductor substrate; and a first transfer circuit for sequentially transferring photo-charges generated by each of the plurality of photoelectric conversion elements to a first floating diffusion node.

Abstract: An image sensor includes an active region including a photoelectric conversion region and a floating diffusion region, which are separated from each other, defined by a device isolation region on a semiconductor substrate, and a transfer transistor including a first sub-gate provided on an upper surface of the semiconductor substrate and a second sub-gate extending within a recessed portion of the semiconductor substrate on the active region between the photoelectric conversion region and the floating diffusion region, wherein the photoelectric conversion region includes a plurality of photoelectric conversion elements, which vertically overlap each other within the semiconductor substrate and are spaced apart from the recessed portion.

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 photoelectric conversion apparatus includes a plurality of photoelectric conversion elements configured to convert incident light to electric carriers, an amplifier MOS transistor shared by the plurality of photoelectric conversion elements, a plurality of floating diffusions connected to the gate electrode of the amplifier MOS transistor, and a plurality of transfer MOS transistors arranged corresponding to the respective photoelectric conversion elements, each of the transfer MOS transistors transferring electric carriers from corresponding one of the photoelectric conversion elements to corresponding one of the floating diffusions. In such a photoelectric conversion apparatus, at least two of the floating diffusions are electrically connected to each other with a wiring line included in the same wiring layer as the gate electrode of the amplifier MOS transistor.

Abstract: An image sensor includes a first substrate including a driving element, a first insulation layer on the first substrate and on the driving element, a second substrate including a photoelectric conversion element, and a second insulation layer on the second substrate and on the photoelectric conversion element. A surface of the second insulation layer is on an upper surface of the first insulation layer. The image sensor includes a conductive connector penetrating the second insulation layer and a portion of the first insulation layer. Methods of forming image sensors are also disclosed.

Abstract: Silicon carbide metal-oxide semiconductor field effect transistors (MOSFETs) may include an n-type silicon carbide drift layer, a first p-type silicon carbide region adjacent the drift layer and having a first n-type silicon carbide region therein, an oxide layer on the drift layer, and an n-type silicon carbide limiting region disposed between the drift layer and a portion of the first p-type region. The limiting region may have a carrier concentration that is greater than the carrier concentration of the drift layer. Methods of fabricating silicon carbide MOSFET devices are also provided.

Abstract: A hard mask material film is formed on a semiconductor substrate and a recess is formed immediately below an opening in an upper surface of the semiconductor substrate. Next, a p-type region is formed immediately below the recess by implanting impurities into an imaging region using the hard mask material film as a mask. Moreover, a trench is formed by further processing the recess in a processing region. A half-buried dielectric film and a STI are formed by burying a dielectric material in the recess and the trench to remove the hard mask material film. Next, two electrodes are formed so as to overlap the half-buried dielectric film and the STI, respectively, and impurities are implanted into the imaging region using one electrode and the half-buried dielectric film as a mask, and hence a n-type region constituting a photodiode is formed in a region being in contact with the p-type region in the semiconductor substrate.

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

Abstract: A photoelectric conversion apparatus includes: a first interlayer insulation film disposed on a semiconductor substrate; a first plug disposed in a first hole in the first interlayer insulation film, and serving to electrically connect between a plurality of active regions disposed in the semiconductor substrate, between gate electrodes of a plurality of MOS transistors, or between the active region and the gate electrode of the MOS transistor, not through the wiring of the wiring layer; and a second plug disposed in a second hole in the first interlayer insulation film, the second plug being electrically connected to the active region, wherein a wiring arranged over the second plug and closest to the second plug is electrically connected to the second plug, and the wiring electrically connected to the second plug forms a portion of dual damascene structure. By such a structure, incidence efficiency of light onto a photoelectric conversion element can be improved.

Abstract: A photosensor includes a semiconductor thin film for photoelectric conversion having a first side portion and a second side portion. A source electrode extends in the longitudinal direction of the semiconductor thin film and has a side edge portion that overlaps the first side portion of the semiconductor thin film, and a drain electrode extends in the longitudinal direction and has a side edge portion that overlaps the second side portion of the semiconductor thin film. At least one of the side edge portions of the source and drain electrodes has protruding portions which are arranged along the longitudinal direction and which overlap the semiconductor thin film, and notched portions formed between the protruding portions. An ohmic contact layer is formed between the semiconductor thin film and the protruding portions of the at least one of the side edge portions of the source and drain electrodes.

Abstract: A backside illuminated image sensor includes a photodiode, formed below the top surface of a semiconductor substrate, for receiving light illuminated from the backside of the semiconductor substrate to generate photoelectric charges, a reflecting gate, formed on the photodiode over the front upper surface of the semiconductor substrate, for reflecting light illuminated from the backside of the substrate and receiving a bias to control a depletion region of the photodiode, and a transfer gate for transferring photoelectric charges from the photodiode to a sensing node of a pixel.

Abstract: A solid-state imaging device with a structure such that an electrode for reading a signal charge is provided on one side of a light-receiving sensor portion constituting a pixel; a predetermined voltage signal V is applied to a light-shielding film formed to cover an image pickup area except the light-receiving sensor portion; a second-conductivity-type semiconductor area is formed in the center on the surface of a first-conductivity-type semiconductor area constituting a photo-electric conversion area of the light-receiving sensor portion; and areas containing a lower impurity concentration than that of the second-conductivity-type semiconductor area is formed on the surface of the first-conductivity-type semiconductor area at the end on the side of the electrode and at the opposite end on the side of a pixel-separation area.

Abstract: An infrared sensor IC and an infrared sensor, which are extremely small and are not easily affected by electromagnetic noise and thermal fluctuation, and a manufacturing method thereof are provided. A compound semiconductor that has a small device resistance and a large electron mobility is used for a sensor (2), and then, the compound semiconductor sensor (2) and an integrated circuit (3), which processes an electrical signal output by the compound semiconductor sensor (2) and performs an operation, are arranged in a single package using hybrid formation. In this manner, an infrared sensor IC that can be operated at room temperature can be provided by a microminiature and simple package that is not conventionally produced.

Abstract: The present invention relates to a field effect transistor (FET) containing a channel extending perpendicularly across at least one V-shaped trench and along the interior surfaces thereof. In one aspect, a semiconductor device is provided that includes a semiconductor substrate having first and second device regions that are isolated from each other by an isolation region. The first device region has a planar surface with a first crystalline orientation, and the second device region has at least one V-shaped trench which has interior surfaces with a second, different crystalline orientation. A first FET is located at the first device region and contains a channel extending along the planar surface of the first device region. A second, complementary FET is located at the second device region and contains a channel extending perpendicularly across the at least one V-shaped trench and along the interior surfaces thereof.

Abstract: It is intended to provide a CMOS image sensor with a high degree of pixel integration. A solid-state imaging device comprises a signal line (256) formed on a Si substrate, an island-shaped semiconductor formed on the signal line, and a pixel selection line (255). The island-shaped semiconductor includes: a first semiconductor layer (252) connected to the signal line; a second semiconductor layer (251) located above and adjacent to the first semiconductor layer; a gate (253) connected to the second semiconductor layer through an insulating film; and a charge storage section comprised of a third semiconductor layer (254) connected to the second semiconductor layer and adapted, in response to receiving light, to undergo a change in amount of electric charges therein; a fourth semiconductor layer (250) located above and adjacent to the second and third semiconductor layers. The pixel selection line (255) is connected to the fourth semiconductor layer formed as a top portion of the island-shaped semiconductor.

Abstract: Provided is a stacked image sensor. Particularly, provided are a stacked image sensor including a photosensitive element portion having a photo-conductive thin film on an upper portion of a wafer where a peripheral circuit is formed and a method of manufacturing the stacked image sensor. In the stacked image sensor according to the present invention, since a wafer where a circuit is formed and a photosensitive element portion are formed in a stacked structure, a whole size of the image sensor can be reduced, and there is no optical crosstalk due to absorption of incident light to adjacent pixels. In addition, since a photo-conductive element having a high light absorbance is used, a high photo-electric conversion efficiency can be obtained. In addition, in the method of manufacturing a stacked image sensor according to the present invention, since the upper photosensitive element can be formed by using a simple low-temperature process, a production cost can be reduced.

Abstract: A solid-state imaging device having a plurality of image pixels arranged along a main surface of a semiconductor substrate, wherein each of the plurality of image pixels includes a photodiode that converts incident light into an electric charge and a transmission gate that is formed so as to have a crossing area that partially passes over the photodiode when seen from the thickness direction of the semiconductor substrate. The transmission gate of the solid-state imaging device is formed in a manner that (i) a first region including a laminated body of a silicon film and a silicide film, and (ii) a second region that includes the silicon film and does not include the silicide film, both arranged along a main surface of the semiconductor substrate, and the second region in the transmission gate is formed in at least one part of the crossing area.

Abstract: The present invention relates to a method of fabricating a semiconductor substrate that includes forming at least first and second device regions, wherein the first device region includes a first recess having interior surfaces oriented along a first set of equivalent crystal planes, and wherein the second device region includes a second recess having interior surfaces oriented along a second, different set of equivalent crystal planes. The semiconductor device structure formed using such a semiconductor substrate includes at least one n-channel field effect transistor (n-FET) formed at the first device region having a channel that extends along the interior surfaces of the first recess, and at least one p-channel field effect transistor (p-FET) formed at the second device region having a channel that extends along the interior surfaces of the second recess.

Abstract: A MIS transistor includes a gate electrode portion, insulating sidewalls formed on side surfaces of the gate electrode portion, source/drain regions and a stress film formed so as to cover the gate electrode portion and the source/drain regions. A height of an upper surface of the gate electrode portion is smaller than a height of an upper edge of each of the insulating sidewalls. A thickness of first part of the stress film located on the gate electrode portion is larger than a thickness of second part of the stress film located on the source/drain regions.

Abstract: A lower cost range-finding image sensor based upon measurement of reflection time of light with reduced fabrication processes compared to standard CMOS manufacturing procedures. An oxide film is formed on a silicon substrate, and two photo-gate electrodes for charge-transfer are provided on the oxide film. Floating diffusion layers for taking charges out from a photodetector layer are provided at the ends of the oxide film, and on the outside thereof are provided a gate electrode for resetting and a diffusion layer for providing a reset voltage.

Abstract: A CMOS image sensor and a method for manufacturing the same. In one example embodiment, a CMOS image sensor includes a field region and an active region, a second conductive bottom region, a first conductive well region, a second conductive top region, and a first conductive high concentration region. The field region and the active region are formed in a first conductive semiconductor substrate. The second conductive bottom region has a first depth in part of the active region. The first conductive well region is formed in the active region. The second conductive top region has a depth that is less than the first depth. The first conductive high concentration region has a depth that is less than the depth of the second conductive top region.

Abstract: An image sensor includes a semiconductor substrate, a photo receiving area in the semiconductor substrate, a gate electrode installed in a lateral side of the photo receiving area on the semiconductor substrate, and a patterned dielectric layer covering the gate electrode, the photo receiving area, and exposing a partial gate electrode. A spacer surrounds the gate electrode on the dielectric layer.

Abstract: Disclosed is a method for manufacturing an image sensor. The method includes a process for removing foreign matter from a non-device area of a wafer before forming contacts in a device area of the wafer. According to an embodiment, an insulating layer formed in the non-device area is removed by performing a first process with respect to the non-device area. Then, a contact can be formed in the insulating layer in the device area.

Abstract: A semiconductor imaging device includes a photodetection region formed of a diffusion region of a first conductivity type formed in an active region of a silicon substrate at a first side of a gate electrode such that a top part thereof is separated from a surface of the silicon substrate and such that an inner edge part invades underneath a channel region right underneath the gate electrode, a shielding layer formed of a second conductivity type at a surface of the silicon substrate at the first side of the gate electrode such that an inner edge part thereof is aligned with a sidewall surface of the gate electrode at the first side, a floating diffusion region formed in the active region at a second side of the gate electrode, and a channel region formed right underneath said gate electrode, wherein the channel region includes a first channel region part formed adjacent to the shielding layer and a second channel region part formed adjacent to the floating diffusion region, wherein the second channel region

Abstract: A photoelectric conversion device comprises a first semiconductor region of a first conductivity type; a second semiconductor region of a second conductivity type serving as a photoelectric conversion element together with a part of the first semiconductor region; a gate electrode transferring electric carriers generated in the photoelectric conversion element to a third semiconductor region of the second conductivity type. Moreover, the photoelectric conversion device comprises an isolation region for electrically isolating the second semiconductor region from a fourth semiconductor region of the second conductivity type adjacent to the second semiconductor region. Wiring for applying voltage to the gate electrode is arranged on the isolation region. Here, a fifth semiconductor region of the second conductivity type having an impurity concentration lower than that of the fourth semiconductor region is provided between the fourth semiconductor region and the isolation region.

Abstract: A photo detector is disclosed. The photo detector includes a substrate, a first patterned semiconductor layer with a first state, a dielectric layer, a patterned conductive layer, an inter-layer dielectric, a second patterned semiconductor layer with a second state, two first electrodes disposed on the inter-layer dielectric and two second electrodes disposed on portions of the second semiconductor layer. The first patterned semiconductor layer having a first doping region and a second doping region is disposed on a transistor region of the substrate. The dielectric layer is disposed to cover the substrate and the first semiconductor layer, the patterned conductive layer is disposed on the dielectric layer, and the inter-layer dielectric having at least two openings adapted to expose the first doping region and the second doping region is disposed to cover the dielectric layer.

Abstract: Embodiments of the invention provide an image sensor having an improved dynamic range. A pixel cell comprises at least one transistor structure. The transistor structure comprises at least one semiconductor channel region, at least one gate for controlling the channel region, and first and second leads respectively coupled to a source region on one side of the at least one channel region and a drain region on an opposite side of the at least one channel region. The transistor structure has at least two threshold voltages associated with the at least one channel region, and an I-V characteristic of the transistor structure is determined at least in part by the threshold voltages.

Abstract: A photoelectric-conversion apparatus includes a photoelectric-conversion area where a plurality of photoelectric-conversion elements configured to convert incident light into electrical charges, a plurality of floating-diffusion areas, a plurality of transfer-MOS transistors configured to transfer electrical charges of the photoelectric-conversion element to the floating-diffusion area, and a plurality of amplification-MOS transistors configured to read and transmit a signal generated based on the transferred electrical charges to an output line are provided. An antireflection film is provided on a light-receiving surface of the photoelectric-conversion element. The gate of the amplification-MOS transistor is electrically connected to one floating-diffusion area by providing one conductor in a single contact hole, and the anti-reflection film covers the photoelectric-conversion area except a base part of the contact hole.

Abstract: In order to detect light with in particular a high blue component, the inversion zone and the space charge zone of a CMOS-like structure are used. In conjunction with an at least partly transparent gate electrode, in particular a transparent conductive oxide or a patterned gate electrode, it becomes possible to absorb the short-wave component of incident light within the inversion zone and to reliably conduct away the generated charge carrier pairs to first and second contacts. During operation, a control voltage is applied to the gate electrode with a magnitude that generates a continuous inversion zone below the optionally patterned gate electrode.

Abstract: A method and structure for providing a high energy implant in only the red pixel location of a CMOS image sensor. The implant increases the photon collection depth for the red pixels, which in turn increases the quantum efficiency for the red pixels. In one embodiment, a CMOS image sensor is formed on an p-type substrate and the high energy implant is a p-type implant that creates a p-type ground contact under the red pixel, thus reducing dark non-uniformity effects. In another embodiment, a CMOS image sensor is formed on an n-type substrate and a high energy p-type implant creates a p-type region under only the red pixel to increase photon collection depth, which in turn increases the quantum efficiency for the red pixels.

Abstract: An optic wafer for assembly with an imager wafer, the optic wafer comprising a plurality of reliefs in a surface thereof coincident with street locations separating mutually adjacent optic element locations. A wafer assembly that includes the optic wafer and an imager wafer and methods of dicing a wafer assembly are also disclosed.

Abstract: Provided are a semiconductor device and a method of driving the semiconductor device. The semiconductor device includes an optical reaction transistor. The optical reaction transistor includes a semiconductor substrate, a tunnel insulation layer formed on the semiconductor substrate, an optical reaction layer formed on the tunnel insulation layer, a blocking insulation layer formed on the optical reaction layer, and a gate electrode formed on the blocking insulation layer.

Abstract: A pixel sensor cell of improved dynamic range comprises a coupling transistor that couples a capacitor device to a photosensing region (e.g., photodiode) of the pixel cell, the photodiode being coupled to a transfer gate and one terminal of the coupling transistor. In operation, the additional capacitance is coupled to the pixel cell photodiode when the voltage on the photodiode is drawn down to the substrate potential. Thus, the added capacitance is only connected to the imager cell when the cell is nearing its charge capacity. Otherwise, the cell has a low capacitance and low leakage. In an additional embodiment, a terminal of the capacitor is coupled to a “pulsed” supply voltage signal that enables substantially full depletion of stored charge from the capacitor to the photosensing region during a read out operation of the pixel sensor cell. In various embodiments, the locations of the added capacitance and photodiode may be interchanged with respect to the coupling transistor.

Abstract: A floating node structure of a CMOS image sensor disposed in a floating node region defined by an isolation structure of a substrate is described. The floating node structure comprises an n-doped region within the floating node region, a p-well surrounding the periphery and the bottom of the n-doped region in the substrate within the folating node region, a surface passivation layer disposed at least on the surface of the p-well, and a contact plug coupling the n-doped region to a source follower transistor of the CMOS image sensor.

Abstract: A method to fabricate an image sensor includes providing a semiconductor substrate having a pixel region and a periphery region, forming a light sensing element on the pixel region, and forming at least one transistor in the pixel region and at least one transistor in the periphery region. The step of forming the at least one transistor in the pixel region and periphery region includes forming a gate electrode in the pixel region and periphery region, depositing a dielectric layer over the pixel region and periphery region, partially etching the dielectric layer to form sidewall spacers on the gate electrode and leaving a portion of the dielectric layer overlying the pixel region, and forming source/drain (S/D) regions by ion implantation.

Abstract: A method for fabricating a CMOS image sensor may include forming an isolation layer defining an active area on a semiconductor substrate, forming first and second gate electrodes in the transistor area of the semiconductor substrate, forming a photodiode area in the semiconductor substrate at a first side of the first gate electrode, forming an oxide layer over the photodiode area, the oxide layer having a thickness greater than that of the dielectric layer, forming a source/drain extension area in the semiconductor substrate at a second side of the second gate electrode and between the first and second gate electrodes, forming source/drain regions in the transistor area of the semiconductor substrate by ion implantation through the dielectric layer, and forming a complementary ion implantation region in the photodiode area through the oxide layer.

Abstract: A method of fabricating a CMOS image sensor can include forming a first conductive type epitaxial layer on a heavily doped first conductive type substrate, forming a device isolation layer on a prescribed portion of the epitaxial layer, forming a gate electrode on an active area of the epitaxial layer defined by the device isolation layer, forming a second conductive type first diffusion area to be connected to a surface of the epitaxial layer by carrying out ion implantation on the epitaxial layer for forming a photodiode therein, and forming a second conductive type second diffusion area by carrying out ion implantation on a boundary between the gate electrode and the first diffusion area. Accordingly, the gate and the depletion region of the photodiode are connected, thereby suppressing noise generation by enabling electrons trapped by defects to move freely via the depletion area.

Abstract: A photosensor includes a semiconductor thin film for photoelectric conversion having a first side portion and a second side portion. A source electrode extends in the longitudinal direction of the semiconductor thin film and has a side edge portion that overlaps the first side portion of the semiconductor thin film, and a drain electrode extends in the longitudinal direction and has a side edge portion that overlaps the second side portion of the semiconductor thin film. At least one of the side edge portions of the source and drain electrodes has protruding portions which are arranged along the longitudinal direction and which overlap the semiconductor thin film, and notched portions formed between the protruding portions. An ohmic contact layer is formed between the semiconductor thin film and the protruding portions of the at least one of the side edge portions of the source and drain electrodes.

Abstract: An image sensor includes a semiconductor substrate of a first conductivity type, a photodiode of a second conductivity type located in the substrate, a hole accumulated device (HAD) region of the first conductivity type located over the photodiode, a thin surface diffusion region formed on the surface of the HAD region, and a transfer gate located over the surface of the substrate adjacent the HAD region. The image sensor further includes a first channel region of the first conductivity type located in the substrate and aligned below the transfer gate, a second channel region of the second conductivity type located in the substrate between said transfer gate and the first channel region, and an floating diffusion region which is located in the substrate and which electrically contacts the second channel region.

Abstract: In a photoelectric conversion device comprising a photoelectric-conversion section and a peripheral circuit section where signals sent from the photoelectric-conversion section are processed, the both sections being provided on the same semiconductor substrate, a semiconductor compound layer of a high-melting point metal is provided on the source and drain and a gate electrode of an MOS transistor that forms the peripheral circuit section, and the top surface of a semiconductor diffusion layer that serves as a light-receiving part of the photoelectric conversion section is in contact with an insulating layer.

Abstract: Embodiments relate to a horizontal type bipolar junction transistor element (BJT) and a CMOS image sensor having the same to form a photodiode. In embodiments, the bipolar junction transistor as well as collector current may flow uniformly in a horizontal direction, which may increase the entire amount of current. In embodiments, large current gain may be obtained.

Abstract: Embodiments relate to an image sensor and a method for manufacturing an image sensor. According to embodiments, ions of low concentration may be implanted into a photodiode region of a semiconductor substrate to form a photodiode. At least one gate insulating layer pattern may be formed on the semiconductor substrate, and a gate electrode may be formed on each of the at least one gate insulating layer pattern to receive charges from the photodiode. Spacers may be formed at sidewalls of the gate electrode, respectively. A selective epitaxial growth layer may be formed on the photodiode, and ions of low concentration may be obliquely implanted into one side and the other side of the gate electrode to form a low concentration source and a low concentration drain extending below the spacer. Subsequently, a high concentration source and a high concentration drain may be formed on both sides of the gate electrode, respectively.