Abstract: Embodiments of a pixel including a photosensitive region formed in a surface of a substrate and an overflow drain formed in the surface of the substrate at a distance from the photosensitive area, an electrical bias of the overflow drain being variable and controllable. Embodiments of a pixel including a photosensitive region formed in a surface of a substrate, a source-follower transistor coupled to the photosensitive region, the source-follower transistor including a drain, and a doped bridge coupling the photosensitive region to the drain of the source-follower transistor.

Abstract: An approach is provided for forming a backside illuminated image sensor that includes a semiconductor substrate having a front side and backside, a sensor element formed overlying the frontside of the semiconductor substrate, and a capacitor formed overlying the sensor element.

Abstract: An image sensor for a semiconductor light-sensitive device including a semiconductor substrate and a light receiving device configured to receive light and generate a signal from the light. The image sensor may include an electron collecting device formed in the semiconductor substrate to receive at least a portion of the electrons generated by the light in the light receiving device. The image sensor may include a first type device isolation film configured to isolate the light receiving device from the electron collecting device. The image sensor may include a shielding film formed over the semiconductor substrate and configured to shield the first electron collecting device from the light.

Abstract: A backside illuminated image sensor includes a semiconductor substrate having a front side and backside, a sensor element formed overlying the frontside of the semiconductor substrate, and a capacitor formed overlying the sensor element.

Abstract: An image sensor for a semiconductor light-sensitive device including a semiconductor substrate and a light receiving device configured to receive light and generate a signal from the light. The image sensor may include an electron collecting device formed in the semiconductor substrate to receive at least a portion of the electrons generated by the light in the light receiving device. The image sensor may include a first type device isolation film configured to isolate the light receiving device from the electron collecting device. The image sensor may include a shielding film formed over the semiconductor substrate and configured to shield the first electron collecting device from the light.

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

Abstract: A light receiving device comprises a photoelectric conversion element formed on a first-conductivity-type semiconductor substrate, and further comprises a plurality of photoelectron distributors formed on the first-conductivity-type semiconductor substrate. The photoelectron distributor has a first transfer unit for transferring photoelectrons generated in the photoelectric conversion element, a photoelectron hold unit for temporarily holding the photoelectrons generated in the photoelectric conversion element, a second transfer unit for transferring the photoelectrons held in the photoelectron hold unit, and a floating diffusion layer for storing the transferred photoelectrons and converting the photoelectrons to a voltage.

Abstract: A basic device for an image sensor includes a photodiode consisting of a doped area having a first type of conductivity and formed at the surface of a semiconductor substrate having a second type of conductivity, adapted to be biased at a first reference voltage, wherein the photodiode is combined with a device for the transfer, multiplication and insulation of charges, the photodiode being a fully depleted one and including, at the surface of the doped area having a first type of conductivity, a strongly doped region having the second type of conductivity and adapted to be biased at a second reference voltage.

Abstract: A system for imaging a textured surface comprising includes a photoreceptor array having: at least a first photoreceptor and a second photoreceptor, each configured to receive electromagnetic radiation reflected from the textured surface and to generate a signal corresponding thereto; wherein the photoreceptor array is configured to detect an image of the textured surface based on the relative difference between the time of arrival of the signals from the first and second photoreceptors. Methods for imaging a textured surface and fabricating a photoreceptor array structure for imaging a textured surface are also provided.

Abstract: A method for manufacturing a solid-state imaging device in which a charge generator that detects an electromagnetic wave and generates signal charges is formed on a semiconductor substrate and a negative-charge accumulated layer having negative fixed charges is formed above a detection plane of the charge generator, the method includes the steps of: forming an oxygen-feed film capable of feeding oxygen on the detection plane of the charge generator; forming a metal film that covers the oxygen-feed film on the detection plane of the charge generator; and performing heat treatment for the metal film in an inactive atmosphere to thereby form an oxide of the metal film between the metal film and the oxygen-feed film on the detection plane of the charge generator, the oxide being to serve as the negative-charge accumulated layer.

Abstract: A method of manufacturing a solid state imaging device having a photo-electric conversion portion array and a transfer electrode array, these arrays being provided in parallel to each other, upper surfaces and side wall surfaces of the transfer electrode array being covered with a light-shielding layer, and a transparent layer showing an oxidizing property at the time of film formation, the transparent layer being formed on the photo-electric conversion parts and the light-shielding layer.

Abstract: A pickup device according to the present invention includes a photoelectric conversion portion, a charge holding portion configured to include a first semiconductor region, and a transfer portion configured to include a transfer gate electrode that controls a potential between the charge holding portion and a sense node. A second semiconductor region is disposed on a surface of a semiconductor region between the control electrode and the transfer gate electrode. A third semiconductor region is disposed below the second semiconductor region. An impurity concentration of the third semiconductor region is higher than the impurity concentration of the first semiconductor region.

Abstract: In a solid-state image pick-up device in which a photoelectric converting section formed on a semiconductor substrate and a gate oxide film of a transfer path of a charge coupled device (CCD) which is close to the photoelectric converting section are constituted by a laminated film comprising a silicon oxide film (SiO) and a silicon nitride film (SiN), the gas oxide film has a single layer structure in which at least an end on the photoelectric converting section side of the gate oxide film does not contain the silicon nitride film.

Abstract: A solid-state image pickup device including: a pixel region on a semiconductor substrate, the pixel region including: a sensor region for photoelectrically converting incident light; a vertical CCD formed on one side of the sensor region with a readout region interposed between the sensor region and the vertical CCD; and a channel stop region formed on a side opposite from the sensor region with the vertical CCD interposed between the sensor region and the channel stop region; and a vertical transfer electrode on the vertical CCD with an insulating film interposed between the vertical transfer electrode and the vertical CCD. The vertical transfer electrode is formed above the vertical CCD such that width of the vertical transfer electrode and width of a channel region of the vertical CCD are substantially equal to each other.

Abstract: A solid-state imaging device is disclosed. In the solid-state imaging device, plural unit areas, each having a photoelectric conversion region converting incident light into electric signals are provided adjacently, in which each photoelectric conversion region is provided being deviated from the central position of each unit area to a boundary position between the plural unit areas, a high refractive index material layer is arranged over the deviated photoelectric conversion region, and a low refractive index material layer is provided over the photoelectric conversion regions at the inverse side of the deviated direction being adjacent to the high refractive index material layer, and optical paths of the incident light are changed by the high refractive index material layer and the low refractive index material layer, and the incident light enters the photoelectric conversion region.

Abstract: In the manufacture of an electronic device such as an active matrix display, a vertical amorphous PIN photodiode or similar thin-film diode (D) is advantageously integrated with a polysilicon TFT (TFT1, TFT2) in a manner that permits a good degree of optimization of the respective TFT and diode properties while being compatible with the complex pixel context of the display. High temperature processes for making the active semiconductor film (10) of the TFT more crystalline than an active semiconductor film (40) of the diode and for forming the source and drain doped regions (s1,s2, d1,d2) of the TFT are carried out before depositing the active semiconductor film (40) of the diode. Thereafter, the lateral extent of the diode is defined by etching while protecting with an etch-stop film (30) an interconnection film (20) that can provide a doped bottom electrode region (41) of the diode as well as one of the doped regions (s2, g1) of the TFT.

Abstract: Provided is a manufacturing method of a CCD solid-state imaging device having such an impurity concentration distribution with which shading is reduced and formation of a buried channel endowed with a large saturation signal charge amount is made possible. The manufacturing method includes: an oxide layer forming step of forming an oxide layer (12) on a semiconductor substrate (11); an ion implantation step of performing ion implantation through the oxide layer (12) to the semiconductor substrate (11) thereby forming a well in a position corresponding to a charge transfer portion; and an insulation layer forming step of performing insulation layer forming processing to the oxide layer (12) having undergone the ion implantation step, at least in a position corresponding to the well.

Abstract: A solid image capturing element comprising a plurality of vertical shift registers arranged to each correspond to a column of a plurality of light receiving pixels in a matrix arrangement, a horizontal shift register provided on an output side of the plurality of vertical shift registers, and an output section provided on an output side of the horizontal shift register. In this solid image capturing element, a reverse conductive semiconductor region is formed over one major surface of one conductive semiconductor substrate, the plurality of light receiving pixels, the plurality of vertical shift registers, the horizontal shift register, and the output section are formed in the semiconductor region, and a portion of the semiconductor region where the output section is formed has a higher dopant concentration than the portion of the semiconductor region where the horizontal shift register is formed.

Abstract: A source region and drain region are formed in a surface region of a first semiconductor region. Moreover, a second semiconductor region connected to the drain region is formed in the surface region of the first semiconductor region. A third semiconductor region is formed in the first semiconductor region under the second semiconductor region, connected to the second semiconductor region, and accumulates signal charges in accordance with an incident light. A fourth semiconductor region is formed in the surface region of the first semiconductor region between the drain region and source region. Moreover, these source region, drain region, second semiconductor region, and third semiconductor region constitute a pixel, and different voltages are supplied to the drain region in an accumulation period of the signal charges in the pixel, signal readout period, and discharge period of the signal charges.

Abstract: A first gate electrode and a second gate electrode are formed on a semiconductor substrate, and then a resist pattern is formed so as to selectively leave open a portion including an overlap between the first and second gate electrodes. Next, the overlap between the gate electrodes is removed through isotropic etching. Etching is carried out at this time by an amount within a range of 140% to 200% of the film thickness of the second gate electrode. Next, a normal inter-layer insulating film and light-shielding film are formed. It is possible to eliminate the overlap between the gate electrodes adjacent to an opening of the light-shielding film, suppress the height of the light-shielding film at that portion, reduce shading for the light condensed by a lens and thereby improve the light condensing efficiency of the lens.

Abstract: An image sensor and manufacturing process thereof are provided. An image sensor according to an embodiment comprises a first wafer formed with a photodiode cell without a microlens and a second wafer formed with a circuit part including transistor and a capacitor. The first wafer is stacked on the second wafer such that a connecting electrode can be used to electrically connect the photodiode cell of the first wafer to the circuit part of the second wafer.

Abstract: An interline transfer type image sensing device that can be operated at high speed and with low image smear is described. The device incorporates a refractory metal layer which is used for both a light shield over the vertical charge transfer region and as a wiring layer for low resistance strapping of poly crystalline silicon (polysilicon) gate electrodes for the vertical charge transfer region. Plugs provided by a separate metallization layer connect the refractory light shield to the polysilicon gate electrode. These plugs allow high temperature processing after refractory light shield patterning for improved sensor performance without degradation of the polysilicon gate electrode or the refractory lightshield layer.

Abstract: A solid state image pickup device in which an image pickup region composed of a plurality of light-receiving pixel portions 1 and a transfer register 2 for transferring in one direction the signal charges accumulated in the light-receiving pixel portions 1 is formed on the face layer portion side of a semiconductor substrate and which prevents the mixing of signals between the adjacent signals even in the case where an overflow barrier is formed at a deep position for the purpose of enhancing the sensitivity per unit area, wherein barrier regions 15 each being an impurity region continuing in a direction orthogonal to the transfer direction of the transfer register 2 over the entire region of the image pickup region are each formed at a position corresponding to a position between the light-receiving pixel portions 1 adjacent to each other in the transfer direction, whereby a sufficient potential barrier is formed and the mixing of signals is thereby prevented.