An image sensor includes a first substrate. A photoelectric conversion region is in the first substrate. A first interlayer insulating layer is on the first substrate. A transistor includes a bonding insulating layer on the first interlayer insulating layer, a semiconductor layer on the bonding insulating layer, and a first gate on the semiconductor layer. A bias pad is spaced apart from the semiconductor layer by the bonding insulating layer. The bias pad overlaps the first gate in a planar view. A second interlayer insulating layer covers the transistor.

A method of clocking an image sensor which eliminates well bounce effects caused by global current flow in large image sensors during frame readout and line transfer is described. During charge transfer operations in which voltages are applied to VCCD gate contacts that are adjacent to the photodiodes, a compensating voltage may be applied to the lightshield that is associated with, and at least partially formed over the photodiode. Depending on polarity, the compensating lightshield pulse allows holes to locally flow from under the VCCD gates to the photodiode P+ pinning region or vice-versa, and in such a manner to eliminate the global flow of hole current. Lightshields may also be biased during electronic shuttering operations.

An image sensor pixel having a hybrid transfer storage gate-storage diode storage node is disclosed herein. An example image sensor includes a photodiode, a storage diode, a transfer gate, and a buried storage well. The photodiode, storage diode, and buried storage well are all disposed in a semiconductor material. The transfer storage gate may be disposed on a surface of the semiconductor material between the photodiode and the storage diode. Further, the buried storage well may be disposed under the storage diode and partially under the transfer storage gate. Additionally, a length of the transfer storage gate and a length of the storage diode may be equal, and the storage diode may passivate a surface of the semiconductor material between the transfer storage gate and an output gate.

A solid-state imaging device includes a layout in which one sharing unit includes an array of photodiodes of 2 pixels by 4n pixels (where, n is a positive integer), respectively, in horizontal and vertical directions.

Channel stop sections formed by multiple times of impurity ion implanting processes. Four-layer impurity regions are formed across the depth of a semiconductor substrate (across the depth of the bulk), so that a P-type impurity region is formed deep in the semiconductor substrate; thus, incorrect movement of electric charges is prevented. Other four-layer impurity regions of another channel stop section are decreased in width step by step across the depth of the substrate, so that the reduction of a charge storage region of a light receiving section due to the dispersion of P-type impurity in the channel stop section is prevented in the depth of the substrate.

A semiconductor device is provided that includes an array of imaging cells realized from a plurality of layers formed on a substrate, wherein the plurality of layers includes at least one modulation doped quantum well structure spaced from at least one quantum dot structure. Each respective imaging cell includes an imaging region spaced from a corresponding charge storage region. The at least one quantum dot structure of the imaging region generates photocurrent arising from absorption of incident electromagnetic radiation. The at least one modulation doped quantum well structure defines a buried channel for lateral transfer of the photocurrent for charge accumulation in the charge storage region and output therefrom. The at least one modulation doped quantum well structure and the at least one quantum dot structure of each imaging cell can be disposed within a resonant cavity that receives the incident electromagnetic radiation or below a structured metal film having a periodic array of holes.

An image sensor with a pinned photodiode includes a photodiode formed in a substrate by implanting dopants of a first type through one or more dielectric layers formed over the substrate. A pinning layer for the photodiode may be formed by implanting dopants of a second type through the same one or more dielectric layers. The pinning layer may be formed over a photodiode region of the substrate. The concentration of dopants of the second type may have a maximum value in dielectric layers over the photodiode that exceeds the concentration of dopants of the second type in the substrate below. The photodiode and pinning layer may both be formed by implanting ions of the first and second type respectively through a dielectric layer formed after etching away a portion of another dielectric layer, having a different thickness, and having different optical transmission properties than the another dielectric layer.

A charge-coupled device (CCD) image sensor is provided. The CCD image sensor may include an array of photosensors that transfer charge to multiple vertical CCD shift registers, which then in turn transfer the charge to a horizontal CCD shift register. The horizontal CCD shift register then feeds an output buffer circuit. The output buffer circuit can include multiple output stages, each of which can include a source-follower transistor coupled in series with a current sink transistor and at least one cascode transistor. The current sink transistor may have its gate terminal shorted to ground. In one arrangement, the cascode transistor has a gate terminal that receives a non-zero bias voltage. In another arrangement, the cascode transistor has a gate terminal that is also shorted to ground and operates in depletion mode.

Methods of measuring and calibrating the gain of a CCD imaging system are described. Charge injectors may be present on either side of an image sensor array that provide test charges to respective calibration VCCDs. Test charges may be transferred to upper and lower HCCDs during quad-output read out or to only the lower HCCD during dual-output or single-output read out. In each quadrant of the imaging system, test charges may be transferred to an EMCCD output or to a non-EMCCD output via a charge switch based on the magnitude of the test charges. The gains of all EMCCD outputs and non-EMCCD outputs in the imaging system may be calibrated against one another by adjusting the gain at each output when a discrepancy is detected between any two outputs.

An image sensor with a pinned photodiode includes a photodiode formed in a substrate by implanting dopants of a first type through one or more dielectric layers formed over the substrate. A pinning layer for the photodiode may be formed by implanting dopants of a second type through the same one or more dielectric layers. The pinning layer may be formed over a photodiode region of the substrate. The concentration of dopants of the second type may have a maximum value in dielectric layers over the photodiode that exceeds the concentration of dopants of the second type in the substrate below. The photodiode and pinning layer may both be formed by implanting ions of the first and second type respectively through a dielectric layer formed after etching away a portion of another dielectric layer, having a different thickness, and having different optical transmission properties than the another dielectric layer.