A semiconductor device includes a substrate, a circuit layer formed on a first surface of the substrate and including a via pad and an interlayer insulating layer covering the via pad, a via structure configured to fully pass through the substrate, partially pass through the interlayer insulating layer and be in contact with the via pad, a via isolation insulating layer configured to pass through the substrate and be spaced apart from outer side surfaces of the via structure in a horizontal direction and a pad structure buried in the substrate and exposed on a second surface of the substrate opposite the first surface of the substrate.

A scanning electron microscope incorporates a multi-pixel solid-state electron detector. The multi-pixel solid-state detector may detect back-scattered and/or secondary electrons. The multi-pixel solid-state detector may incorporate analog-to-digital converters and other circuits. The multi-pixel solid state detector may be capable of approximately determining the energy of incident electrons and/or may contain circuits for processing or analyzing the electron signals. The multi-pixel solid state detector is suitable for high-speed operation such as at a speed of about 100 MHz or higher. The scanning electron microscope may be used for reviewing, inspecting or measuring a sample such as unpatterned semiconductor wafer, a patterned semiconductor wafer, a reticle or a photomask. A method of reviewing or inspecting a sample is also described.

A semiconductor device having a first semiconductor section including a first wiring layer at one side thereof; a second semiconductor section including a second wiring layer at one side thereof, the first and second semiconductor sections being secured together with the respective first and second wiring layer sides of the first and second semiconductor sections facing each other; a conductive material extending through the first semiconductor section to the second wiring layer of the second semiconductor section and by means of which the first and second wiring layers are in electrical communication; and an opening, other than the opening for the conductive material, which extends through the first semiconductor section to the second wiring layer.

A method for manufacturing a back-side illumination (BSI) complementary metal-oxide-semiconductor (CMOS) image sensor with a vertical transfer gate structure for improved quantum efficiency (QE) and global shutter efficiency (GSE) is provided. A sacrificial dielectric layer is formed over a semiconductor region. A first etch is performed into the sacrificial dielectric layer to form an opening exposing a photodetector in the semiconductor region. A semiconductor column is formed in the opening. A floating diffusion region (FDR) is formed over the semiconductor column and the sacrificial dielectric layer. A second etch is performed into the sacrificial dielectric layer to remove the sacrificial dielectric layer, and to form a lateral recess between the FDR and the photodetector. A gate is formed filling the lateral recess and laterally spaced from the semiconductor column by a gate dielectric layer. The BSI CMOS image sensor resulting from the method is also provided.

A hybrid analog-digital pixel circuit is fabricated on two wafers. A first wafer includes the analog pixel circuitry and a second wafer includes the digital control and processing circuitry. Externally accessible contact structures for electrically interconnecting the two wafers are arranged in groups. Each group includes externally accessible contact structures for carrying signals associated solely with operation of a corresponding pixel.

An image sensor device includes a semiconductor substrate, a radiation sensing member, a shallow trench isolation, and a color filter layer. The radiation sensing member is in the semiconductor substrate. An interface between the radiation sensing member and the semiconductor substrate includes a direct band gap material. The shallow trench isolation is in the semiconductor substrate and surrounds the radiation sensing member. The color filter layer covers the radiation sensing member.

A metal grid within a trench isolation structure on the back side of an image sensor is coupled to a contact pad so that a voltage on the metal grid is continuously variable with a voltage on the contact pad. One or more conductive structures directly couple the metal grid to a contact pad. The conductive structures may bypass a front side of the image sensor. A bias voltage on the metal grid may be varied through the contact pad whereby a trade-off between reducing cross-talk and increasing quantum efficiency may be adjusted dynamically in accordance with the application of the image sensor, its environment of use, or its mode of operation.

An electronic device includes: an imaging unit including a region having a pixel group that has a plurality of first pixels, and second pixels that are fewer than the first pixels in the pixel group; and a control unit that reads out the signals based upon exposure of the second pixels during exposure of the plurality of first pixels.

A sensing device includes a light source to emit light, a light sensor to detect reflection of the emitted light and distance determination circuitry responsive to reflected-light detection within the light sensor. The light sensor includes a photodetector having a photocharge storage capacity in excess of one electron and an output circuit that generates an output signal responsive to light detection within the photodetector with sub-hundred nanosecond latency. The distance determination circuitry measures an elapsed time based on transition of the output signal in response to photonic detection within the photodetector and determines, based on the elapsed time, a distance between the sensing device and a surface that yielded the reflection of the emitted light.

A method is provided for three-dimensional wafer scale integration of heterogeneous wafers with unequal die sizes that include a first wafer and a second wafer. The method includes selecting a periodicity for the second wafer to be manufactured that matches the periodicity of the first wafer. The method further includes manufacturing the second wafer in accordance with the selected periodicity. The method also includes placing, by a laser-based patterning device, a pattern in spaces between dies of the second wafer. The method additionally includes stacking the first wafer onto the second wafer using a bonding material.