A solid-state imaging element including: a photoelectric conversion layer, a first electrode and a second electrode opposed to each other with the photoelectric conversion layer interposed therebetween, a semiconductor layer provided between the first electrode and the photoelectric conversion layer, an accumulation electrode opposed to the photoelectric conversion layer with the semiconductor layer interposed therebetween, an insulating film provided between the accumulation electrode and the semiconductor layer, and a barrier layer provided between the semiconductor layer and the photoelectric conversion layer.

The present disclosure relates to an image pickup device and an electronic apparatus that enable warping of a substrate to be suppressed. A first structural body including a pixel array unit is layered with a second structural body including an input/output circuit unit and outputting a pixel signal output from the pixel to the outside of the device, and a signal processing circuit; and a signal output external terminal and a signal input external terminal are arranged below the pixel array unit, the signal output external terminal being connected to the outside via a first through-via penetrating through a semiconductor substrate in the second structural body, the signal input external terminal being connected to the outside via a second through-via connected to an input circuit unit and penetrating through the semiconductor substrate. The present disclosure can be applied to, for example, the image pickup device, and the like.

A heteroepitaxial semiconductor device includes a seed layer including a first semiconductor material, the seed layer including a first side, an opposing second side and lateral sides connecting the first and second sides, a separation layer arranged at the first side of the seed layer, the separation layer including an aperture, a heteroepitaxial structure grown at the first side of the seed layer at least in the aperture and including a second semiconductor material, different from the first semiconductor material, and a first dielectric material layer arranged at the second side of the seed layer and covering the lateral sides of the seed layer.

The present application discloses a method for measuring stitching overlay accuracy of image sensor stitching manufacturing, forming an A-type overlay pattern mark and a corresponding B-type overlay pattern mark on the edge of each rectangular pixel area to be stitched; after the A-type overlay pattern mark and the B-type overlay pattern mark are stitched and exposed, performing metrology by means of a scanning electron microscope to obtain dimension features; and according to the dimension features of the A-type overlay pattern mark and the B-type overlay pattern mark stitched together and exposed and measured by the scanning electron microscope, determining stitching overlay accuracy of two adjacent rectangular pixel areas. The present application can achieve direct metrology on the overlay pattern mark on the stitched pixel area of a product, facilitating timely and accurate monitoring on the stitching overlay accuracy of image sensor stitching manufacturing.

Various embodiments of the present disclosure are directed towards a method for forming an image sensor in which a device layer has high crystalline quality. According to some embodiments, a hard mask layer is deposited covering a substrate. A first etch is performed into the hard mask layer and the substrate to form a cavity. A second etch is performed to remove crystalline damage from the first etch and to laterally recess the substrate in the cavity so the hard mask layer overhangs the cavity. A sacrificial layer is formed lining cavity, a blanket ion implantation is performed into the substrate through the sacrificial layer, and the sacrificial layer is removed. An interlayer is epitaxially grown lining the cavity and having a top surface underlying the hard mask layer, and a device layer is epitaxially grown filling the cavity over the interlayer. A photodetector is formed in the device layer.

A semiconductor package is disclosed. The package includes a package substrate having top and bottom major package substrate surfaces, the top major package surface including a die region. A die having first and second major die surfaces is attached onto the die region. The second major die surface is attached to the die region. The first major die surface includes a sensor region and a cover adhesive region surrounding the sensor region. The package also includes a cover adhesive to the cover adhesive region on the first major die surface. A protective cover with first and second major cover surfaces and side surfaces is attached to the die using the cover adhesive. The second major cover surface contacts the cover adhesive. The protective cover covers the sensor region. The protective cover includes a cover attached to the first major die surface, the cover includes top and bottom major cover surfaces and side cover surfaces. The cover includes an opaque region disposed at a periphery of the bottom cover surface of the cover, the opaque region is configured to prevent flaring or scattering of light. An encapsulant is disposed on the package substrate to cover exposed portions of the package substrate, die and bond wires and side surfaces of the cover, while leaving the first major cover surface exposed.

One or more semiconductor processing tools may deposit a contact etch stop layer on a substrate. In some implementations, the contact etch stop layer is comprised of less than approximately 12 percent hydrogen. Depositing the contact etch stop layer may include depositing contact etch stop layer material at a temperature of greater than approximately 600 degrees Celsius, at a pressure of greater than approximately 150 torr, and/or with a ratio of at least approximately 70:1 of NH3 and SiH4, among other examples. The one or more semiconductor processing tools may deposit a silicon-based layer above the contact etch stop layer. The one or more semiconductor processing tools may perform an etching operation into the silicon-based layer until reaching the contact etch stop layer to form a trench isolation structure.

A method includes disposing a sheet of glass on a front side of a semiconductor substrate that includes at least one image sensor die, attaching the sheet of glass to the at least one image sensor die by a bead of adhesive material disposed on an edge of the at least one image sensor die, and sawing the semiconductor substrate from a back side to form a trench along a side of the at least one image sensor die. The trench extends through a thickness of the semiconductor substrate and through a part of a thickness of the sheet of glass. The method further includes filling the trench with a molding material to form a layer of molding material on a sidewall of the at least one image sensor die, and singulating the semiconductor substrate to isolate an individual image sensor package enclosing the at least one image sensor die.

A biosensor is provided. The biosensor includes a substrate, photodiodes, pixelated filters, an excitation light rejection layer and an immobilization layer. The substrate has pixels. The photodiodes are disposed in the substrate and correspond to one of the pixels, respectively. The pixelated filters are disposed on the substrate. The excitation light rejection layer is disposed on the pixelated filter. The immobilization layer is disposed on the excitation light rejection layer.

Provided is a semiconductor device, including a substrate including a pixel region, a gate structure on the substrate in the pixel region, wherein the gate structure comprises a gate dielectric layer and a gate conductive layer on the gate dielectric layer; a dielectric layer located over the substrate and the gate structure; and a contact located in the dielectric layer and electrically connected to the gate conductive layer. The contact includes a doped polysilicon layer in contact with the gate conductive layer; a metal layer located on the doped polysilicon layer, wherein a part of the metal layer is embedded in the doped polysilicon layer; a barrier layer located between the metal layer and the doped polysilicon layer; and a metal silicide layer located between the barrier layer and the doped polysilicon layer.