An imaging pixel may be provided with a photodiode and a floating diffusion region. The pixel may include multiple charge storage regions interposed between the photodiode and the floating diffusion region. A first charge storage region may be used to store charge from the photodiode for global shutter functionality. A second charge storage region may not be coupled to the photodiode. The second charge storage region may be used to determine how much charge is generated in the charge storage region from incident light on the charge storage region. The second charge storage region may help account for incident light noise in the first charge storage region. The second charge storage region may be the same size as the first charge storage region, or may be smaller than the first charge storage region.

The present invention provides a method of more efficiently producing a semiconductor epitaxial wafer, which can suppress metal contamination by achieving higher gettering capability. A method of producing a semiconductor epitaxial wafer 100 according to the present invention includes a first step of irradiating a semiconductor wafer 10 with cluster ions 16 to form a modifying layer 18 formed from a constituent element of the cluster ions 16 in a surface portion 10A of the semiconductor wafer; and a second step of forming an epitaxial layer 20 on the modifying layer 18 of the semiconductor wafer 10.

A semiconductor device includes a semiconductor substrate, a radiation-sensing region, at least one isolation structure, and a doped passivation layer. The radiation-sensing region is present in the semiconductor substrate. The isolation structure is present in the semiconductor substrate and adjacent to the radiation-sensing region. The doped passivation layer at least partially surrounds the isolation structure in a substantially conformal manner.

A backside illuminated image sensor with an array of pixels formed in a substrate is provided. To improve surface planarity, bond pads formed at the periphery of the array of pixels may be recessed into a back surface of the substrate. The bond pads may be recessed into a semiconductor layer of the substrate, may be recessed into a window in the semiconductor layer, or may be recessed in a passivation layer and covered with non-conductive material such as resin. In order to further improve surface planarity, a window may be formed in the semiconductor layer at the periphery of the array of pixels, or scribe region, over alignment structures. By providing an image sensor with improved surface planarity, device yield and time-to-market may be improved, and window framing defects and microlens/color filter non-uniformity may be reduced.

A monolithic sensor for detecting infrared and visible light according to an example includes a semiconductor substrate and a semiconductor layer coupled to the semiconductor substrate. The semiconductor layer includes a device surface opposite the semiconductor substrate. A visible light photodiode is formed at the device surface. An infrared photodiode is also formed at the device surface and in proximity to the visible light photodiode. A textured region is coupled to the infrared photodiode and positioned to interact with electromagnetic radiation.

There is provided a semiconductor device, including a semiconductor substrate, an interlayer insulating layer formed on the semiconductor substrate, a bonding electrode formed on a surface of the interlayer insulating layer, and a metal film which covers an entire surface of a bonding surface including the interlayer insulating layer and the bonding electrode.

Provided are an image sensor and an imaging apparatus. The image sensor of a multi-layered sensor structure, the image sensor includes a plurality of sensing pixels, each of the plurality of sensing pixels including a micro lens configured to collect light, a first photoelectric converter configured to convert light of a first wavelength band into an electric signal, and a second photoelectric converter formed on a substrate configured to convert incident light into the electric signal, wherein a central axis of the second photoelectric converter is spaced apart from an optical axis of the micro lens.

There is provided solid-state imaging devices and methods of forming the same, the solid-state imaging devices including: a semiconductor substrate; a glass substrate; an adhesion layer provided between the semiconductor substrate and the glass substrate; and a warpage correction film provided adjacent to one of the semiconductor substrate and the glass substrate.

A semiconductor device has a chip region including a back-side illumination type photoelectric conversion element, a mark-like appearance part, a pad electrode, and a coupling part. The mark-like appearance part includes an insulation film covering the entire side surface of a trench part formed in a semiconductor substrate. The pad electrode is arranged at a position overlapping the mark-like appearance part. The coupling part couples the pad electrode and mark-like appearance part. At least a part of the pad electrode on the other main surface side of the substrate is exposed through an opening reaching the pad electrode from the other main surface side of the substrate. The mark-like appearance part and coupling part are arranged to at least partially surround the outer circumference of the opening in plan view.

BSI image sensors and methods. In an embodiment, a substrate is provided having a sensor array and a periphery region and having a front side and a back side surface; a bottom anti-reflective coating (BARC) is formed over the back side to a first thickness, over the sensor array region and the periphery region; forming a first dielectric layer over the BARC; a metal shield is formed; selectively removing the metal shield from over the sensor array region; selectively removing the first dielectric layer from over the sensor array region, wherein a portion of the first thickness of the BARC is also removed and a remainder of the first thickness of the BARC remains during the process of selectively removing the first dielectric layer; forming a second dielectric layer over the remainder of the BARC and over the metal shield; and forming a passivation layer over the second dielectric layer.