Provided is a composition with which a film that allows transmission of infrared light in a state where noise generated from visible light is small can be formed. In addition, provided are a film, a laminate, an infrared transmitting filter, a solid image pickup element, and an infrared sensor. This composition includes: a coloring material that allows transmission of infrared light and shields visible light; an infrared absorber; and a curable compound, in which the infrared absorber includes a material that shields light in a wavelength range of longer than 1000 nm and 1200 nm or shorter. In the composition, a ratio A/B of a minimum value A of an absorbance of the composition in a wavelength range of 400 to 1100 nm to a maximum value B of an absorbance of the composition in a wavelength range of 1400 to 1500 nm is 4.5 or higher.

Provided is a solid-state imaging device capable of improving sensitivity of near-infrared wavelengths and suppressing color mixing without being restricted by a wiring layout. A solid-state imaging device includes: a substrate on which a plurality of photoelectric conversion units are formed corresponding to different light wavelengths; a wiring layer including a transistor on a surface opposite to a surface on a light incident side of the substrate and on a photoelectric conversion unit side to execute signal processing on a charge output from the photoelectric conversion unit and a wiring on a side opposite to the photoelectric conversion unit side of the transistor so as to transfer an electrical signal obtained by the transistor; and a reflection design film on a transistor side from at least a junction between the substrate and the wiring layer, which has higher reflectivity than the wiring layer and reflects a vertical component of incident light.

Provided is a sequencing chip. The sequencing chip includes: a chip main body, nucleic acids, and a phosphonic acid polymer film. The chip main body includes a plurality of chip particles arranged in a same layer, the chip particles are obtained by cutting a chip matrix along cutting lines of a wafer layer, and the chip matrix includes: the wafer layer having the cutting lines uniformly distributed thereon; a first silicon oxide layer made of silicon oxide and formed on an upper surface of the wafer layer; and a transition metal oxide layer made of a transition metal oxide and formed on an upper surface of the first silicon oxide layer. The nucleic acids are fixed on the transition metal oxide layer; and the phosphonic acid polymer film is made of a polyphosphonic acid polymer and formed on an upper surface of the transition metal oxide layer.

An apparatus and method enabling a reduction in a resistance of a conductive path electrically connecting an upper substrate and a lower substrate. The apparatus includes a first semiconductor layer with element formation regions disposed adjacent to one another via element isolation regions, each of the element formation regions having a first active element, contact regions on an element isolation region side of a front layer portion of the element formation regions, conductive pads connected to the contact regions and extending across the element isolation region, a first insulating layer, a second semiconductor layer on the first insulating layer and having a second active element, a second insulating layer covering the second semiconductor layer, and conductive plugs extending from the second insulating layer to the conductive pad, the conductive plugs including a material identical to a material of the conductive pad and formed integrally with the conductive pad.

An image sensor device includes a substrate, photosensitive pixels, an interconnect structure, a dielectric layer, and a light blocking element. The photosensitive pixels are in the substrate. The interconnect structure is over a first side of the substrate. The dielectric layer is over a second side of the substrate opposite the first side of the substrate. The light blocking element has a first portion extending over a top surface of the dielectric layer and a second portion extending in the dielectric layer. The second portion of the light blocking element laterally surrounds the photosensitive pixels.

A direct bonding method for infrared focal plane arrays, includes steps of depositing a thin adhesion layer on infrared radiation detecting material, removing a portion of the thin adhesion layer with a chemical-mechanical polishing process, forming a bonding layer at a bonding interface, and bonding the infrared radiation detecting material to a silicon wafer with the thin adhesion layer as a bonding layer. The thin adhesion layer may include SiO.sub.x, where x ranges between 1.0 and 2.0. The thickness of the thin adhesion layer to form the bonding layer is 500 angstrom or less.

An image sensing device includes a pixel array including a plurality of pixels, each of pixels configured to generate a pixel signal corresponding to intensity of incident light, and a plurality of grid structures, each grid structure disposed to overlap with a boundary between adjacent pixels among the plurality of pixels and configured to include an air layer so as to optically isolate the adjacent pixels. Each of the grid structures includes regions that form a cross shape.

A radiation-resistant image sensor package may include: a substrate; an image sensor disposed over the substrate; and an optical cover disposed over the image sensor, wherein a radiation-resistant passivation layer is coupled to the optical cover.

An image sensor structure includes a semiconductor device, a plurality of image sensing elements formed in the semiconductor substrate, an interconnect structure formed on the semiconductor substrate, and a composite grid structure over the semiconductor substrate. The composite grid structure includes a tungsten grid, an oxide grid over the tungsten grid, and an adhesion enhancement grid spacing the tungsten grid from the oxide grid.

Various embodiments of the present disclosure are directed towards an image sensor. The image sensor includes and image sensor element disposed within a substrate. The substrate comprises a first material. The image sensor element includes an active layer comprising a second material different from the first material. A buffer layer is disposed between the active layer and the substrate. The buffer layer extends along outer sidewalls and a bottom surface of the active layer. A capping structure overlies the active layer. Outer sidewalls of the active layer are spaced laterally between outer sidewalls of the capping structure such that the capping structure continuously extends over outer edges of the active layer.