A light-receiving device includes: a first chip having a pixel region in which a sensor pixel is provided; a second chip including a processing circuit that performs signal processing on a sensor signal outputted from the sensor pixel, the second chip being stacked on the first chip; and a first alignment mark provided in the pixel region of the first chip to correspond to a second alignment mark provided in the second chip.

A photoelectric conversion element includes a first electrode, a second electrode, a photoelectric conversion layer positioned between the first electrode and the second electrode and including a donor semiconductor material and an acceptor semiconductor material, and a first charge blocking layer positioned between the first electrode and the photoelectric conversion layer. The first charge blocking layer includes a first material and a second material having an energy band gap narrower than that of the first material. The electron affinity of the first material is lower than that of the second material, and the ionization potential of the first material is higher than that of the second material.

Some aspects of the present disclosure relate to a method. In the method, a semiconductor substrate is received. A photodetector is formed in the semiconductor substrate. An interconnect structure is formed over the photodetector and over a frontside of the semiconductor substrate. A backside of the semiconductor substrate is thinned, the backside being furthest from the interconnect structure. A ring-shaped structure is formed so as to extend into the thinned backside of the semiconductor substrate to laterally surround the photodetector. A series of trench structures are formed to extend into the thinned backside of the semiconductor substrate. The series of trench structures are laterally surrounded by the ring-shaped structure and extend into the photodetector.

There is provided a solid-state imaging device including a substrate having a surface over which a plurality of photodiodes are formed, and a protection film that is transparent, has a water-proofing property, and includes a side wall part vertical to the surface of the substrate and a ceiling part covering a region surrounded by the side wall part, the side wall part and the ceiling part surrounding a region where the plurality of photodiodes are arranged over the substrate.

A solid-state imaging device having a backside illuminated structure, includes: a pixel region in which pixels each having a photoelectric conversion portion and a plurality of pixel transistors are arranged in a two-dimensional matrix; an element isolation region isolating the pixels which is provided in the pixel region and which includes a semiconductor layer provided in a trench by an epitaxial growth; and a light receiving surface at a rear surface side of a semiconductor substrate which is opposite to a multilayer wiring layer.

A semiconductor optical sensor (1) is provided with: a substrate (2) integrating a plurality of photodetector active areas (4); and a CMOS layer stack (6) arranged on the substrate (2) and including a number of dielectric (6a) and conductive (6b) layers. UV conversion regions (10) are arranged above a number of first photodetector active areas (4) to convert UV light radiation into visible light radiation towards the first photodetector active areas (4), so that the first photodetector active areas (4) are designed to detect UV light radiation. In particular, the first photodetector active areas (4) are alternated to a number of second photodetector active areas (4), designed to detect visible light radiation, in an array (15) of photodetection units (16) of the optical sensor (1), defining a single image detection area (15′), sensitive to both UV and visible light radiation with a same spatial resolution.

Photosensors may be formed on a front side of a semiconductor substrate. An optical refraction layer having a first refractive index may be formed on a backside of the semiconductor substrate. A grid structure including openings is formed over the optical refraction layer. A masking material layer is formed over the grid structure and the optical refraction layer. The masking material layer may be anisotropically etched using an anisotropic etch process that collaterally etches a material of the optical refraction layer and forms non-planar distal surface portions including random protrusions on physically exposed portions of the optical refraction layer. An optically transparent layer having a second refractive index that is different from the first refractive index may be formed on the non-planar distal surface portions of the optical refraction layer. A refractive interface refracts incident light in random directions, and improves quantum efficiency of the photosensors.

An object of the present disclosure is to provide a solid-state imaging device capable of suppressing deterioration of image quality. The solid-state imaging device includes: a first pixel that has a plurality of photoelectric conversion units sharing a first color filter with each other and a plurality of on-chip lenses; a second pixel that is arranged adjacent to the first pixel and has a plurality of photoelectric conversion units sharing a second color filter with each other and a plurality of on-chip lenses; and a first light shielding region that is provided between the first pixel and the second pixel.

An image sensor pixel includes a substrate having a pixel electrode on a light receiving surface thereof, and a photoelectric conversion layer including a perovskite material, on the pixel electrode. A transparent electrode is provided on the photoelectric conversion layer, and a vertical electrode is provided, which is electrically connected to the pixel electrode and extends at least partially through the substrate. The photoelectric conversion layer includes a perovskite layer, a first blocking layer extending between the pixel electrode and the perovskite layer, and a second blocking layer extending between the transparent electrode and the perovskite layer. The perovskite material may have a material structure of ABX.sub.3, A.sub.2BX.sub.4, A.sub.3BX.sub.5, A.sub.4BX.sub.6, ABX.sub.4, or A.sub.n−1B.sub.nX.sub.3n+1, where: n is a positive integer in a range from 2 to 6; A includes at least one material selected from a group consisting of Na, K, Rb, Cs and Fr; B includes at least one material selected from a divalent transition metal, a rare earth metal, an alkaline earth metal, Ga, In, Al, Sb, Bi, and Po; and X includes at least one material selected from Cl, Br, and I.

An image sensing device includes a pixel array configured to include a plurality of pixel groups arranged in a matrix structure. Each of the pixel groups includes an optical filter configured to selectively pass incident light, a plurality of photoelectric conversion regions disposed below the optical filter and arranged in a matrix structure, a first isolation structure disposed between the photoelectric conversion regions and other pixel groups, a plurality of second isolation structures disposed between two adjacent photoelectric conversion regions from among the photoelectric conversion regions, and a third isolation structure disposed between the second isolation structures, and configured to interconnect the second isolation structures. The third isolation structure includes a cavity region formed adjacent to contact any one of the photoelectric conversion regions.