The present invention relates to a semiconductor device, a solid-state image sensor and a camera system capable of reducing the influence of noise at a connection between chips without a special circuit for communication and reducing the cost as a result. The semiconductor device includes: a first chip; and a second chip, wherein the first chip and the second chip are bonded to have a stacked structure, the first chip has a high-voltage transistor circuit mounted thereon, the second chip has mounted thereon a low-voltage transistor circuit having lower breakdown voltage than the high-voltage transistor circuit, and wiring between the first chip and the second chip is connected through a via formed in the first chip.

A semiconductor device is disclosed, which includes: at least one device layer being a crystallized layer for example including: a superlattice layer and/or a layer of group III-V semiconductor materials; and a passivation structure comprising one or more layers wherein at least one layer of the passivation structure is a passivation layer grown in-situ in a crystallized form on top of the device layer, and at least one of the one or more layers of the passivation structure includes material having a high density of surface states which forces surface pinning of an equilibrium Fermi level within a certain band gap of the device layer, away from its conduction and valence bands.

A semiconductor device structure and method for forming the same are provided. The semiconductor device structure includes an interconnect structure formed over a substrate and a passivation layer formed over the interconnect structure. The semiconductor device structure also includes an anti-acid layer formed in the passivation layer and a bonding layer formed on the anti-acid layer and the passivation layer. The anti-acid layer has a thickness that is greater than about 140 nm.

A curved image sensor system includes (a) an image sensor substrate having a concave light-receiving surface, a pixel array located along the concave light-receiving surface, and a planar external surface facing away from the concave light-receiving surface, (b) a light-transmitting substrate bonded to the image sensor substrate by a bonding layer, and (c) a hermetically sealed cavity, bounded at least by the concave light-receiving surface, the light-transmitting substrate, and the bonding layer.

A method of manufacturing a photoelectric conversion device includes forming, with material containing aluminum, an electrically conductive pattern on a semiconductor substrate including a photoelectric converter, forming, on the electrically conductive pattern, an insulating film containing hydrogen, performing first annealing in a hydrogen-containing atmosphere, forming, on the insulating film, a protective film having lower hydrogen permeability than that of the insulating film after the first annealing, and performing second annealing in the hydrogen-containing atmosphere. Temperature in the first annealing is not less than temperature when forming the insulating film and not more than temperature when forming the protective film.

Described herein is a method of manufacturing at least one spectrometer device for evaluating electromagnetic radiation. The method includes: a) providing at least one electro-optical system configured for generating at least one electronic signal according to the electromagnetic radiation; b) providing at least one readout integrated circuit (ROIC) for processing the at least one electronic signal; c) providing at least one circuit carrier; d) arranging the electro-optical system on the ROIC; e) bonding the electro-optical system and the ROIC to establish at least one electrical connection between the electro-optical system and the ROIC; and f) arranging the ROIC on the circuit carrier, such that the ROIC is located between the electro-optical system and the circuit carrier. Also described herein is a spectrometer device for evaluating electromagnetic radiation.

A structure usable in a molecular sensor device comprises a substrate defining a substrate plane and spaced apart pairs of reducible metal oxide or metal nitride sheets attached to the substrate at an angle to the substrate plane. The structure further includes intervening dielectric sheets. Fabrication methods for manufacturing structures for molecular sensors are disclosed comprising oblique angle deposition of reducible metal oxide or metal nitride and dielectric layers, planarization of the resulting stack, and reduction of portions of the reducible metal oxide or metal nitride sheets to the corresponding base metal.

A method includes forming a package, which includes an optical die and a protection layer attached to the optical die. The optical die includes a micro lens, with the protection layer and the micro lens being on a same side of the optical die. The method further includes encapsulating the package in an encapsulant, planarizing the encapsulant to reveal the protection layer, and removing the protection layer to form a recess in the encapsulant. The optical die is underlying the recess, with the micro lens facing the recess.

A chip package includes a chip, an adhesive layer, and a dam element. The chip has a sensing area, a first surface, and a second surface that is opposite to the first surface. The sensing area is located on the first surface. The adhesive layer covers the first surface of the chip. The dam element is located on the adhesive layer and surrounds the sensing area. The thickness of the dam element is in a range from 20 m to 750 m, and the wall surface of the dam element surrounding the sensing area is a rough surface.

The invention relates to a method for texturing a semiconductor substrate (1), comprising steps consisting in forming a plurality of cavities of random shapes, depths and distribution, in an etch mask (2), by means of non-homogeneous reactive-ion etching, forming a first rough random design, and etching the substrate using the etch mask, by means of reactive-ion etching, in such a way as to transfer the first rough random design into the substrate and to produce a second rough random design (200), comprising cavities (20) of random shapes, depths (d2r) and distribution, on the surface of the substrate.