A joined body includes a first substrate, a second substrate which faces the first substrate, and a joining film which joins the first substrate to the second substrate, wherein the joining film has a first region and a second region, and in a plan view of the first substrate, the first region has a higher metal nanoparticle density than the second region.

Provided is an adhesive for semiconductor mounting that can achieve high-precision gap control and can increase heat resistance when a semiconductor is mounted. An adhesive for semiconductor mounting according to the present invention is an adhesive that is used for mounting a semiconductor, and contains a silicone resin and a spacer, the content of the spacer being 0.1% by weight or more and 5% by weight or less in 100% by weight of the adhesive, the 10% compressive elasticity modulus of the spacer being 5000 N/mm.sup.2 or more and 15000 N/mm.sup.2 or less, and the average particle diameter of the spacer being 10 m or more and 200 m or less.

Provided is an adhesive for semiconductor sensor chip mounting that can reduce detection of noise and can increase heat resistance and thermal cycle resistance characteristics. An adhesive for semiconductor sensor chip mounting according to the present invention is an adhesive used for mounting a semiconductor sensor chip and contains a silicone resin and a spacer, the 10% compressive elasticity modulus of the spacer being 10 N/mm.sup.2 or more and 2000 N/mm.sup.2 or less, the compression recovery rate of the spacer being 20% or less, and the average particle diameter of the spacer being 10 m or more and 200 m or less.

A method for manufacturing a display panel, and a display device are disclosed. The method for manufacturing a display panel includes: providing a TFT substrate; dispersing graphene and metal nanowires in a hydrophilic solvent to form a hydrophilic conductive ink; applying the hydrophilic conductive ink onto the TFT substrate to form a composite electrode layer; forming, on the composite electrode layer, a pixel defining layer having a plurality of openings at least partially exposing the composite electrode layer; applying hydrophilic organic ink into the plurality of openings of the pixel defining layer to form an organic layer; drying the composite electrode layer and the organic layer to form a first electrode and an organic light emitting structure; and forming a second electrode on the organic light emitting structure and the pixel defining layer.

An electronic device has a substrate 5, a first electric element 91 provided on a first conductor layer 71, a second electric element 92 provided on the first electric element 91, and a connector 50 having a base end part 45 provided on a second conductor layer 72 and a head part 40 provided on a front surface electrode 92a of the second electric element 92 via a conductive adhesive 75. An area of the base end part 45 placed on the second conductor layer 72 is larger than an area of the head part 40 placed on the second electric element 92. The base end part 45 is located at a side of the substrate 5 compared with the head part 40, and a gravity center position of the connector 50 is at a side of the base end part 45 of the connector 50.

An electrically conductive paste used to form an electrode used for electrical connection to a p-type semiconductor layer of a crystalline silicon solar cell, wherein the electrically conductive paste is able to fire through an antireflective film during firing and is capable of forming an electrode having low contact resistance on a p-type semiconductor layer. The electrically conductive paste contains (A) an electrically conductive powder, (B) Al powder or Al compound powder having an average particle diameter of 0.5 m to 3.5 m, (C) a glass frit and (D) an organic medium, and contains 0.5 parts by weight to 5 parts by weight of the Al powder or Al compound powder (B) based on 100 parts by weight of the electrically conductive powder (A).

A method for manufacturing a display panel, and a display device are disclosed. The method for manufacturing a display panel includes: providing a TFT substrate; dispersing graphene and metal nanowires in a hydrophilic solvent to form a hydrophilic conductive ink; applying the hydrophilic conductive ink onto the TFT substrate to form a composite electrode layer; forming, on the composite electrode layer, a pixel defining layer having a plurality of openings at least partially exposing the composite electrode layer; applying hydrophilic organic ink into the plurality of openings of the pixel defining layer to form an organic layer; drying the composite electrode layer and the organic layer to form a first electrode and an organic light emitting structure; and forming a second electrode on the organic light emitting structure and the pixel defining layer.

The present invention relates to conductive pastes, suitable for use in solar cells, a method for the manufacture of a light receiving surface electrode of a solar cell, a light receiving electrode for a solar cell and a solar cell. The paste comprises a solids portion dispersed in an organic medium, the solids portion comprising electrically conductive metal, and mixed oxide, wherein the mixed oxide is a tellurium-bismuth-cerium mixed oxide and is substantially lead-free and substantially silicon-free.

A device includes a first conductive feature in an insulating layer; a dielectric layer over the first conductive feature; a second conductive feature in the dielectric layer, wherein the second conductive feature is over and physically contacting the first conductive feature; an air spacer encircling the second conductive feature, wherein sidewalls of the second conductive feature are exposed to the air spacer; a metal cap covering the second conductive feature and extending over the air spacer, wherein the air spacer is sealed by a bottom surface of the metal cap; a first etch stop layer on the dielectric layer, wherein a sidewall of the first etch stop layer physically contacts a sidewall of the metal cap; and a second etch stop layer extending on a top surface of the metal cap and a top surface of the first etch stop layer.

The embodiments of the present disclosure provide a bonding device for a chip on film and a display panel and a bonding method for the same. The bonding device includes: a bearing stage having a horizontal bearing surface for supporting at least one row of display panels, wherein one row of the at least one row of display panels has a row of first bonding regions; a grasping unit disposed above the bearing stage and configured to grasp at least a partial area of the entire chip on film so that a row of second bonding regions of the entire chip on film is horizontally located above the one row of display panels; and a bonding unit configured to bond the row of second bonding regions which has been aligned with the row of first bonding regions to the row of first bonding regions.