A semiconductor device includes a first semiconductor chip having a first surface with a semiconductor element and a second surface opposing the first surface. A first metal layer has a third surface supporting the first semiconductor chip and a fourth surface opposing the third surface. The third surface is larger than the second surface. A resin layer has a fifth surface facing the first semiconductor chip and a sixth surface facing the first metal layer. A pad is on the first surface of the first semiconductor chip. A first via contact is within the resin layer on the third surface of the first metal layer. A second via contact is within the resin layer on the pad. The first and second via contacts are connected to first and the second interconnects, respectively.

A method for producing a multiplicity of semiconductor chips (13) is provided, comprising the following steps: providing a wafer (1) comprising a multiplicity of semiconductor bodies (2), wherein separating lines (9) are arranged between the semiconductor bodies (2), depositing a contact layer (10) on the wafer (1), wherein the material of the contact layer (10) is chosen from the following group: platinum, rhodium, palladium, gold, and the contact layer (10) has a thickness of between 8 nanometres and 250 nanometres, inclusive, applying; the wafer (1) to a film (11), at least partially severing the wafer (1) in the vertical direction along the separating lines (9) or introducing fracture nuclei (12) into the wafer (1) along the separating lines (9), and breaking the wafer (1) along the separating lines (9) or expanding the film (11) such that a spatial separation of the semiconductor chips (13) takes place, wherein the contact layer (10) is also separated. A semiconductor chip, a component and a method for producing the latter are also provided.

A method for producing a multiplicity of semiconductor chips (13) is provided, comprising the following steps: providing a wafer (1) comprising a multiplicity of semiconductor bodies (2), wherein separating lines (9) are arranged between the semiconductor bodies (2), depositing a contact layer (10) on the wafer (1), wherein the material of the contact layer (10) is chosen from the following group: platinum, rhodium, palladium, gold, and the contact layer (10) has a thickness of between 8 nanometres and 250 nanometres, inclusive, applying; the wafer (1) to a film (11), at least partially severing the wafer (1) in the vertical direction along the separating lines (9) or introducing fracture nuclei (12) into the wafer (1) along the separating lines (9), and breaking the wafer (1) along the separating lines (9) or expanding the film (11) such that a spatial separation of the semiconductor chips (13) takes place, wherein the contact layer (10) is also separated. A semiconductor chip, a component and a method for producing the latter are also provided.

A method of and system for adhesive bonding by a) providing a polymerizable adhesive composition on a surface of an element to be bonded to form an assembly; b) irradiating the assembly with radiation at a first wavelength capable of vulcanization of bonds in the polymerizable adhesive composition by activation of sulfur-containing compound with at least one selected from x-ray, e-beam, visible, or infrared light to thereby generate ultraviolet light in the polymerizable adhesive composition; and c) adhesively joining two or more components together by way of the polymerizable adhesive composition, and a curable polymer for use therein.

A method of and system for adhesive bonding by a) providing a polymerizable adhesive composition on a surface of an element to be bonded to form an assembly; b) irradiating the assembly with radiation at a first wavelength capable of vulcanization of bonds in the polymerizable adhesive composition by activation of sulfur-containing compound with at least one selected from x-ray, e-beam, visible, or infrared light to thereby generate ultraviolet light in the polymerizable adhesive composition; and c) adhesively joining two or more components together by way of the polymerizable adhesive composition, and a curable polymer for use therein.

An anisotropic conductive film includes, as conductive particles for anisotropic conductive connection, metal particles such as solder particles having on the surface an oxide film. In this anisotropic conductive film, the metal particles are contained in an insulating film and regularly arranged as viewed in a plan view. A flux is disposed to be in contact with, or in proximity to, at least one of ends of the metal particles on a front surface side of the anisotropic conductive film and a rear surface side of the anisotropic conductive film. Preferable metal particles are solder particles. Preferably, the insulating film has a structure of two layers, and the metal particles are disposed between the two layers.

Provided is a multilayer substrate including laminated semiconductor substrates each having a penetrating hole (hereinafter referred to as through hole) having a plated film formed in the inner surface. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are selectively present at a position where the through holes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through holes are connected by the conductive particles, and the semiconductor substrates each having the through hole are bonded by an insulating adhesive.

Provided is a multilayer substrate including laminated semiconductor substrates each having a penetrating hole (hereinafter referred to as through hole) having a plated film formed in the inner surface. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are selectively present at a position where the through holes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through holes are connected by the conductive particles, and the semiconductor substrates each having the through hole are bonded by an insulating adhesive.

A display device according to an example embodiment of the present disclosure includes a stretchable display panel; and an actuator configured to deform the display panel, wherein the display panel includes a first area that is protruded by the actuator, a second area that is not protruded by the actuator, and a third area that is between the first area and the second area, wherein a plurality of pixels are disposed in the first area and the second area, wherein in the third area, only a plurality of connection lines connecting the plurality of pixels disposed in the first area and the plurality of pixels disposed in the second area are disposed, so that three-dimensional display capability of the display device can be improved.

A semiconductor assembly with a package on package (POP) structure includes a first semiconductor package having a first lower substrate, a first upper substrate facing the first lower substrate, and a first semiconductor chip mounted on an area of the first lower substrate. The POP structure further includes a second semiconductor package having a second lower substrate stacked on the first semiconductor package and spaced apart from the first semiconductor package, and a second semiconductor chip mounted in an area of the second lower substrate. At least one passive element is disposed in one of the first upper substrate and the second lower substrate and electrically connected to the second semiconductor chip.