A method of manufacturing a semiconductor device includes embedding electrodes in insulating layers exposed to the joint surfaces of a first substrate and a second substrate, subjecting the joint surfaces of the first substrate and the second substrate to chemical mechanical polishing, to form the electrodes into recesses recessed as compared to the insulating layer, laminating insulating films of a uniform thickness over the entire joint surfaces, forming an opening by etching in at least part of the insulating films covering the electrodes of the first substrate and the second substrate, causing the corresponding electrodes to face each other and joining the joint surfaces of the first substrate and the second substrate to each other, heating the first substrate and the second substrate joined to each other, causing the electrode material to expand and project through the openings, and joining the corresponding electrodes to each other.

Disclosed are an array substrate, and a display device, and a method for manufacturing the same. The array substrate includes: a base substrate, and a thin film transistor, a planarization pattern, a bonding pattern, and a conductive structure that are disposed on the base substrate. The thin film transistor, the planarization pattern, and the bonding pattern are laminated in a direction going distally from the base substrate. The planarization pattern is provided with a via and a groove, the conductive structure is disposed in the via, wherein the bonding pattern is conductive and is electrically connected to the thin film transistor by the conductive structure, an orthographic projection of the bonding pattern on the base substrate falls outside an orthographic projection of the groove on the base substrate, and the groove is configured to accommodate an adhesive.

A flexible foil-based package is disclosed which comprises at least one flexible foil substrate on which at least one electronic device is mounted in flip-chip mounting technology. The flexible foil substrate is bent so that a recess is created in which the electronic device is arranged. A casting compound is applied to cover the electronic device.

Anisotropic conductive films, each including an insulating adhesive layer and conductive particles insulating adhesive layer in a lattice-like manner. Among center distances between an arbitrary conductive particle and conductive particles adjacent to the conductive particle, the shortest distance to the conductive particle is a first center distance; the next shortest distance is a second center distance. These center distances are 1.5 to 5 times the conductive particles' diameter. The arbitrary conductive particle, conductive particle spaced apart from the conductive particle by the first center distance, conductive particle spaced apart from the conductive particle by first center distance or second center distance form an acute triangle. Regarding this acute triangle, an acute angle formed between a straight line orthogonal to a first array direction passing through the conductive particles and second array direction passing through conductive particles being 18 to 35°. These anisotropic conductive films have stable connection reliability in COG connection.

A semiconductor device package includes a semiconductor device, a non-semiconductor substrate over the semiconductor device, and a first connection element extending from the semiconductor device to the non-semiconductor substrate and electrically connecting the semiconductor device to the non-semiconductor substrate.

A driving chip and a display device are provided herein. The driving chip includes a substrate, a plurality of connection bumps and a plurality of buffer bumps on the substrate. Each of the connection bumps and the buffer bumps is disposed on a first substrate of the substrate. The buffer bump includes a first end face with a height a, and the connection bump has a connection bump end face with a height b, a<b. The height is a distance from a corresponding end face of the connection bump or the buffer bump to the first surface. With the buffer bumps on the driving chip, stress buffering can be achieved, which can further improve the bonding effect of the driving chip.

A light-emitting device includes a carrier, a light-emitting element and a connection structure. The carrier includes a first electrical conduction portion. The light-emitting element includes a first light-emitting layer capable of emitting first light and a first contact electrode formed under the light-emitting layer. The first contact electrode is corresponded to the first electrical conduction portion. The connection structure includes a first electrical connection portion and a protective portion surrounding the first contact electrode and the first electrical connection portion. The first electrical connection portion includes an upper portion, a lower portion and a neck portion arranged between the upper portion and the lower portion. The lower portion has a width is wider than of the upper portion.

The display device includes a flexible base layer including a first region and a second region located around the first; a display unit on one surface of the first region and including a light emitting element; a driving circuit on the second region and including a plurality of first bumps arranged in a first row and a plurality of second bumps arranged in a second row, the driving circuit includes a third bump in the first row and disposed outward relative to the plurality of first bumps, a first and second reference bump each disposed at a center of the plurality of first and second bumps that are disposed along a reference line defined in a column direction vertically intersecting a row direction, the remaining first and second bumps excluding the first reference bump and the second reference bump arranged to have a preset slope with respect to the reference line.

There is provided a flexible electronic structure for bonding with an external circuit, comprising a flexible substrate, having a first surface, configured for bonding with the external circuit, and an opposing second surface, configured for engagement with a bonding tool, comprising at least one electronic component; at least one contact member, operatively coupled with said at least one electronic component and provided at said first surface of said flexible substrate, and adapted to operably interface with the external circuit after bonding, and at least one shield member, provided at said first surface so as to shieldingly overlap at least a portion of said at least one electronic component, adapted to withstand a predetermined pressure applied to said first surface and/or said opposing second surface during bonding with the external circuit.

There is provided a flexible electronic structure for bonding with an external circuit. The flexible electronic structure comprising: a flexible body having a first surface, the flexible body comprising at least one electronic component; at least one contact element configured to bond with the external circuit, the at least one contact element operatively coupled with the at least one electronic component and provided at the first surface of the flexible body, and arranged to operably interface with the external circuit after bonding, and at least one support element provided at the first surface of the flexible body, each support element arranged to contact a corresponding surface element disposed on a first surface of an external structure comprising the external circuit.