Techniques are disclosed for facilitating interconnecting semiconductor devices. In one example, a method of interconnecting a first substrate to a second substrate is provided. The method includes forming a first plurality of contacts on the first substrate. The method further includes forming an insulative layer on the first substrate. The method further includes forming a second plurality of contacts on the second substrate. The method further includes joining the first plurality of contacts to the second plurality of contacts to form interconnects between the first substrate and the second substrate. When the first and second substrates are joined, at least a portion of each of the interconnects is surrounded by the insulative layer. Related systems and devices are also provided.

An integrated circuit structure may be formed having a first integrated circuit device, a second integrated circuit device electrically coupled to the first integrated circuit device with a plurality of device-to-device interconnects, and at least one jumping drops vapor chamber between the first integrated circuit device and the second integrated circuit device wherein at least one device-to-device interconnect of the plurality of device-to-device interconnects extends through the jumping drops vapor chamber. In one embodiment, the integrated circuit structure may include three or more integrated circuit devices with at least two jumping drops vapor chambers disposed between the three or more integrated circuit devices. In a further embodiment, the two jumping drops chambers may be in fluid communication with one another.

A camera assembly includes a photosensitive unit, including a photosensitive chip and an optical filter mounted on the photosensitive chip; functional components; and an encapsulation layer, embedded with the photosensitive unit and the functional components. The photosensitive chip and the functional components are exposed from a bottom surface of the encapsulation layer. A top surface of the encapsulation layer is higher than the photosensitive chip and functional components and exposes the optical filter. The photosensitive chip has soldering pads facing away from the bottom surface of the encapsulation layer. The functional components have soldering pads exposed from the bottom surface of the encapsulation layer. The camera assembly further includes a redistribution layer structure, disposed on the bottom surface of the encapsulation layer and electrically connecting to the soldering pads.

The present disclosure provides a method for packaging a camera assembly. The method includes: providing a photosensitive chip; mounting an optical filter on the photosensitive chip; temporarily bonding the photosensitive chip and functional components on a carrier substrate, where the photosensitive chip has soldering pads facing away from the carrier substrate and the functional components have soldering pads facing toward the carrier substrate; forming an encapsulation layer covering the carrier substrate, the photosensitive chip, and the functional components, and exposing the optical filter; after the encapsulation layer is formed, removing the carrier substrate; and after the carrier substrate is removed, forming a redistribution layer structure on a side of the encapsulation layer facing away from the optical filter to electrically connect the soldering pads of the photosensitive chip with the soldering pads of the functional components.

The present disclosure relates to micro-LED chips, methods for manufacturing the same, and display devices. The micro-LED chip includes: a driving backplane including at least one first electrode, a groove being provided above the first electrode, and the first electrode being located at a bottom of the groove; the groove being filled with a conductive material, and the conductive material being obtained by curing a corresponding conductive ink; and a light emitting chip including at least one second electrode; and the first electrode is connected to the second electrode through the conductive material.

A substrate treating apparatus for treating substrates includes a plurality of substrate treatment lines arranged vertically for carrying out plural types of treatment on the substrates while transporting the substrates substantially horizontally, and a controller for changing processes of treatment carried out on the substrates for each of the substrate treatment lines. By changing the processes of treatment carried out for the substrates for each substrate treatment line, the processes of treatment carried out for the substrates can be changed for each substrate conveniently. Thus, a plurality of different processes of treatment corresponding to the number of substrate treatment lines can be carried out in parallel for the respective substrates.

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.

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 wafer-level packaging method includes providing a base substrate and providing first chips. A photolithographic bonding layer is formed on the base substrate or on the first chips. First vias are formed in the photolithographic bonding layer. The first chips are pre-bonded to the base substrate through a photolithographic bonding layer with each first chip corresponding to a first via. A thermal compression bonding process is used to bond the first chips to the base substrate such that an encapsulation material fills between adjacent first chips and covers the first chips and the base substrate. The base substrate is etched to form second vias through the base substrate with each second via connected to a first via to form a first conductive via. A first conductive plug is formed in the first conductive via to electrically connect to a corresponding first chip.