A curable resin or adhesive composition includes at least one monomer, a photoinitiator capable of initiating polymerization of the monomer when exposed to light, and at least one energy converting material, preferably a phosphor, capable of producing light when exposed to radiation (typically X-rays). The material is particularly suitable for bonding components at ambient temperature in situations where the bond joint is not accessible to an external light source. An associated method includes: placing a polymerizable adhesive composition, including a photoinitiator and energy converting material, such as a down-converting phosphor, in contact with at least two components to be bonded to form an assembly; and, irradiating the assembly with radiation at a first wavelength, capable of conversion (down-conversion by the phosphor) to a second wavelength capable of activating the photoinitiator, to prepare items such as inkjet cartridges, wafer-to-wafer assemblies, semiconductors, integrated circuits, and the like.

A Micro LED transferring method, a Micro LED display panel and a Micro LED display device are provided. The Micro LED display panel includes a substrate, a pixel defining layer including multiple openings, first conducting layer located in the multiple openings, photosensitive conductive bonding layers and Micro LED structures. The photosensitive conductive bonding layer is solidified after receiving light, such that elements adhered on two opposite surfaces of the photosensitive conductive bonding layer are bonded together. Due to the photosensitive conductive bonding layer, a Micro LED is detected during a transferring process rather than after a bonding process, thereby eliminating a step of removing a bonded abnormal Micro LED, thus simplifying the detecting and repairing processes of Micro LEDs.

A mounting method of an electronic device includes providing an electronic device which includes a semiconductor chip body including an upper surface, a lower surface opposite to the upper surface, and side surfaces connecting the upper surface and the lower surface, a plurality of bumps disposed on the lower surface, and an under-fill element disposed on at least one side surface. The method further includes mounting the electronic device on a printed circuit board including connecting pads formed thereon. The bumps of the semiconductor chip body are connected to the connecting pads. The method additionally includes heating the under-fill element to a predetermined temperature to form an under-fill layer between the lower surface of the semiconductor chip body and the printed circuit board.

Provided is an inkjet adhesive which is applied using an inkjet device, wherein the adhesive can suppress generation of voids in the adhesive layer and, after bonding, can enhance adhesiveness, moisture-resistant adhesion reliability, and cooling/heating cycle reliability. An inkjet adhesive according to the present invention comprises a photocurable compound, a photo-radical initiator, a thermosetting compound having one or more cyclic ether groups or cyclic thioether groups, and a compound capable of reacting with the thermosetting compound, and the compound capable of reacting with the thermosetting compound contains aromatic amine.

Embodiments of the present invention provide for the enhancement of transistors in a semiconductor structure using a strain layer. The structure comprises a patterned layer consisting of an excavated region and a pattern region, a strain layer located in the excavated region and on the pattern region, an active layer located above the strain layer, a field effect transistor formed in the active layer, and a handle layer located above the active layer. The field effect transistor comprises a source, a drain, and a channel. The channel lies completely within a lateral extent of the pattern region. The source and the drain each lie only partially within the lateral extent of the pattern region. The strain layer alters a carrier mobility of the channel. In some embodiments, the strain layer is introduced to the back side of a semiconductor-on-insulator structure.

Embodiments of the present invention provide for the enhancement of transistors in a semiconductor structure using a strain layer. The structure comprises a patterned layer consisting of an excavated region and a pattern region, a strain layer located in the excavated region and on the pattern region, an active layer located above the strain layer, a field effect transistor formed in the active layer, and a handle layer located above the active layer. The field effect transistor comprises a source, a drain, and a channel. The channel lies completely within a lateral extent of the pattern region. The source and the drain each lie only partially within the lateral extent of the pattern region. The strain layer alters a carrier mobility of the channel. In some embodiments, the strain layer is introduced to the back side of a semiconductor-on-insulator structure.

Provided is an inkjet adhesive which is applied using an inkjet device, wherein the adhesive can suppress generation of voids in the adhesive layer and, after bonding, can enhance adhesiveness, moisture-resistant adhesion reliability, and cooling/heating cycle reliability. An inkjet adhesive according to the present invention comprises a photocurable compound, a photo-radical initiator, a thermosetting compound having one or more cyclic ether groups or cyclic thioether groups, and a compound capable of reacting with the thermosetting compound, and the compound capable of reacting with the thermosetting compound contains aromatic amine.

The invention relates to a method for manufacturing an electronic device (1) comprising a bonding phase (P1) of said electronic device (1), comprising: a step (E2) of applying a bonding layer (11) consisting of a photosensitive polymer to a surface of the electronic device (1) and/or to an interface surface (S3) of a manufacturing element (3, 7); a step (E4) of bringing the manufacturing element (3, 7) into contact with the electronic device (1) so as to adhere the manufacturing element (3, 7) to the electronic device (1) via the bonding layer (11); and a release phase (P4), in which the bonding layer (11) is exposed to a first light radiation having a first wavelength so as to dissociate the manufacturing element (3, 7) from the bonding layer (11).

According to an embodiment of the present disclosure, a bonding structure is provided, the bonding structure including: a first substrate including a first bonding surface including a first signal transmission metal region and a first ground metal region insulated from the first signal transmission metal region; and a second substrate bonded to the first substrate, the second substrate including a second bonding surface including a second signal transmission metal region and a second ground metal region insulated from the second signal transmission metal region, wherein the first signal transmission metal region and the second signal transmission metal region are bonded, and the first ground metal region and the second ground metal region are bonded.

In various embodiments this disclosure is directed to conductive adhesives layers that can be used, in one example embodiment, to connect one or more shielding structures (for example, metal cans and/or covers) to a semiconductor package to enclose one or more electronic components on the semiconductor package. In another embodiment, the conductive adhesive layers disclosed herein can be used in connection with optoelectronic devices (for example, optoelectronic devices including laser diodes and/or avalanche photodiodes, APDs). In one embodiment, the conductive adhesives can additionally be used for thermal dissipation and for electrical contact in connection with one or more electronic components on a semiconductor package. In one embodiment, various materials including, spray prints, conductive paste, inks (for example, sintering silver-based materials), epoxy material (for example, epoxy materials filled with silver and/or other metal particles) can be used to provide a conductive adhesive layer.