There is provided a release agent composition for photoirradiation release, containing: a Novolac resin, a (meth)acrylic acid ester-based polymer, and a solvent.

Described herein are manufacturing techniques and packages that enable wafer-scale heterogenous integration of electronic integrated circuits (EIC) with photonic integrated circuits (PIC) using a reconstitution-based fabrication approach. Wafer-scale photonic devices are formed by assembling strips of known-good dies (KGD). Such strips include arrays of adjacent reticles that have been singulated from a wafer. A strip can include a single row (or column) of reticles singulated from a wafer or multiple rows (or columns) that are adjacent to one another, enabling two-dimensional assembly and increased coverage. Wafer reconstitution involves transferring and bonding one or more strips of KGDs to a target substrate. A KGD is a reticle that is not part of an exclusion zone and has been verified to work properly. Thus, a reconstituted wafer includes strips that have verified to be fully functional.

A semiconductor die assembly is introduced in this disclosure. The semiconductor die assembly includes one or more semiconductor dies, a dielectric layer disposed under a bottom surface of the one or more semiconductor dies, and metal fragments or a metal layer disposed under the dielectric layer, wherein metal-OH bonds or metal-OSiOH bonds are disposed on a bottom surface of the dielectric layer. Alternatively, the semiconductor die assembly includes one or more semiconductor dies, a metal layer disposed under a bottom surface of the one or more semiconductor dies, and a metal oxidation layer disposed under the dielectric layer, wherein the metal oxidation layer comprises metal-OH bonds or metal-OSiOH bonds.

A dry adhesive microfiber array comprising a plurality of fibers with enlarged tips, where the dry adhesive is capable of adhering to a surface of a silicon wafer and/or carrier, in which the dry adhesive can be debonded without the use of chemicals or heat and does not leave a residue on the surface of the wafer, and, a liquid can be introduced to the interface between the dry adhesive and semiconductor device to adjust the force of adhesion.

A bonded structure can include a first reconstituted element comprising a first element and having a first side comprising a first bonding surface and a second side opposite the first side. The first reconstituted element can comprise a first protective material disposed about a first sidewall surface of the first element. The bonded structure can comprise a second reconstituted element comprising a second element and having a first side comprising a second bonding surface and a second side opposite the first side. The first reconstituted element can comprise a second protective material disposed about a second sidewall surface of the second element. The second bonding surface of the first side of the second reconstituted element can be directly bonded to the first bonding surface of the first side of the first reconstituted element without an intervening adhesive along a bonding interface.

A package structure includes a first dielectric layer disposed on a first patterned circuit layer, a first conductive via in the first dielectric layer and electrically connected to the first patterned circuit layer, a circuit layer on the first dielectric layer, a second dielectric layer on the first dielectric layer and covering the circuit layer, a second patterned circuit layer on the second dielectric layer and including conductive features, a chip on the conductive features, and a molding layer disposed on the second dielectric layer and encapsulating the chip. The circuit layer includes a plurality of portions separated from each other and including a first portion and a second portion. The number of pads corresponding to the first portion is different from that of pads corresponding to the second portion. An orthographic projection of each portion overlaps orthographic projections of at least two of the conductive features.

The present invention relates to an ultra-thin light-emitting diode (LED) electrode assembly, a manufacturing method of the ultra-thin LED electrode assembly, and a transfer film of an ultra-thin LED used for manufacturing the ultra-thin LED electrode assembly and relates to an ultra-thin LED electrode assembly in which a plurality of LED elements are simultaneously transferred using a laser-assisted multi-chip transfer printing method to form and pattern the LED elements, thereby preventing process defects caused by omission of the LED elements during transfer and deviation thereof from an electrode line, and defects such as dark spots caused in an LED display, a manufacturing method of the ultra-thin LED electrode assembly, and a transfer film of an ultra-thin LED used for manufacturing the ultra-thin LED electrode assembly.

A display device and a method of manufacturing the display device are proposed. The method may include disposing light emitting elements on a first transfer film; stretching the first transfer film so that the plurality of light emitting elements are spaced apart from each other; transferring the light emitting elements onto a thin film transistor array substrate; and removing the transfer film from the light emitting elements.

A back grinding adhesive film used to protect a surface of a wafer, the back grinding adhesive film including a base material layer, and an adhesive resin layer which is formed on one surface side of the base material layer and configured with an ultraviolet curable adhesive resin material, in which, when a viscoelastic characteristic is measured after curing the ultraviolet curable adhesive resin material by irradiating with an ultraviolet ray, a storage elastic modulus at 5 C. E (5 C.) is 2.010.sup.6 to 2.010.sup.9 Pa, and a storage elastic modulus 100 C. E (100 C.) is 1.010.sup.6 to 3.010.sup.7 Pa.

A semiconductor device includes a semiconductor layer that includes a semiconductor substrate having a first thickness and has a main surface, a main surface electrode that is arranged at the main surface and has a second thickness less than the first thickness, and a pad electrode that is arranged on the main surface electrode and has a third thickness exceeding the first thickness.