A three-dimensional (3D) integrated circuit (IC) includes a first IC die and a second IC die. The first IC die includes a first semiconductor substrate, and a first interconnect structure over the first semiconductor substrate. The second IC die includes a second semiconductor substrate, and a second interconnect structure that separates the second semiconductor substrate from the first interconnect structure. A seal ring structure separates the first interconnect structure from the second interconnect structure and perimetrically surrounds a gas reservoir between the first IC die and second IC die. The seal ring structure includes a sidewall gas-vent opening structure configured to allow gas to pass between the gas reservoir and an ambient environment surrounding the 3D IC.

A light emitting device includes a wavelength conversion layer, at least one light emitting unit and a reflective protecting element. The wavelength conversion layer has an upper surface and a lower surface opposite to each other. The light emitting unit has two electrode pads located on the same side of the light emitting unit. The light emitting unit is disposed on the upper surface of the wavelength conversion layer and exposes the two electrode pads. The reflective protecting element encapsulates at least a portion of the light emitting unit and a portion of the wavelength conversion layer, and exposes the two electrode pads of the light emitting unit.

Air cavity packages and methods for producing air cavity packages containing sintered bonded components, multipart window frames, and/or other unique structural features are disclosed. In one embodiment, a method for fabricating an air cavity package includes the step or process of forming a first metal particle-containing precursor layer between a base flange and a window frame positioned over the base flange. A second metal particle-containing precursor layer is further formed between the base flange and a microelectronic device positioned over the base flange. The metal particle-containing precursor layers are sintered substantially concurrently at a maximum processing temperature less than melt point(s) of metal particles within the layers to produce a first sintered bond layer from the first precursor layer joining the window frame to the base flange and to produce a second sintered bond layer from the second precursor layer joining the microelectronic device to the base flange.

Air cavity packages and methods for producing air cavity packages containing sintered bonded components, multipart window frames, and/or other unique structural features are disclosed. In one embodiment, a method for fabricating an air cavity package includes the step or process of forming a first metal particle-containing precursor layer between a base flange and a window frame positioned over the base flange. A second metal particle-containing precursor layer is further formed between the base flange and a microelectronic device positioned over the base flange. The metal particle-containing precursor layers are sintered substantially concurrently at a maximum processing temperature less than melt point(s) of metal particles within the layers to produce a first sintered bond layer from the first precursor layer joining the window frame to the base flange and to produce a second sintered bond layer from the second precursor layer joining the microelectronic device to the base flange.

A method includes applying a die attach material to a die pad of an integrated circuit. The die attach material is employed as a bonding material to the die pad. The method includes mounting an integrated circuit die to the die pad of the integrated circuit via the die attach material. The method includes printing an adhesion deposition material on the die attach material appearing at the interface of the integrated circuit die and the die pad of the integrated circuit to mitigate delamination between the integrated circuit die and the die pad.

A method includes applying a die attach material to a die pad of an integrated circuit. The die attach material is employed as a bonding material to the die pad. The method includes mounting an integrated circuit die to the die pad of the integrated circuit via the die attach material. The method includes printing an adhesion deposition material on the die attach material appearing at the interface of the integrated circuit die and the die pad of the integrated circuit to mitigate delamination between the integrated circuit die and the die pad.

A packaged semiconductor device includes a substrate and a contact pad disposed on the semiconductor substrate. The packaged semiconductor device also includes a dielectric layer disposed over the contact pad, the dielectric layer including a first opening over the contact pad, and an insulator layer disposed over the dielectric layer, the insulator layer including a second opening over the contact pad. The packaged semiconductor device also includes a molding material disposed around the substrate, the dielectric layer, and the insulator layer and a wiring over the insulator layer and extending through the second opening, the wiring being electrically coupled to the contact pad.

A method of forming a solder joint, the method comprising: (i) providing a solder flux; (ii) providing solder particles; (iii) providing two or more work pieces to be joined; and (iv) heating the solder flux and the solder particles in the vicinity of the two or more work pieces to be joined to form: (i) a solder joint between the two or more work pieces to be joined, and (ii) a solder flux residue. The solder flux residue substantially covers the exposed surfaces of the solder joint.

A semiconductor package and a method of manufacturing a semiconductor package. As non-limiting examples, various aspects of this disclosure provide various semiconductor packages, and methods of making thereof, that comprise a cover layer that enhances reliability of the semiconductor packages.

An electrode connection structure includes: a first electrode of an electrical circuit; and a second electrode of the electrical circuit that is electrically connected to the first electrode. The first and second electrodes are oppositely disposed in direct or indirect contact with each other. A plated lamination is substantially uniformly formed by plating process from a surface of a contact region and opposed surfaces of the first and second electrodes. A void near the surface of the contact region is filled by formation of the plated lamination. Portions of the plated lamination formed from the opposed surfaces of the first and second electrodes in a region other than the contact region are not joined together.