A crystal oscillator (101) includes: a piezoelectric resonator plate (2) on which a first excitation electrode and a second excitation electrode are formed; a first sealing member (3) covering the first excitation electrode of the piezoelectric resonator plate (2); a second sealing member (4) covering the second excitation electrode of the piezoelectric resonator plate (2); and an internal space (13) formed by bonding the first sealing member (3) to the piezoelectric resonator plate (2) and by bonding the second sealing member (4) to the piezoelectric resonator plate (2), so as to hermetically seal a vibrating part including the first excitation electrode and the second excitation electrode of the piezoelectric resonator plate (2). An electrode pattern (371) including a mounting pad for wire bonding is formed on an outer surface (first main surface (311)) of the first sealing member (3).

A fan-out package includes a redistribution structure having redistribution-side bonding structures, a plurality of semiconductor dies including a respective set of die-side bonding structures that is attached to a respective subset of the redistribution-side bonding structures through a respective set of solder material portions, and an underfill material portion laterally surrounding the redistribution-side bonding structures and the die-side bonding structures of the plurality of semiconductor dies. A subset of the redistribution-side bonding structures is not bonded to any of the die-side bonding structures of the plurality of semiconductor dies and is laterally surrounded by the underfill material portion, and is used to provide uniform distribution of the underfill material during formation of the underfill material portion.

An apparatus is provided which comprises: a substrate, a die site on the substrate to couple with a die, a die side component site on the substrate to couple with a die side component, and a raised barrier on the substrate between the die and die side component sites to contain underfill material disposed at the die site, wherein the raised barrier comprises electroplated metal. Other embodiments are also disclosed and claimed.

The present disclosure is directed to a lead frame including a die pad with cavities, and methods for attaching a semiconductor die to the lead frame. The cavities allow for additional adhesive to be formed on the die pad at the corners of the semiconductor die, and prevent the additional adhesive from overflowing on to active areas of the semiconductor die.

An electronic module is disclosed. The electronic module can include a package substrate, an integrated device die, a dam structure, and a mounting compound. The integrated device die can have an upper side, a lower side, and an outer side edge. The dam structure can have a first sidewall and a second sidewall opposite the first sidewall. The second sidewall can be nearer to the outer side edge than the first sidewall. The first sidewall can be laterally positioned between a center of the lower side of the integrated device die and the outer side edge. The dam structure can be disposed between a portion of the package substrate and a portion of the lower side of the integrated device die. The mounting compound can be disposed between the lower side of the integrated device die and the package substrate. The dam structure can be positioned between the mounting compound and the outer side edge of the integrated device die.

In a semiconductor package, flow guiding strips are provided on a guiding area of a flexible substrate to separate a chip and the flexible substrate such that a filling material flowing between the chip and the flexible substrate can squeeze out the air between the chip and the flexible substrate to improve the reliability of the semiconductor package.

A semiconductor die package that has a substrate with one or more substrate layers with one or more substrate connections. A substrate layer can include one or more redistribution layers (RDLs). One or more dies (e.g., multiple dies) are disposed on a top substrate layer. The dies have one or more die external connections. Some of the die external connections are electrically connected to one or more substrate connections. One or more metallic dam stiffeners form into a dam enclosure that is disposed on and physically connected to the top substrate layer. The dam enclosure encloses one or more of the dies. The metallic dam enclosure has one or more electrically connected regions where the metallic dam enclosure is electrically connected to one or more of the substrate horizontal connections and one or more electrically insulated regions where the metallic dam enclosure is electrically insulated from one or more of the substrate horizontal connections and the substrate via connections. In different embodiments, the dam enclosure stiffens the substrates/package during manufacture, assembly, and operation; provides confinement for underfill application; and provides a heat conduction path for heat removal. Methods of manufacturing and assembling the die package are disclosed.

A semiconductor package includes a semiconductor chip on a package substrate, a dam structure disposed on the package substrate and surrounding the semiconductor chip, the dam structure including a first dam portion having a first length in a vertical direction, and a second dam portion connected to the first dam portion and extending from an outer side of the first dam portion, and having a second length less than the first length in the vertical direction, and an adhesive layer disposed on the package substrate, the adhesive layer including a first adhesive portion disposed between the semiconductor chip and the package substrate and overlapping the semiconductor chip in the vertical direction, and a second adhesive portion on an outer side of the semiconductor chip and including at least a part contacting a top surface of the first dam portion.

Semiconductor packaging substrates and processing sequences are described. In an embodiment, a packaging substrate includes a build-up structure, and a patterned metal contact layer partially embedded within the build-up structure and protruding from the build-up structure. The patterned metal contact layer may include an array of surface mount (SMT) metal bumps in a chip mount area, a metal dam structure or combination thereof.

A package comprising a substrate, an integrated device, and an interconnect integrated device. The substrate includes a first surface and a second surface. The substrate further includes a plurality of interconnects. The integrated device is coupled to the substrate. The interconnect integrated device is coupled to a surface of the substrate. The integrated device, the interconnect integrated device and the substrate are configured to provide an electrical path for an electrical signal of the integrated device, that travels through at least the substrate, then through the interconnect integrated device and back through the substrate.