A high-frequency package includes a radio wave shielding portion that shields radio waves radiated from a high-frequency component, a radio wave absorber that is arranged facing the high-frequency component and that absorbs the radio waves, and an adjusting means that enables adjustment of distance from the radio wave absorber to the high-frequency component by adjusting a position of the radio wave absorber with respect to the radio wave shielding portion.

An interposer structure includes: an interposer substrate; an interposer through electrode penetrating through the interposer substrate in a vertical direction; a redistribution structure on the interposer substrate and including a redistribution pattern connected to the interposer through electrode and a redistribution insulating layer on side surfaces of the redistribution pattern on the interposer substrate; a conductive post on the redistribution structure and connected to the redistribution pattern; and an interposer insulating layer on side surfaces of the conductive post on the redistribution structure.

Electronic assemblies and methods of assembly are described. In an embodiment, an electronic assembly includes a stiffener structure shear bonded to an opposite side of a module substrate from a ball grid array (BGA) package. The stiffener structure may be shear bonded at elevated temperature after bonding of the BGA package to lock in a flat or near-flat surface contour of the module substrate.

Disclosed herein are channeled lids for integrated circuit (IC) packages, as well as related methods and devices. For example, in some embodiments, an IC package may include a die between a lid and a package substrate. A bottom surface of the lid may include a channel that at least partially overlaps the die.

A semiconductor package includes a first substrate, a first chip structure and a second chip structure spaced apart from each other on the first substrate, a gap region being defined between the first and second chip structures, and a heat dissipation member covering the first chip structure, the second chip structure, and the first substrate, the heat dissipation member including a first trench in an inner top surface of the heat dissipation member, wherein the first trench vertically overlaps with the gap region and has a width greater than a width of the gap region, and wherein the first trench vertically overlaps with at least a portion of a top surface of the first chip structure or a portion of a top surface of the second chip structure.

A method and structure for packaging a semiconductor device are provided. In an embodiment a first substrate is bonded to a second substrate, which is bonded to a third substrate. A thermal interface material is placed on the second substrate prior to application of an underfill material. A ring can be placed on the thermal interface material, and an underfill material is dispensed between the second substrate and the third substrate. By placing the thermal interface material and ring prior to the underfill material, the underfill material cannot interfere with the interface between the thermal interface material and the second substrate, and the thermal interface material and ring can act as a physical barrier to the underfill material, thereby preventing overflow.

A semiconductor package is disclosed for efficiently facilitating heat dissipation. The semiconductor package includes a substrate layer, a chip, a housing lid and thermal-conductive liquid. A chip is disposed on the substrate layer and electrically coupled to the substrate layer. The chip includes at least one through silicon via (TSV). The housing lid is disposed above both the substrate layer and the chip. Also, the housing lid is coupled to the substrate layer at its edge for forming an internal space that encompasses the chip. The thermal-conductive liquid is filled within the internal space.

Techniques for integrating two-phase cooling into a microprocessor chip package lid are provided. In one aspect, a vapor chamber lid device includes: an evaporator plate; a condenser plate attached to the evaporator plate such that a cavity is formed between the evaporator plate and the condenser plate; a thermal insulation layer sandwiched between the evaporator plate and the condenser plate; and a working fluid enclosed within the cavity, wherein the working fluid partially fills the cavity. At least one heat-dissipating device can be placed in thermal contact with the evaporator plate via a thermal interface material. A method is also provided for forming the vapor chamber lid device.

The present invention relates to a molded air-cavity package. In addition, the present invention is related to a device comprising the same. The present invention is particularly related to molded air-cavity packages for radio-frequency ‘RF’ applications including but not limited to RF power amplifiers.

Instead of using hard-stop features that are arranged around the entire perimeter of the package in a continuous manner, the present invention proposes to use spaced apart pillars formed by first and second cover supporting elements. By using only a limited amount of pillars, e.g. three or four, the position of the cover relative to the body can be defined in a more predictable manner. This particularly holds if the pillars are arranged in the outer corners of the package.

A semiconductor package includes a first substrate, a first chip structure and a second chip structure spaced apart from each other on the first substrate, a gap region being defined between the first and second chip structures, and a heat dissipation member covering the first chip structure, the second chip structure, and the first substrate, the heat dissipation member including a first trench in an inner top surface of the heat dissipation member, wherein the first trench vertically overlaps with the gap region and has a width greater than a width of the gap region, and wherein the first trench vertically overlaps with at least a portion of a top surface of the first chip structure or a portion of a top surface of the second chip structure.