A semiconductor device has a substrate and a first semiconductor die disposed over the substrate. A first metal frame is disposed over the substrate around the first semiconductor die. A first metal lid is disposed over the first metal frame. A flap of the first metal lid includes an elastic characteristic to latch onto the first metal frame. An edge of the flap can have a castellated edge. A recess in the first metal frame and a protrusion on the first metal lid can be used to latch the first metal lid onto the first metal frame. A second metal frame and second metal lid can be disposed over an opposite surface of the substrate from the first metal frame.

A package comprising a substrate comprising a plurality of interconnects, a first integrated device coupled to the substrate, a second integrated device coupled to the substrate, and an interconnect device coupled to the substrate. The first integrated device, the second integrated device, the interconnect device and the substrate are configured to provide an electrical path for an electrical signal between the first integrated device and the second integrated device, that extends through at least the substrate, through the interconnect device and back through the substrate. The electrical path includes at least one interconnect that extends diagonally.

An electronic package is provided and includes an electronic element, an intermediary structure disposed on the electronic element, and a heat dissipation element bonded to the electronic element through the intermediary structure. The intermediary structure has a flow guide portion and a permanent fluid combined with the flow guide portion so as to be in contact with the electronic element, thereby achieving a preferred heat dissipation effect and preventing excessive warping of the electronic element or the heat dissipation element due to stress concentration.

A package comprising a substrate comprising a plurality of interconnects, a first integrated device coupled to the substrate, a second integrated device coupled to the substrate, and an interconnect device coupled to the substrate. The first integrated device, the second integrated device, the interconnect device and the substrate are configured to provide an electrical path for an electrical signal between the first integrated device and the second integrated device, that extends through at least the substrate, through the interconnect device and back through the substrate. The electrical path includes at least one interconnect that extends diagonally.

A heat spreading plate is suitable to be a top cover of a chip package structure. The heat spreading plate includes a main body and an isolating frame. The main body includes a plurality of metal sheets which are arranged spaced apart from one another totally and capable of thermally connecting different working chips mounted within the chip package structure, respectively. A gap is formed between any two neighboring ones of the metal sheets to completely separate them. The isolating frame surrounds the outer edges of the metal sheets and fills into the gaps for fixedly holding the metal sheets together. One surface of the isolating frame is formed with a plurality of hollow recesses, and each of the metal sheets is exposed outwards from one of the hollow recesses.

A semiconductor structure and a method for fabricating the same are disclosed. A semiconductor structure includes a first substrate, a package, a second substrate, and a lid. The package is attached to a first side of the first substrate. The second substrate is attached to a second side of the first substrate. The lid is connected to the first substrate and the second substrate. The lid includes a ring part over the first side of the first substrate. The ring part and the first substrate define a space and the package is accommodated in the space. The lid further includes a plurality of overhang parts which extend from corner sidewalls of the ring part toward the second substrate to cover corner sidewalls of the first substrate.

A semiconductor device includes a circuit substrate, a semiconductor package, and a metallic cover. The semiconductor package is disposed on the circuit substrate. The metallic cover is disposed over the semiconductor package and over the circuit substrate. The metallic cover comprises a lid and outer flanges. The lid overlies the semiconductor package. The outer flanges are disposed at edges of the lid, are connected with the lid, extend from the lid towards the circuit substrate, and face side surfaces of the semiconductor package. The lid has a first region that is located over the semiconductor package and is thicker than a second region that is located outside a footprint of the semiconductor package.

A mechanism is provided to remove heat from an integrated circuit (IC) device die by directing heat through a waveguide to a heat sink. Embodiments provide the waveguide mounted on top of a package containing the IC device die. The waveguide is thermally coupled to the IC device die. The waveguide transports the heat to a heat sink coupled to the waveguide and located adjacent to the package on top of a printed circuit board on which the package is mounted. Embodiments provide both thermal dissipation of the generated heat while at the same time maintaining good radio frequency (RF) performance of the waveguide.

A semiconductor device includes a circuit substrate, a semiconductor package, and a metallic cover. The semiconductor package is disposed on the circuit substrate. The metallic cover is disposed over the semiconductor package and over the circuit substrate. The metallic cover comprises a lid and outer flanges. The lid overlies the semiconductor package. The outer flanges are disposed at edges of the lid, are connected with the lid, extend from the lid towards the circuit substrate, and face side surfaces of the semiconductor package. The lid has a first region that is located over the semiconductor package and is thicker than a second region that is located outside a footprint of the semiconductor package.

Embodiments disclosed herein include electronic packages. In an embodiment, the electronic package comprises an interposer, a first die attached to the interposer, and a second die attached to the interposer. In an embodiment, the electronic package further comprises a heatsink thermally coupled to the first die and the second die. In an embodiment, the heatsink has a first surface facing away from the first die and the second die and a second surface facing the first die and the second die. In an embodiment, the heatsink comprises a thermal break between the first die and the second die.