A semiconductor device includes a semiconductor chip and a package structure mounted on a wiring substrate, and a lid for covering the semiconductor chip, which is fixed to the surface of the wiring substrate, without overlapping with the package structure in plan view. The lid includes an upper surface portion overlapping with the semiconductor chip, a flange portion fixed to the surface of the wiring substrate, and a slant portion for jointing the upper surface portion and the flange portion. Then, a distance from the surface of the wiring substrate to the top surface of the upper surface portion is larger than a distance from the surface of the wiring substrate to the top surface of the flange portion.

Various applications of interconnect substrates in power management systems are described.

The present disclosure provides embodiments for a semiconductor structure including a heat spreader that includes a graphene grid having a first major surface and a second major surface opposite the first major surface. The graphene grid has a plurality of holes, each hole having a first opening in the first major surface and a second opening in the second major surface. The heat spreader also includes a first copper portion covering the first major surface of the graphene grid, a second copper portion covering the second major surface of the graphene grid, and a plurality of copper vias filling the plurality of holes.

A device package may include a package substrate, a package cover disposed on the package substrate, and an integrated cooling assembly disposed between the package substrate and the package cover. The package cover generally has an inlet opening and an outlet opening disposed there through. The integrated cooling assembly includes a semiconductor device and a cold plate attached to the semiconductor device. The device package may include a material layer between the package cover and the cold plate. The cold plate may include a patterned first side and an opposite second side. The patterned first side may include a base surface and sidewalls extending downward from the base surface, where the base surface is spaced apart from the semiconductor device to collectively define a coolant channel. Here, the coolant channel is in fluid communication with the inlet opening and the outlet opening through openings disposed through respective portions of the material layer.

A package structure includes a first layer, a second layer and a third layer. The second layer includes an outer frame, a resonator and a chip. The second layer is arranged between the first layer and the third layer. The outer frame, the first layer and the third layer are constituted a rectangular accommodation portion. The resonator and the chip are located in the rectangular accommodation portion. The chip is located at a side of the resonator, and is electrically connected to the third layer and the resonator through a plurality of conductive components on the chip. A package structure in which the chip is located below the resonator is also provided.

Provided is a clip structure for a semiconductor package comprising: a first bonding unit bonded to a terminal part of an upper surface or a lower surface of a semiconductor device by using a conductive adhesive interposed therebetween, a main connecting unit which is extended and bent from the first bonding unit, a second bonding unit having an upper surface higher than the upper surface of the first bonding unit, an elastic unit elastically connected between the main connecting unit and one end of the second bonding unit, and a supporting unit bent and extended from the other end of the second bonding unit toward the main connecting unit, wherein the supporting unit is formed to incline at an angle of 1 through 179 from an extended surface of the main connecting unit and has an elastic structure so that push-stress applying to the semiconductor device while molding may be dispersed.

A semiconductor device has an antenna substrate and a component module disposed over the antenna substrate. The component module includes an electrical component, and a conductive structure formed around the electrical component. Alternatively, an electrical component can be disposed over the antenna substrate, and a conductive structure is disposed over the antenna substrate and around the electrical component. An encapsulant is deposited around the electrical component and conductive structure. A shielding material is formed over the component module, and a heat sink formed over the component module. The shielding material can be formed over the component module, while the heat sink is formed over the shielding material. Alternatively, the heat sink is formed over the component module, while the shielding material is formed over the heat sink. The conductive structure has a plurality of posts or a frame. A thermal interface material is disposed over the component module.

A power module includes a first conductor plate to which a first power semiconductor element is bonded, a second conductor plate to which a second power semiconductor element is bonded, the second conductor plate being disposed adjacent to the first conductor plate, a first heat-dissipating member disposed counter to the first conductor plate and the second conductor plate, and a first insulating sheet member disposed between the first heat-dissipating member and the first conductor plate. The first power semiconductor element is disposed at a position at which a first length from an end of the first conductor plate, the end being closer to the second conductor plate, to the first power semiconductor element is larger than a second length from an end of the first conductor plate, the end being far from the second conductor plate, to the first power semiconductor element, and the second length is larger than the thickness of the first conductor plate.

A semiconductor device is made by calculating a thermal resistance matrix for the semiconductor device. A plurality of maximum junction temperatures for the plurality of die of the semiconductor device is selected. A plurality of power envelope surfaces are calculated for the semiconductor device based on the thermal resistance matrix and the maximum junction temperatures. A plurality of powers is selected for the plurality of die. The plurality of powers are compared against the plurality of power envelope surfaces to determine a plurality of risk values.

In an embodiment, a package is provided. The package includes a semiconductor device; an encapsulant laterally surrounding the semiconductor device; and a heat dissipation structure disposed over the semiconductor device and the encapsulant, wherein the heat dissipation structure includes a plurality of pillars and a porous layer extending over sidewalls of the plurality of pillars.