A memory device including a base chip and a memory cube mounted on and connected with the base chip is described. The memory cube includes multiple stacked tiers, and each tier of the multiple stacked tiers includes semiconductor chips laterally wrapped by an encapsulant and a redistribution structure. The semiconductor chips of the multiple stacked tiers are electrically connected with the base chip through the redistribution structures in the multiple stacked tiers. The memory cube includes a thermal path structure extending through the multiple stacked tiers and connected to the base chip. The thermal path structure has a thermal conductivity larger than that of the encapsulant. The thermal path structure is electrically isolated from the semiconductor chips in the multiple stacked tiers and the base chip.

A semiconductor device with high heat dissipation efficiency includes a base structure, a semiconductor chip, a heat dissipating structure, and a package body. The semiconductor chip is disposed on the base structure and has a first surface distant from the base structure. The heat dissipating structure includes a buffer layer and a first heat spreader. The buffer layer is disposed on the first surface of the semiconductor chip and a coverage rate thereof on the first surface is at least 10%. The first heat spreader is disposed on the buffer layer and bonded to the first surface of the semiconductor chip through the buffer layer. The package body encloses the semiconductor chip and the heat dissipating structure, and the package body and the buffer layer have the same heat curing temperature.

A method for forming a semiconductor device package is provided. The method includes bonding a semiconductor device to a package substrate; placing a metal lid over the semiconductor device and the package substrate with a metal thermal interface material (TIM) provided between the metal lid and the semiconductor device; heating the metal TIM to melt the metal TIM; pressing the metal lid downward so that the molten metal TIM flows toward the boundary of the semiconductor device, and the outermost point of the lateral sidewall of the molten metal TIM extends beyond the boundary of the semiconductor device; lifting the metal lid upward so that the molten metal TIM flows back, and the outermost point of the lateral sidewall is within the boundary of the semiconductor device; and bonding the metal lid to the semiconductor device through the metal TIM by curing the molten metal TIM.

A radar chip package includes a radar monolithic microwave integrated circuit (MMIC) having a backside, a frontside arranged opposite to the backside, and lateral sides that extend between the backside and the frontside, wherein the radar MIMIC comprises a recess that extends from the backside at least partially towards the frontside; a plurality of electrical interfaces coupled to the frontside of the radar MIMIC; at least one antenna arranged at the frontside of the radar MIMIC; and a lens formed over the recess and the at least one antenna, wherein the lens is coupled to the backside of the radar MMIC.

A semiconductor device includes an integrated circuit, first conductive features, second conductive features, a package structure, and an encapsulant. The integrated circuit has an active surface and a rear surface opposite to the active surface. The first conductive features surround the integrated circuit. The second conductive features are stacked on the first conductive features. The package structure is disposed on the second conductive features and the rear surface of the integrated circuit. The encapsulant laterally encapsulates the integrated circuit, the first conductive features, the second conductive features, and the package structure.

The present disclosure relates to a radio frequency device that includes a device region with a back-end-of-line (BEOL) portion and a front-end-of-line (FEOL) portion, first bump structures, a first mold compound, and a second mold compound. The FEOL portion includes an active layer, a contact layer, and isolation sections. Herein, the active layer and the isolation sections reside over the contact layer, and the active layer is surrounded by the isolation sections. The BEOL portion is formed underneath the FEOL portion, and the first bump structures and the first mold compound are formed underneath the BEOL portion. Each first bump structure is partially encapsulated by the first mold compound, and electrically coupled to the FEOL portion via connecting layers within the BEOL portion. The second mold compound resides over the active layer without a silicon material, which has a resistivity between 5 Ohm-cm and 30000 Ohm-cm, in between.

A mold chase for packaging a compartmentally shielded multifunctional semiconductor is provided. The mold chase generally includes a first cavity and a second cavity separated by a trench plate positioned between a first component and a second component of the multifunctional semiconductor between which a compartmental shield is required. The mold chase is lowered into a molding position over the multifunctional semiconductor and a molding material is injected through an inlet sprue into the first and second cavities to surround the first and second components, respectively. After the molding material is cured, the mold chase is removed and an open trench is formed in the cured molding material by the trench plate. The open trench is filled with a conductive material to form the compartmental shield. A conformal shield may be added to cover the package.

A semiconductor package includes a first die; a first redistribution structure over the first die, the first redistribution structure being conterminous with the first die; a second die over the first die, a first portion of the first die extending beyond a lateral extent of the second die; a conductive pillar over the first portion of the first die and laterally adjacent to the second die, the conductive pillar electrically coupled to first die; a molding material around the first die, the second die, and the conductive pillar; and a second redistribution structure over the molding material, the second redistribution structure electrically coupled to the conductive pillar and the second die.

Disclosed is a semiconductor package comprising a first semiconductor chip, a second semiconductor chip on a first surface of the first semiconductor chip, and a plurality of conductive pillars on the first surface of the first semiconductor chip and adjacent to at least one side of the second semiconductor chip. The first semiconductor chip includes a first circuit layer adjacent to the first surface of the first semiconductor chip. The second semiconductor chip and the plurality of conductive pillars are connected to the first surface of the first semiconductor chip.

Package structures and methods for forming the same are provided. The method includes forming a passivation layer having an opening and forming a first seed layer in the opening. The method further includes filling the opening with a conductive layer over the first seed layer and bonding an integrated circuit die to the conductive layer over a first side of the passivation layer. The method further includes removing a portion of the first seed layer to expose a top surface of the conductive layer and to partially expose a first sidewall of the passivation layer from a second side of the passivation layer and forming a second seed layer over the top surface of the conductive layer and over the first sidewall of the passivation layer.