A semiconductor device, including a cooling body, a semiconductor unit including a wiring portion electrically connected to a semiconductor chip, and a sealing member sealing the entire semiconductor unit over a cooling surface of the cooling body. The sealing member includes a first portion and a second portion which surrounds the first portion in a plan view. The first portion seals a central portion of a main electrode of the semiconductor chip, and has a first sealing surface opposite the cooling surface of the cooling body. The second portion seals a wiring portion to thereby surround the first portion in the plan view, and has a second sealing surface opposite the cooling surface. A distance in a thickness direction of the semiconductor device from the cooling surface to the first sealing surface, is smaller than a distance in the thickness direction from the cooling surface to the second sealing surface.

A semiconductor device, including a cooling body, a semiconductor unit including a wiring portion electrically connected to a semiconductor chip, and a sealing member sealing the entire semiconductor unit over a cooling surface of the cooling body. The sealing member includes a first portion and a second portion which surrounds the first portion in a plan view. The first portion seals a central portion of a main electrode of the semiconductor chip, and has a first sealing surface opposite the cooling surface of the cooling body. The second portion seals a wiring portion to thereby surround the first portion in the plan view, and has a second sealing surface opposite the cooling surface. A distance in a thickness direction of the semiconductor device from the cooling surface to the first sealing surface, is smaller than a distance in the thickness direction from the cooling surface to the second sealing surface.

A semiconductor device has a first semiconductor package, second semiconductor package, and RDL. The first semiconductor package is disposed over a first surface of the RDL and the second semiconductor package is disposed over a second surface of the RDL opposite the first surface of the RDL. A carrier is initially disposed over the second surface of the RDL and removed after disposing the first semiconductor package over the first surface of the RDL. The first semiconductor package has a substrate, plurality of conductive pillars formed over the substrate, electrical component disposed over the substrate, and encapsulant deposited around the conductive pillars and electrical component. A shielding frame can be disposed around the electrical component. An antenna can be disposed over the first semiconductor package. A portion of the encapsulant is removed to planarize a surface of the encapsulant and expose the conductive pillars.

A semiconductor structure includes a first semiconductor device, a second semiconductor device, a connection device and a redistribution circuit structure. The first semiconductor device is bonded on the second semiconductor device. The connection device is bonded on the second semiconductor device and arranged aside of the first semiconductor device, wherein the connection device includes a first substrate and conductive vias penetrating through the first substrate and electrically connected to the second semiconductor device. The redistribution circuit structure is located over the second semiconductor device, wherein the first semiconductor device and the connection device are located between the redistribution circuit structure and the second semiconductor device. The redistribution circuit structure and the first semiconductor device are electrically connected to the second semiconductor device through the conductive vias of the connection device.

A semiconductor device includes a substrate. A semiconductor die is disposed over the substrate. An encapsulant is deposited over the substrate and semiconductor die. A first trench is formed in the encapsulant over the semiconductor die. A conductive layer is formed over the encapsulant and into the first trench.

An electronic device and a method of manufacturing an electronic device are provided. The electronic device includes a first conductive layer and a first power die. The first conductive layer including a first part and a second part separated from the first part. The first power die is disposed above the first conductive layer and has a first surface. The first power die includes a first terminal exposed from the first surface and a second terminal exposed from the first surface. The first part is electrically connected to the first terminal and the second part is electrically connected to the second terminal.

A semiconductor arrangement includes first and second semiconductor packages separate from one another. Each semiconductor package includes a die carrier having opposite first and second main faces, a transistor die disposed on the first main face, a first lead connected to a first load electrode of the transistor die, a second lead connected to a gate electrode of the transistor die, and an encapsulant embedding at least part of the first main face of the die carrier, inner portions of the leads and the transistor die. The first lead of the first semiconductor package is electrically connected to the first lead of the second semiconductor package, forming a source-source connection. The second lead of the first semiconductor package and the second lead of the second semiconductor package are arranged between the first semiconductor package and the second semiconductor package.

Methods, systems, and devices for polymer material gap-fill for hybrid bonding in a stacked semiconductor system are described. A stacked semiconductor may include a first semiconductor die on a semiconductor wafer. A polymer material may be on the semiconductor wafer and may at least partially surround the first semiconductor die. A silicon nitride material may be on the first semiconductor die and on the polymer material. And a second semiconductor die may be hybrid bonded with a bonding material on the silicon nitride material.

A resin composition includes a compound having an oxazoline group, a phenol type curing agent, and an inorganic filler.

A power semiconductor module arrangement comprises a substrate comprising a dielectric insulation layer, and a first metallization layer attached to the dielectric insulation layer, at least one semiconductor body mounted on the first metallization layer, and a first layer comprising an encapsulant, the first layer being arranged on the substrate and covering the first metallization layer the at least one semiconductor body, wherein the first layer is configured to release liquid or oil at temperatures exceeding a defined threshold temperature.