A semiconductor device and a semiconductor package including the same are provided. The semiconductor device includes a semiconductor element; a protective layer disposed adjacent to the surface of the semiconductor element, the protective layer defining an opening to expose the semiconductor element; a first bump disposed on the semiconductor element; and a second bump disposed onto the surface of the protective layer. The first bump has a larger cross-section surface area than the second bump.

A method of manufacturing a semiconductor package includes forming a plurality of trenches at a first surface of a silicon substrate, forming a conductive pad inside each of the plurality of trenches, forming a redistribution layer on the first surface of the silicon substrate, forming an external connection terminal on a first surface of the redistribution layer, removing the silicon substrate to expose each conductive pad, mounting a semiconductor chip to be connected to the conductive pads, and forming an encapsulant to cover at least one surface of the semiconductor chip.

A method of manufacturing a semiconductor package includes forming a plurality of trenches at a first surface of a silicon substrate, forming a conductive pad inside each of the plurality of trenches, forming a redistribution layer on the first surface of the silicon substrate, forming an external connection terminal on a first surface of the redistribution layer, removing the silicon substrate to expose each conductive pad, mounting a semiconductor chip to be connected to the conductive pads, and forming an encapsulant to cover at least one surface of the semiconductor chip.

An integrated circuit structure that includes a first integrated circuit package and a second integrated circuit package is described. The two packages can be stacked above, for example, a printed circuit board. The top package is inverted, such that a first die of that top package is facing a second die of the bottom package. A cooling arrangement is in a gap between the first and second integrated circuit packages, and is thermally coupled to the first and second die. The cooling arrangement is to transfer heat generated by a first die of the first integrated circuit package and a second die of the second integrated circuit package. In some cases, structures comprising electrically conductive material (e.g., metal) are encapsulated by a molding compound or insulator, and extend between a first substrate of the first integrated circuit package and a second substrate of the second integrated circuit package.

An integrated circuit structure that includes a first integrated circuit package and a second integrated circuit package is described. The two packages can be stacked above, for example, a printed circuit board. The top package is inverted, such that a first die of that top package is facing a second die of the bottom package. A cooling arrangement is in a gap between the first and second integrated circuit packages, and is thermally coupled to the first and second die. The cooling arrangement is to transfer heat generated by a first die of the first integrated circuit package and a second die of the second integrated circuit package. In some cases, structures comprising electrically conductive material (e.g., metal) are encapsulated by a molding compound or insulator, and extend between a first substrate of the first integrated circuit package and a second substrate of the second integrated circuit package.

A display device includes a flexible base layer including a first portion and a second portion disposed around the second portion; a display unit disposed on a first surface of the first portion and including a light emitting element; a driving circuit disposed on a first surface of the second portion and including a driving chip; a support member attached to a second surface of the first portion and a second surface of the second portion; and an adhesive member disposed between the flexible base layer and the support member, wherein the adhesive member includes a first adhesive member having a first elastic modulus and a second adhesive member having a second elastic modulus that is higher than the first elastic modulus, and the second adhesive member overlaps the driving circuit.

A display device includes a flexible base layer including a first portion and a second portion disposed around the second portion; a display unit disposed on a first surface of the first portion and including a light emitting element; a driving circuit disposed on a first surface of the second portion and including a driving chip; a support member attached to a second surface of the first portion and a second surface of the second portion; and an adhesive member disposed between the flexible base layer and the support member, wherein the adhesive member includes a first adhesive member having a first elastic modulus and a second adhesive member having a second elastic modulus that is higher than the first elastic modulus, and the second adhesive member overlaps the driving circuit.

A method for making a semiconductor device includes providing a releasable carrier attached to a conductive layer, patterning a conductive circuit on a surface of the conductive layer, applying an insulative material at least partially covering the conductive circuit, releasing the releasable carrier from the conductive layer, and facilitating the releasing with an activating source. A method of fabricating a releasable carrier includes providing a supporting carrier, attaching a releasable tape to the supporting carrier, providing a first conductive layer and a second conductive layer attached to the first conductive layer, and attaching the first conductive layer to the releasable tape, where the releasable tape is configured to release the supporting carrier from the first conductive layer after being exposed to an activating source.

A method for making a semiconductor device includes providing a releasable carrier attached to a conductive layer, patterning a conductive circuit on a surface of the conductive layer, applying an insulative material at least partially covering the conductive circuit, releasing the releasable carrier from the conductive layer, and facilitating the releasing with an activating source. A method of fabricating a releasable carrier includes providing a supporting carrier, attaching a releasable tape to the supporting carrier, providing a first conductive layer and a second conductive layer attached to the first conductive layer, and attaching the first conductive layer to the releasable tape, where the releasable tape is configured to release the supporting carrier from the first conductive layer after being exposed to an activating source.

Disclosed herein is a releasable carrier that includes a supporting carrier, a carrier conductive layer, and a releasable tape located between the supporting carrier and the carrier conductive layer. The releasable tape attaches the supporting carrier to the carrier conductive layer. The releasable tape is configured to release the supporting carrier from the carrier conductive layer after being exposed to an activating source. The releasable carrier further includes a thin conductive layer attached to the carrier conductive layer, the thin conductive layer creating a surface configured to receive a conductive circuit. Further disclosed is a method for fabricating the releasable carrier and a method for making a semiconductor device using the releasable carrier.