A semiconductor device is disclosed. The semiconductor device comprises a first die, a second die, and a redistribution structure. The first die and the second die are electrically connected to the redistribution structure. There are no solder bumps between the first die and the redistribution structure. There are no solder bumps between the second die and the redistribution structure. The first die and the second die have a shift with regard to each other from a top view.

Methods of fabricating semiconductor packages are provided. One of the methods includes forming a protection layer including metal on a first surface of a substrate to cover a semiconductor device disposed on the first surface of the substrate, attaching a support substrate to the protection layer by using an adhesive member, processing a second surface of the substrate opposite to the protection layer to remove a part of the substrate, and detaching the support substrate from the substrate.

Methods of fabricating semiconductor packages are provided. One of the methods includes forming a protection layer including metal on a first surface of a substrate to cover a semiconductor device disposed on the first surface of the substrate, attaching a support substrate to the protection layer by using an adhesive member, processing a second surface of the substrate opposite to the protection layer to remove a part of the substrate, and detaching the support substrate from the substrate.

Disclosed herein are compositions for removing silicone resins and methods of thinning a substrate by using the same, as well as related methods, apparatus and systems for facilitating the removal of silicone resins. More particularly, disclosed herein are compositions for removing silicone resins, the compositions including a heterocyclic solvent and an alkyl ammonium fluoride salt represented by a formula, (R).sub.4N.sup.+F.sup., wherein R is a C1 to C4 linear alkyl group. Silicone resins may be effectively removed by using the compositions since the compositions exhibit an excellent decomposition rate with respect to the silicone resins that remain on a semiconductor substrate in a process of backside grinding of the semiconductor substrate, backside electrode formation, or the like.

Disclosed herein are compositions for removing silicone resins and methods of thinning a substrate by using the same, as well as related methods, apparatus and systems for facilitating the removal of silicone resins. More particularly, disclosed herein are compositions for removing silicone resins, the compositions including a heterocyclic solvent and an alkyl ammonium fluoride salt represented by a formula, (R).sub.4N.sup.+F.sup., wherein R is a C1 to C4 linear alkyl group. Silicone resins may be effectively removed by using the compositions since the compositions exhibit an excellent decomposition rate with respect to the silicone resins that remain on a semiconductor substrate in a process of backside grinding of the semiconductor substrate, backside electrode formation, or the like.

A semiconductor device is disclosed. The semiconductor device comprises a first die, a second die, and a redistribution structure. The first die and the second die are electrically connected to the redistribution structure. There are no solder bumps between the first die and the redistribution structure. There are no solder bumps between the second die and the redistribution structure. The first die and the second die have a shift with regard to each other from a top view.

A semiconductor device is disclosed. The semiconductor device comprises a first die, a second die, and a redistribution structure. The first die and the second die are electrically connected to the redistribution structure. There are no solder bumps between the first die and the redistribution structure. There are no solder bumps between the second die and the redistribution structure. The first die and the second die have a shift with regard to each other from a top view.

Methods of fabricating semiconductor packages are provided. One of the methods includes forming a protection layer including metal on a first surface of a substrate to cover a semiconductor device disposed on the first surface of the substrate, attaching a support substrate to the protection layer by using an adhesive member, processing a second surface of the substrate opposite to the protection layer to remove a part of the substrate, and detaching the support substrate from the substrate.

Methods of fabricating semiconductor packages are provided. One of the methods includes forming a protection layer including metal on a first surface of a substrate to cover a semiconductor device disposed on the first surface of the substrate, attaching a support substrate to the protection layer by using an adhesive member, processing a second surface of the substrate opposite to the protection layer to remove a part of the substrate, and detaching the support substrate from the substrate.

Provided are a semiconductor chip and a semiconductor package capable of obtaining stability and reliability through a connection structure using a through-silicon-via (TSV). The semiconductor chip includes a semiconductor substrate and a through-silicon-via (TSV) structure penetrating through the semiconductor substrate. A connection pad includes a foundation base disposed on a lower surface of the semiconductor substrate and connected to the TSV structure. A protruding portion protrudes from the foundation base and extend to an inside of a first groove formed in a lower surface of the semiconductor substrate.