Abstract: A semiconductor manufacturing method includes providing a carrier; forming a first photoresist layer; forming plural core portions; removing the first photoresist layer; forming a second photoresist layer; forming a plurality of connection portions, each of the plurality of connection portions includes a first connection layer and a second connection layer and connects to each of the core portions to form a hybrid bump, wherein each of the first connection layers comprises a base portion, a projecting portion and an accommodating space, each base portion comprises an upper surface, each projecting portion is protruded to the upper surface and located on top of each core portion, each accommodating space is located outside each projecting portion, the second connection layers cover the projecting portions and the upper surfaces, and the accommodating spaces are filled by the second connection layers; removing the second photoresist layer to reveal the hybrid bumps.

Abstract: A semiconductor structure includes a carrier, a first protective layer, a second protective layer, and a third protective layer. A first surface of the first protective layer comprises a first anti-stress zone. A first extension line from a first bottom edge intersects with a second extension line from a second bottom edge to form a first base point. A first projection line is formed on the first surface, an extension line of the first projection line intersects with the second bottom edge to form a first intersection point, a second projection line is formed on the first surface, and an extension line of the second projection line intersects with the first bottom edge to form a second intersection point. A zone by connecting the first base point, the first intersection point and the second intersection point is the first anti-stress zone.

Abstract: A semiconductor structure includes a carrier, a first protective layer, a second protective layer, and a third protective layer. A first surface of the first protective layer comprises a first anti-stress zone. The second protective layer reveals the first anti-stress zone and comprises a second surface, a first lateral side, a second lateral side and a first connection side. The second surface comprises a second anti-stress zone. An extension line of the first lateral side intersects with an extension line of the second lateral side to form a first intersection point. A zone formed by connecting the first intersection point and two points of the first connection side is the first anti-stress zone. The third protective layer reveals the second anti-stress zone and comprises a second connection side projected on the first surface to form a projection line parallel to the first connection side.

Abstract: A semiconductor structure includes a carrier, a first protective layer, a second protective layer, and a third protective layer. A first surface of the first protective layer comprises a first anti-stress zone. The second protective layer reveals the first anti-stress zone and comprises a second surface, a first lateral side, a second lateral side and a first connection side. The second surface comprises a second anti-stress zone. An extension line of the first lateral side intersects with an extension line of the second lateral side to form a first intersection point. A zone formed by connecting the first intersection point and two points of the first connection side is the first anti-stress zone. The third protective layer reveals the second anti-stress zone and comprises a second connection side projected on the first surface to form a projection line parallel to the first connection side.

Abstract: A semiconductor structure includes a carrier, a first protective layer, a second protective layer, and a third protective layer. A first surface of the first protective layer comprises a first anti-stress zone. A first extension line from a first bottom edge intersects with a second extension line from a second bottom edge to form a first base point. A first projection line is formed on the first surface, an extension line of the first projection line intersects with the second bottom edge to form a first intersection point, a second projection line is formed on the first surface, and an extension line of the second projection line intersects with the first bottom edge to form a second intersection point. A zone by connecting the first base point, the first intersection point and the second intersection point is the first anti-stress zone.

Abstract: A bumping process comprises steps of forming a metal layer with copper on a substrate, and the metal layer with copper comprises a plurality of first zones and second zones; forming a photoresist layer on the metal layer with copper; patterning the photoresist layer to form a plurality of openings; forming a plurality of copper bumps within the openings, each of the copper bumps covers the first zones and comprises a first top surface; forming a connection layer on the first top surface; removing the photoresist layer; removing the second zones and enabling each of the first zones to form an under bump metallurgy layer, wherein the under bump metallurgy layer, the copper bump, and the connection layer possess their corresponded peripheral walls, and covering sections of a first protective layer formed on the connection layer may cover those peripheral walls to prevent ionization phenomenon.

Abstract: A semiconductor manufacturing method includes providing a carrier; forming a first photoresist layer; forming plural core portions; removing the first photoresist layer; forming a second photoresist layer; forming a plurality of connection portions, each of the plurality of connection portions includes a first connection layer and a second connection layer and connects to each of the core portions to form a hybrid bump, wherein each of the first connection layers comprises a base portion, a projecting portion and an accommodating space, each base portion comprises an upper surface, each projecting portion is protruded to the upper surface and located on top of each core portion, each accommodating space is located outside each projecting portion, the second connection layers cover the projecting portions and the upper surfaces, and the accommodating spaces are filled by the second connection layers; removing the second photoresist layer to reveal the hybrid bumps.

Abstract: A semiconductor structure having a first corner includes a carrier, a first protective layer, a second protective layer, and a third protective layer. The carrier comprises a carrier surface having a protection-layered disposing zone. The first protective layer comprises a first surface having a first disposing zone, a first anti-stress zone and a first exposing zone, the first anti-stress zone is located at a corner of the first disposing zone, the second protective layer is disposed at the first disposing zone. The second protective layer comprises a second surface having a second disposing zone, a second anti-stress zone and a second exposing zone, the second anti-stress zone is located at a corner of the second disposing zone. The first anti-stress zone and the second anti-stress zone are located at the first corner. An area of the first anti-stress zone is not smaller than that of the second anti-stress zone.

Abstract: A semiconductor manufacturing method includes providing a carrier; forming a first photoresist layer; forming plural core portions; removing the first photoresist layer; forming a second photoresist layer; forming a plurality of connection portions, each of the plurality of connection portions includes a first connection layer and a second connection layer and connects to each of the core portions to form a hybrid bump, wherein each of the first connection layers comprises a base portion, a projecting portion and an accommodating space, each base portion comprises an upper surface, each projecting portion is protruded to the upper surface and located on top of each core portion, each accommodating space is located outside each projecting portion, the second connection layers cover the projecting portions and the upper surfaces, and the accommodating spaces are filled by the second connection layers; removing the second photoresist layer to reveal the hybrid bumps.

Abstract: A semiconductor package includes a lead frame, at least one chip and a molding compound. The lead frame comprises a plurality of leads, each lead comprises a first end portion and at least one coupling protrusion, wherein the first end portion comprises a first upper surface, the coupling protrusion comprises a ring surface and is integrally formed as one piece with the first upper surface. The chip disposed on top of the leads comprises a plurality of bumps and a plurality of solders, the coupling protrusions embed into the solders to make the ring surfaces of the coupling protrusions cladded with the solders. The solders cover the first upper surfaces. The chip and the leads are cladded with the molding compound.

Abstract: A semiconductor package structure includes a first substrate, a second substrate and an encapsulant. The first substrate comprises a plurality of first bumps and a plurality of first solder layers. Each of the first solder layers is formed on each of the first bumps and comprises a cone-shaped slot having an inner surface. The second substrate comprises a plurality of second bumps and a plurality of second solder layers. Each of the second solder layers is formed on each of the second bumps and comprises an outer surface. Each of the second solder layers is a cone-shaped body. The second solder layer couples to the first solder layer and is accommodated within the first solder layer. The inner surface of the cone-shaped slot contacts with the outer surface of the second solder layer. The encapsulant is formed between the first substrate and the second substrate.

Abstract: A semiconductor package structure includes a first substrate, a second substrate and an encapsulant. The first substrate comprises a plurality of first bumps and a plurality of first solder layers. Each of the first solder layers is formed on each of the first bumps and comprises a cone-shaped slot having an inner surface. The second substrate comprises a plurality of second bumps and a plurality of second solder layers. Each of the second solder layers is formed on each of the second bumps and comprises an outer surface. Each of the second solder layers is a cone-shaped body. The second solder layer couples to the first solder layer and is accommodated within the first solder layer. The inner surface of the cone-shaped slot contacts with the outer surface of the second solder layer. The encapsulant is formed between the first substrate and the second substrate.

Abstract: A semiconductor manufacturing method includes providing a carrier; forming a first photoresist layer; forming plural core portions; removing the first photoresist layer; forming a second photoresist layer; forming a plurality of connection portions, each of the plurality of connection portions includes a first connection layer and a second connection layer and connects to each of the core portions to form a hybrid bump, wherein each of the first connection layers comprises a base portion, a projecting portion and an accommodating space, each base portion comprises an upper surface, each projecting portion is protruded to the upper surface and located on top of each core portion, each accommodating space is located outside each projecting portion, the second connection layers cover the projecting portions and the upper surfaces, and the accommodating spaces are filled by the second connection layers; removing the second photoresist layer to reveal the hybrid bumps.

Abstract: A semiconductor package structure includes a first substrate, a second substrate and an encapsulant. The first substrate comprises a plurality of first bumps and a plurality of first solder layers. Each of the first solder layers is formed on each of the first bumps and comprises a cone-shaped slot having an inner surface. The second substrate comprises a plurality of second bumps and a plurality of second solder layers. Each of the second solder layers is formed on each of the second bumps and comprises an outer surface. Each of the second solder layers is a cone-shaped body. The second solder layer couples to the first solder layer and is accommodated within the first solder layer. The inner surface of the cone-shaped slot contacts with the outer surface of the second solder layer. The encapsulant is formed between the first substrate and the second substrate.

Abstract: A semiconductor package includes a lead frame, at least one chip and a molding compound. The lead frame comprises a plurality of leads, each lead comprises a first end portion and at least one coupling protrusion, wherein the first end portion comprises a first upper surface, the coupling protrusion comprises a ring surface and is integrally formed as one piece with the first upper surface. The chip disposed on top of the leads comprises a plurality of bumps and a plurality of solders, the coupling protrusions embed into the solders to make the ring surfaces of the coupling protrusions cladded with the solders. The solders cover the first upper surfaces. The chip and the leads are cladded with the molding compound.

Abstract: A semiconductor package structure comprises a lead frame, at least one chip, a molding compound and an anti-conduction film. The lead frame comprises a plurality of leads, each of the leads comprises a first end portion and a second end portion, wherein the first end portion comprises a first upper surface and a first lower surface, and the second end portion comprises a second upper surface and a second lower surface. The chip comprises a plurality of bumps electrically connected with the lead frame. The chip and the leads are covered with the molding compound. The first lower surface of each of the first end portions and the second lower surface of each of the second end portions are exposed by the molding compound. The first lower surface of the first end portion of each of the leads is covered with the anti-conduction film.

Abstract: A semiconductor package structure comprises a lead frame, at least one chip, a molding compound and an anti-conduction film. The lead frame comprises a plurality of leads, each of the leads comprises a first end portion and a second end portion, wherein the first end portion comprises a first upper surface and a first lower surface, and the second end portion comprises a second upper surface and a second lower surface. The chip comprises a plurality of bumps electrically connected with the lead frame. The chip and the leads are covered with the molding compound. The first lower surface of each of the first end portions and the second lower surface of each of the second end portions are exposed by the molding compound. The first lower surface of the first end portion of each of the leads is covered with the anti-conduction film.

Abstract: A thin flip chip package structure comprises a substrate, a chip and a heat dissipation paste, the substrate comprises an insulating layer and a trace layer. The insulating layer comprises a top surface, a bottom surface and a plurality of apertures formed at the bottom surface, wherein the bottom surface of the insulating layer comprises a disposing area and a non-disposing area. Each of the apertures is located at the disposing area and comprises a lateral wall and a base surface. A first thickness is formed between the base surface and the insulating layer, a second thickness is formed between the top surface and the bottom surface, and the second thickness is larger than the first thickness. The chip disposed on the top surface comprises a chip surface and a plurality of bumps. The heat dissipation paste at least fills the apertures and contacts the base surface.

Abstract: A substrate structure with compliant bump comprises a substrate, a plurality of bumps, and a metallic layer, wherein the substrate comprises a surface, a trace layer, and a protective layer. The trace layer comprises a plurality of conductive pads, and each of the conductive pads comprises an upper surface. The protective layer comprises a plurality of openings. The bumps are formed on the surface, and each of the bumps comprises a top surface, an inner surface and an outer surface and defines a first body and a second body. The first body is located on the surface. The second body is located on top of the first body. The metallic layer is formed on the top surface, the inner surface, and the upper surface.

Abstract: A thin flip chip package structure comprises a substrate, a chip and a heat dissipation paste, wherein the substrate comprises an insulating layer and a trace layer. The insulating layer comprises a first insulating portion and a second insulating portion, the first insulating portion comprises a first upward surface, a first downward surface, a first thickness and a recess formed on the first downward surface, wherein the recess comprises a bottom surface. The second insulating portion comprises a second upward surface, a second downward surface and a second thickness larger than the first thickness. The trace layer is at least formed on the second insulating portion, the chip disposed on top of the substrate is electrically connected with the trace layer and comprises a plurality of bumps, and the heat dissipation paste is disposed at the recess.