In examples, a semiconductor package comprises a wafer chip scale package (WCSP) having circuitry formed in a device side and an insulative layer above the device side. The WCSP includes one or more plated walls extending vertically to form a defined space, the one or more plated walls configured to prevent mold compound from flowing into the defined space. The WCSP includes mold compound abutting surfaces of the one or more plated walls opposing the defined space. The WCSP includes a conductive terminal coupled to the circuitry and extending from the WCSP into the defined space.

In examples, a wafer chip scale package (WCSP) comprises a semiconductor die including a device side having circuitry formed therein. The WCSP includes a redistribution layer (RDL) including an insulation layer abutting the device side and a metal trace coupled to the device side and abutting the insulation layer. The WCSP includes a conductive member coupled to the metal trace, the conductive member in a first vertical plane that is positioned no farther than a quarter of a horizontal width of the semiconductor die from a vertical axis extending through a center of the semiconductor die. The WCSP includes a lead coupled to the conductive member and extending horizontally past a second vertical plane defined by a perimeter of the semiconductor die.

In some examples, a semiconductor package includes a semiconductor die having a device side and a non-device side opposing the device side. The device side has a circuit formed therein. The package includes a first conductive member having a first surface coupled to the non-device side of the semiconductor die and a second surface opposing the first surface. The second surface is exposed to a top surface of the semiconductor package. The package includes a second conductive member exposed to an exterior of the semiconductor package and coupled to the device side of the semiconductor die. The package includes a plurality of wirebonded members coupled to the second surface of the first conductive member and exposed to the exterior of the semiconductor package. At least one of the wirebonded members in the plurality of wirebonded members has a gauge of at least 5 mils.

In some examples, a semiconductor package comprises a semiconductor die; a conductive member coupled to the semiconductor die; and a wirebonded protrusion coupled to the conductive member. A physical structure of the wirebonded protrusion is determined at least in part by a sequence of movements of a wirebonding capillary used to form the wirebonded protrusion, the wirebonded protrusion including a ball bond and a bond wire, and the bond wire having a proximal end coupled to the ball bond. The bond wire has a distal end. The package also comprises a mold compound covering the semiconductor die, the conductive member, and the wirebonded protrusion. The distal end is in a common vertical plane with the ball bond and is not connected to a structure other than the mold compound.

A method for forming a through-substrate via structure includes providing a substrate and providing a conductive via structure adjacent to a first surface of the substrate. The method includes providing a recessed region on an opposite surface of the substrate towards the conductive via structure. The method includes providing an insulator in the recessed region and providing a conductive region extending along a first sidewall surface of the recessed region in the cross-sectional view. In some examples, the first conductive region is provided to be coupled to the conductive via structure and to be further along at least a portion of the opposite surface of the substrate outside of the recessed region. The method includes providing a protective structure within the recessed region over a first portion of the first conductive region but not over a second portion of the first conductive region that is outside of the recessed region. The method includes attaching a conductive bump to the second portion of the first conductive region.

An integrated fan-out package includes a die, an encapsulant, a seed layer, a conductive pillar, a redistribution structure, and a buffer layer. The encapsulant encapsulates the die. The seed layer and the conductive pillar are sequentially stacked over the die and the encapsulant. The redistribution structure is over the die and the encapsulant. The redistribution structure includes a conductive pattern and a dielectric layer. The conductive pattern is directly in contact with the seed layer and the dielectric layer covers the conductive pattern and surrounds the seed layer and the conductive pillar. The buffer layer is disposed over the redistribution structure. The seed layer is separate from the dielectric layer by the buffer layer, and a Young's modulus of the buffer layer is higher than a Young's modulus of the dielectric layer of the redistribution structure.

A semiconductor device includes a standardized carrier. A semiconductor wafer includes a plurality of semiconductor die and a base semiconductor material. The semiconductor wafer is singulated through a first portion of the base semiconductor material to separate the semiconductor die. The semiconductor die are disposed over the standardized carrier. A size of the standardized carrier is independent from a size of the semiconductor die. An encapsulant is deposited over the standardized carrier and around the semiconductor die. An interconnect structure is formed over the semiconductor die while leaving the encapsulant devoid of the interconnect structure. The semiconductor device is singulated through the encapsulant. Encapsulant remains disposed on a side of the semiconductor die. Alternatively, the semiconductor device is singulated through a second portion of the base semiconductor and through the encapsulant to remove the second portion of the base semiconductor and encapsulant from the side of the semiconductor die.

A semiconductor device includes a semiconductor die and an encapsulant deposited over and around the semiconductor die. A semiconductor wafer includes a plurality of semiconductor die and a base semiconductor material. A groove is formed in the base semiconductor material. The semiconductor wafer is singulated through the groove to separate the semiconductor die. The semiconductor die are disposed over a carrier with a distance of 500 micrometers (μm) or less between semiconductor die. The encapsulant covers a sidewall of the semiconductor die. A fan-in interconnect structure is formed over the semiconductor die while the encapsulant remains devoid of the fan-in interconnect structure. A portion of the encapsulant is removed from a non-active surface of the semiconductor die. The device is singulated through the encapsulant while leaving encapsulant disposed covering a sidewall of the semiconductor die. The encapsulant covering the sidewall includes a thickness of 50 μm or less.

A semiconductor package comprises a semiconductor substrate, a first metal layer, an adhesive layer, a second metal layer, a rigid supporting layer, and a plurality of contact pads. A thickness of the semiconductor substrate is equal to or less than 50 microns. A thickness of the rigid supporting layer is larger than the thickness of the semiconductor substrate. A thickness of the second metal layer is larger than a thickness of the first metal layer. A method comprises the steps of providing a device wafer; providing a supporting wafer; attaching the supporting wafer to the device wafer via an adhesive layer; and applying a singulation process so as to form a plurality of semiconductor packages.

A semiconductor package includes a first integrated circuit structure, a first encapsulation material laterally encapsulating the first integrated circuit structure, a first redistribution structure, a solder layer, a second integrated circuit structure, a second encapsulation material second laterally encapsulating the second integrated circuit structure and a second redistribution structure. The first integrated circuit structure includes a first metallization layer. The first redistribution structure is disposed over the first integrated circuit structure and first encapsulation material. The first metallization layer faces away from the first redistribution structure and thermally coupled to the first redistribution structure. The solder layer is dispose over the first redistribution structure. The second integrated circuit structure is disposed on the first redistribution structure and includes a second metallization layer in contact with the solder layer. The second redistribution structure is disposed over the second integrated circuit structure and the second encapsulation material.