Abstract: A semiconductor package structure includes a conductive structure, at least one semiconductor element, an encapsulant, a redistribution structure and a plurality of bonding wires. The semiconductor element is disposed on and electrically connected to the conductive structure. The encapsulant is disposed on the conductive structure to cover the semiconductor element. The redistribution structure is disposed on the encapsulant, and includes a redistribution layer. The bonding wires electrically connect the redistribution structure and the conductive structure.

Abstract: A semiconductor package structure includes a conductive structure, at least one semiconductor element, an encapsulant, a redistribution structure and a plurality of bonding wires. The semiconductor element is disposed on and electrically connected to the conductive structure. The encapsulant is disposed on the conductive structure to cover the semiconductor element. The redistribution structure is disposed on the encapsulant, and includes a redistribution layer. The bonding wires electrically connect the redistribution structure and the conductive structure.

Abstract: A semiconductor package structure includes a conductive structure, at least one semiconductor element, an encapsulant, a redistribution structure and a plurality of bonding wires. The semiconductor element is disposed on and electrically connected to the conductive structure. The encapsulant is disposed on the conductive structure to cover the semiconductor element. The redistribution structure is disposed on the encapsulant, and includes a redistribution layer. The bonding wires electrically connect the redistribution structure and the conductive structure.

Abstract: A semiconductor package structure includes a conductive structure, at least one semiconductor element, an encapsulant, a redistribution structure and a plurality of bonding wires. The semiconductor element is disposed on and electrically connected to the conductive structure. The encapsulant is disposed on the conductive structure to cover the semiconductor element. The redistribution structure is disposed on the encapsulant, and includes a redistribution layer. The bonding wires electrically connect the redistribution structure and the conductive structure.

Abstract: A semiconductor package includes a first semiconductor component, a second semiconductor component, and a connecting element. The first semiconductor component includes a first substrate, and a first bonding pad disposed adjacent to a first surface of the first substrate, and at least one conductive via structure extending from a second surface of the first substrate to the first bonding pad. The second semiconductor component includes a second substrate, a redistribution layer disposed adjacent to a first surface of the second substrate, and a second bonding pad disposed on the redistribution layer. The connecting element is disposed between the first bonding pad and the second bonding pad.

Abstract: A semiconductor package includes a first semiconductor device and a second semiconductor device. The first semiconductor device includes a first main body, at least one first columnar portion and at least one first conductive layer. The first columnar portion protrudes from a bottom surface of the first main body. The first conductive layer is disposed on a side surface of the first columnar portion. The second semiconductor device includes a second main body, at least one second columnar portion and at least one second conductive layer. The second columnar portion protrudes from a top surface of the second main body. The second conductive layer is disposed on a side surface of the second columnar portion. The first conductive layer is electrically coupled to the second conductive layer.

Abstract: A semiconductor package includes a first semiconductor device and a second semiconductor device. The first semiconductor device includes a first main body, at least one first columnar portion and at least one first conductive layer. The first columnar portion protrudes from a bottom surface of the first main body. The first conductive layer is disposed on a side surface of the first columnar portion. The second semiconductor device includes a second main body, at least one second columnar portion and at least one second conductive layer. The second columnar portion protrudes from a top surface of the second main body. The second conductive layer is disposed on a side surface of the second columnar portion. The first conductive layer is electrically coupled to the second conductive layer.

Abstract: A semiconductor package includes a first semiconductor component, a second semiconductor component, and a connecting element. The first semiconductor component includes a first substrate, and a first bonding pad disposed adjacent to a first surface of the first substrate, and at least one conductive via structure extending from a second surface of the first substrate to the first bonding pad. The second semiconductor component includes a second substrate, a redistribution layer disposed adjacent to a first surface of the second substrate, and a second bonding pad disposed on the redistribution layer. The connecting element is disposed between the first bonding pad and the second bonding pad.

Abstract: A method for patterning a wafer includes performing a first patterning on a wafer, and after performing the first patterning, calculating a simulated dose mapper (DoMa) map predicting a change in critical dimensions of the wafer due to performing a second patterning on the wafer. The method further includes performing the second patterning on the wafer. Performing the second patterning includes adjusting one or more etching parameters of the second patterning in accordance with differences between the simulated DoMa map and desired critical dimensions of the wafer.

Abstract: A method for patterning a wafer includes performing a first patterning on a wafer, and after performing the first patterning, calculating a simulated dose mapper (DoMa) map predicting a change in critical dimensions of the wafer due to performing a second patterning on the wafer. The method further includes performing the second patterning on the wafer. Performing the second patterning includes adjusting one or more etching parameters of the second patterning in accordance with differences between the simulated DoMa map and desired critical dimensions of the wafer.

Abstract: A method for patterning a wafer includes performing a first patterning on a wafer, and after performing the first patterning, calculating a simulated dose mapper (DoMa) map predicting a change in critical dimensions of the wafer due to performing a second patterning on the wafer. The method further includes performing the second patterning on the wafer. Performing the second patterning includes adjusting one or more etching parameters of the second patterning in accordance with differences between the simulated DoMa map and desired critical dimensions of the wafer.

Abstract: A method for patterning a wafer includes performing a first patterning on a wafer, and after performing the first patterning, calculating a simulated dose mapper (DoMa) map predicting a change in critical dimensions of the wafer due to performing a second patterning on the wafer. The method further includes performing the second patterning on the wafer. Performing the second patterning includes adjusting one or more etching parameters of the second patterning in accordance with differences between the simulated DoMa map and desired critical dimensions of the wafer.

Abstract: The present invention relates to a method for forming a via in a substrate which includes the flowing steps of: (a) providing a substrate having a first surface and a second surface; (b) forming an accommodating groove and a plurality of pillars on the first surface of the substrate, the accommodating groove having a side wall and a bottom wall, the pillars remaining on the bottom wall of the accommodating groove; (c) forming a first insulating material in the accommodating groove and between the pillars; (d) removing the pillars so as to form a plurality of grooves in the first insulating material; and (e) forming a first conductive metal in the grooves. As a result, thicker insulating material can be formed in the via, and the thickness of the insulating material in the via is even.

Abstract: The present invention relates to a semiconductor device with a plurality of mark through substrate vias, including a semiconductor substrate, a plurality of original through substrate vias and a plurality of mark through substrate vias. The original through substrate vias and the mark through substrate vias are disposed in the semiconductor substrate and protrude from the backside surface of the semiconductor substrate. The mark through substrate vias are added at a specific position and/or in a specific pattern and serve as a fiducial mark, which facilitates identifying the position and direction on the backside surface. Thus, the redistribution layer (RBL) or the special equipment for achieving the backside alignment (BSA) is not necessary.

Abstract: The present invention relates to a semiconductor device with a plurality of mark through substrate vias, comprising a semiconductor substrate, a plurality of original through substrate vias and a plurality of mark through substrate vias. The original through substrate vias and the mark through substrate vias are disposed in the semiconductor substrate and protrude from the backside surface of the semiconductor substrate. The mark through substrate vias are added at a specific position and/or in a specific pattern and serve as a fiducial mark, which facilitates identifying to the position and direction on the backside surface. Thus, the redistribution layer (RDL) or the special equipment for achieving the backside alignment (BSA) is not necessary.

Abstract: The present invention relates to a method for forming a via in a substrate which includes the flowing steps of: (a) providing a substrate having a first surface and a second surface; (b) forming an accommodating groove and a plurality of pillars on the first surface of the substrate, the accommodating groove having a side wall and a bottom wall, the pillars remaining on the bottom wall of the accommodating groove; (c) forming a first insulating material in the accommodating groove and between the pillars; (d) removing the pillars so as to form a plurality of grooves in the first insulating material; and (e) forming a first conductive metal in the grooves. As a result, thicker insulating material can be formed in the via, and the thickness of the insulating material in the via is even.

Abstract: A method to enhance resolution of a chemically amplified photoresist generally includes forming a relief image in the chemically amplified photoresist, wherein the relief image comprises a feature having a first dimension; and contacting the relief image with an aqueous acidic solution for a period of time effective to reduce first dimension of the relief image to a second dimension.

Abstract: A method to enhance resolution of a chemically amplified photoresist generally includes forming a relief image in the chemically amplified photoresist, wherein the relief image comprises a feature having a first dimension; and contacting the relief image with an aqueous acidic solution for a period of time effective to reduce first dimension of the relief image to a second dimension.