Alignment of a first micro-electronic component to a receiving surface of a second micro-electronic component is realized by a capillary force-induced self-alignment, combined with an electrostatic alignment. The latter is accomplished by providing at least one first electrical conductor line along the periphery of the first component, and at least one second electrical conductor along the periphery of the location on the receiving surface of the second component onto which the component is to be placed. The contact areas surrounded by the conductor lines are covered with a wetting layer. The electrical conductor lines may be embedded in a strip of anti-wetting material that runs along the peripheries to create a wettability contrast. The wettability contrast helps to maintain a drop of alignment liquid between the contact areas so as to obtain self-alignment by capillary force. By applying appropriate charges on the conductor lines, electrostatic self-alignment is realized, which improves the alignment obtained through capillary force and maintains the alignment during evaporation of the liquid.

Alignment of a first micro-electronic component to a receiving surface of a second micro-electronic component is realized by a capillary force-induced self-alignment, combined with an electrostatic alignment. The latter is accomplished by providing at least one first electrical conductor line along the periphery of the first component, and at least one second electrical conductor along the periphery of the location on the receiving surface of the second component onto which the component is to be placed. The contact areas surrounded by the conductor lines are covered with a wetting layer. The electrical conductor lines may be embedded in a strip of anti-wetting material that runs along the peripheries to create a wettability contrast. The wettability contrast helps to maintain a drop of alignment liquid between the contact areas so as to obtain self-alignment by capillary force. By applying appropriate charges on the conductor lines, electrostatic self-alignment is realized, which improves the alignment obtained through capillary force and maintains the alignment during evaporation of the liquid.

Packaging devices and methods of manufacture thereof for semiconductor devices are disclosed. In some embodiments, a packaging device includes a contact pad disposed over a substrate, and a passivation layer disposed over the substrate and a first portion of the contact pad. A post passivation interconnect (PPI) line is disposed over the passivation layer and is coupled to a second portion of the contact pad. A PPI pad is disposed over the passivation layer. A transition element is disposed over the passivation layer and is coupled between the PPI line and the PPI pad. The transition element comprises a first side and a second side coupled to the first side. The first side and the second side of the transition element are non-tangential to the PPI pad.

Alignment of a first micro-electronic component to a receiving surface of a second micro-electronic component is realized by a capillary force-induced self-alignment, combined with an electrostatic alignment. The latter is accomplished by providing at least one first electrical conductor line along the periphery of the first component, and at least one second electrical conductor along the periphery of the location on the receiving surface of the second component onto which the component is to be placed. The contact areas surrounded by the conductor lines are covered with a wetting layer. The electrical conductor lines may be embedded in a strip of anti-wetting material that runs along the peripheries to create a wettability contrast. The wettability contrast helps to maintain a drop of alignment liquid between the contact areas so as to obtain self-alignment by capillary force. By applying appropriate charges on the conductor lines, electrostatic self-alignment is realized, which improves the alignment obtained through capillary force and maintains the alignment during evaporation of the liquid.

Alignment of a first micro-electronic component to a receiving surface of a second micro-electronic component is realized by a capillary force-induced self-alignment, combined with an electrostatic alignment. The latter is accomplished by providing at least one first electrical conductor line along the periphery of the first component, and at least one second electrical conductor along the periphery of the location on the receiving surface of the second component onto which the component is to be placed. The contact areas surrounded by the conductor lines are covered with a wetting layer. The electrical conductor lines may be embedded in a strip of anti-wetting material that runs along the peripheries to create a wettability contrast. The wettability contrast helps to maintain a drop of alignment liquid between the contact areas so as to obtain self-alignment by capillary force. By applying appropriate charges on the conductor lines, electrostatic self-alignment is realized, which improves the alignment obtained through capillary force and maintains the alignment during evaporation of the liquid.

A Wafer-level chip scale package (WLCSP) includes a semiconductor structure and a first bonding pad formed over a portion of the semiconductor structure. The WLCSP further includes a passivation layer formed over the semiconductor structure and the first bonding pad, exposing portions of the first bonding pad. The WLCSP further includes a conductive redistribution layer formed over the passivation layer and the portions of the first bonding pad exposed by the passivation layer. The WLCSP further includes a planarization layer formed over the passivation layer and the conductive redistribution layer, exposing a portion of the conductive redistribution layer. The WLCSP further includes an under-bump-metallurgy (UBM) layer formed over the planarization layer and a conductive bump formed over the UBM layer.

A package structure is provided, including a substrate, a first passivation layer, a metallization layer, a second passivation layer, and a polymer layer. The first passivation layer is formed over the substrate. The metallization layer is conformally formed on the first passivation layer. The second passivation layer is conformally formed on the first passivation layer and the metallization layer. A step structure is formed on the top surface of the second passivation layer, and includes at least one lower part that is lower than the other parts of the step structure. The polymer layer is formed over the second passivation layer. A portion of the polymer layer extends into the lower part of the step structure to engage with the step structure.

A chip package includes a substrate, an isolation layer, a redistribution layer, a passivation layer, a first conductive layer, a second conductive layer, and a conductive structure. The isolation layer is located on the substrate. The redistribution layer is located on the isolation layer. The passivation layer is located on the isolation layer and the redistribution layer. The passivation layer has an opening, a wall surface that surrounds the opening, and a surface that faces away from the isolation layer. A portion of the redistribution layer is exposed through the opening. The first conductive layer is located on the redistribution layer that is in the opening, and extends to the wall surface and the surface of the passivation layer. The second conductive layer covers the first conductive layer. The conductive structure is located on the second conductive layer and protrudes from the passivation layer.

Packaging devices and methods of manufacture thereof for semiconductor devices are disclosed. In some embodiments, a packaging device includes a contact pad disposed over a substrate, and a passivation layer disposed over the substrate and a first portion of the contact pad. A post passivation interconnect (PPI) line is disposed over the passivation layer and is coupled to a second portion of the contact pad. A PPI pad is disposed over the passivation layer. A transition element is disposed over the passivation layer and is coupled between the PPI line and the PPI pad. The transition element comprises a first side and a second side coupled to the first side. The first side and the second side of the transition element are non-tangential to the PPI pad.

Packaging devices and methods of manufacture thereof for semiconductor devices are disclosed. In some embodiments, a packaging device includes a contact pad disposed over a substrate, and a passivation layer disposed over the substrate and a first portion of the contact pad. A second portion of the contact pad is exposed. A post passivation interconnect (PPI) line is disposed over the passivation layer and is coupled to the second portion of the contact pad. A PPI pad is disposed over the passivation layer. A transition element is disposed over the passivation layer and is coupled between the PPI line and the PPI pad. The transition element includes a hollow region.