Electrical connections for chip scale packaging are disclosed. In one embodiment, a semiconductor device includes a post-passivation layer disposed over a substrate, the substrate having a first direction of coefficient of thermal expansion mismatch. The semiconductor device includes a first opening through the post-passivation layer, the first opening comprising a plurality of elongated apertures. A longest of the plurality of elongated apertures comprises a first dimension, wherein the first dimension is aligned substantially perpendicular to the first direction of coefficient of thermal expansion mismatch.

A package structure including a first semiconductor die, a second semiconductor die, first conductive pillars and a first insulating encapsulation is provided. The first semiconductor die includes a semiconductor substrate, an interconnect structure and a first redistribution circuit structure. The semiconductor substrate includes a first portion and a second portion disposed on the first portion. The interconnect structure is disposed on the second portion, the first redistribution circuit structure is disposed on the interconnect structure, and the lateral dimension of the first portion is greater than the lateral dimension of the second portion. The second semiconductor die is disposed on the first semiconductor die. The first conductive pillars are disposed on the first redistribution circuit structure of the first semiconductor die. The first insulating encapsulation is disposed on the first portion. The first insulating encapsulation laterally encapsulates the second semiconductor die, the first conductive pillars and the second portion.

An integrated circuit structure includes a package component, which further includes a non-porous dielectric layer having a first porosity, and a porous dielectric layer over and contacting the non-porous dielectric layer, wherein the porous dielectric layer has a second porosity higher than the first porosity. A bond pad penetrates through the non-porous dielectric layer and the porous dielectric layer. A dielectric barrier layer is overlying, and in contact with, the porous dielectric layer. The bond pad is exposed through the dielectric barrier layer. The dielectric barrier layer has a planar top surface. The bond pad has a planar top surface higher than a bottom surface of the dielectric barrier layer.

Some embodiments include a method of providing an electronic device. The method includes: (i) providing a carrier substrate, (ii) providing a device substrate comprising a first side and a second side opposite the first side, the device substrate having a flexible substrate, (iii) coupling the first side of the device substrate to the carrier substrate; and (iv) after coupling the first side of the device substrate to the carrier substrate, providing two or more active sections over the second side of the device substrate, each active section of the two or more active sections being spatially separate from each other and having at least one semiconductor device. Other embodiments of related methods and devices are also disclosed.

The present disclosure relates to bump structures and a semiconductor device and semiconductor device package having the same. The semiconductor device includes a body, at least one conductive metal pad and at least one metal pillar. The body includes a first surface. The at least one conductive metal pad is disposed on the first surface. Each metal pillar is formed on a corresponding conductive metal pad. Each metal pillar has a concave side wall and a convex side wall opposite the first concave side wall, and the concave side wall and the convex side wall are orthogonal to the corresponding conductive metal pad.

Stacked semiconductor devices and methods of forming the same are provided. Contact pads are formed on a die. A passivation layer is blanket deposited over the contact pads. The passivation layer is subsequently patterned to form first openings, the first openings exposing the contact pads. A buffer layer is blanket deposited over the passivation layer and the contact pads. The buffer layer is subsequently patterned to form second openings, the second opening exposing a first set of the contact pads. First conductive pillars are formed in the second openings. Conductive lines are formed over the buffer layer simultaneously with the first conductive pillars, ends of the conductive lines terminating with the first conductive pillars. An external connector structure is formed over the first conductive pillars and the conductive lines, the first conductive pillars electrically coupling the contact pads to the external connector structure.

A semiconductor package structure is provided. The semiconductor package structure includes a substrate, a first semiconductor die, and a second semiconductor die. The substrate includes a first substrate partition and a second substrate partition. The first substrate partition has a first wiring structure. The second substrate partition is adjacent to the first substrate partition and has a second wiring structure. The first substrate partition and the second substrate partition are surrounded by a first molding material. The first semiconductor die is disposed over the substrate and electrically coupled to the first wiring structure. The second semiconductor die is disposed over the substrate and electrically coupled to the second wiring structure.

A chip part includes a substrate that has an upper surface, a lower surface positioned on an opposite side of the upper surface, and a sidewall by which the upper surface and the lower surface are connected together and that has a plurality of concavo-convex portions formed on the sidewall from a side of the upper surface toward a side of the lower surface, a functional element formed at the side of the upper surface of the substrate, a first external electrode and a second external electrode that are arranged at the upper surface of the substrate so as to be electrically connected to the functional element, and a sidewall insulating film with which the sidewall of the substrate is coated so as to fill the plurality of concavo-convex portions formed on the sidewall of the substrate with the sidewall insulating film.

Device and method for forming a device are presented. A substrate having circuit component and a back-end-of-line (BEOL) dielectric layer with interconnects is provided. A pad dielectric layer is formed over the BEOL dielectric layer. The pad dielectric layer includes a pad via opening which exposes a surface of one of the interconnects in the BEOL dielectric layer. A pad interconnect is formed on the pad dielectric layer and the pad interconnect is coupled to one of the interconnect in the BEOL dielectric by a pad via contact in the pad via opening. The pad interconnect comprises a pad interconnect pattern which is devoid of 90° angles and any angled structures contained in the pad interconnect pattern less than 90°. A passivation layer is formed on the substrate. The passivation layer lines the pad interconnect and covers an exposed surface of the pad dielectric layer.

In accordance with an embodiment, a method for producing a moisture sensor includes providing a substrate arrangement, applying a sensor structure, applying a first cover layer on the sensor structure, locally removing the planar cover layer arrangement to expose portions of an insulation layer, applying a third cover layer on the exposed portions of the insulation layer, exposing the planar cover layer arrangement covering the sensor structure, and applying a moisture-absorbing layer element on the planar cover layer arrangement covering the sensor structure to obtain the moisture sensor.