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.

The present technology relates to techniques of preventing intrusion of moisture into a chip. Various illustrative embodiments include image sensors that include: a substrate; a plurality of layers stacked on the substrate; the plurality of layers including a photodiode layer having a plurality of photodiodes formed on a surface of the photodiode layer; the plurality of layers including at least one layer having a groove formed such that a portion of the at least one layer is excavated; and a transparent resin layer formed above the photodiode layer and formed in the groove. The present technology can be applied to, for example, an image sensor.

In one instance, a method of forming a semiconductor package with a leadframe includes cutting, such as with a laser, a first side of a metal strip to a depth D1 according to a cutting pattern to form a first plurality of openings, which may be curvilinear. The method further includes etching the second side of the metal strip to a depth D2 according to a photoresist pattern to form a second plurality of openings. At least some of the first plurality of openings are in fluid communication with at least some of the second plurality of openings to form a plurality of leadframe leads. The depth D1 is shallower than a height H of the metal strip, and the depth D2 is also shallower than the height H. Other embodiments are presented.

In one instance, a method of forming a semiconductor package with a leadframe includes cutting, such as with a laser, a first side of a metal strip to a depth D1 according to a cutting pattern to form a first plurality of openings, which may be curvilinear. The method further includes etching the second side of the metal strip to a depth D2 according to a photoresist pattern to form a second plurality of openings. At least some of the first plurality of openings are in fluid communication with at least some of the second plurality of openings to form a plurality of leadframe leads. The depth D1 is shallower than a height H of the metal strip, and the depth D2 is also shallower than the height H. Other embodiments are presented.

According to various aspects and embodiments, a method for forming a packaged electronic device is provided. In accordance with one embodiment, the method comprises depositing a layer of temporary adhesive material on at least a portion of a surface of a first substrate having a coefficient of thermal expansion, depositing a layer of dielectric material on at least a portion of the layer of temporary adhesive material, forming at least one seal ring on at least a portion of the layer of dielectric material, providing a second substrate having a coefficient of thermal expansion that is substantially the same as the coefficient of thermal expansion of the first substrate, the second substrate having at least one bonding structure attached to a surface of the second substrate, and aligning the at least one seal ring to the at least one bonding structure and bonding the first substrate to the second substrate.

A chip package structure and packaging method are provided. The chip package structure includes a sensing chip, a covering layer located on the first surface of the sensing chip, and a plug structure located in the sensing chip. The sensing chip includes a first surface, a second surface opposite to the first surface, and a sensing area located on the first surface. The second surface of the sensing chip faces to a base plate. One end of the plug structure is electrically connected to the sensing area, and the other end of the plug structure is exposed by the second surface of the sensing chip.

Aspects of the disclosure are directed to integrated circuit dies and their manufacture. In accordance with one or more embodiments, a plurality of integrated circuit dies are provided in a semiconductor wafer, with each integrated circuit die having: an integrated circuit within the die, a via extending from a first surface to a second surface that opposes the first surface, and first and second electrical contacts at the first surface respectively coupled to the via and to the integrated circuit. Lanes are created in a front side of the wafer between the dies, and a portion of the back side of the wafer is removed to expose the lanes. A further contact and/or via is also exposed at the backside, with the via providing an electrical signal path for coupling electrical signals through the integrated circuit die (e.g., bypassing circuitry therein).

Aspects of the disclosure are directed to integrated circuit dies and their manufacture. In accordance with one or more embodiments, a plurality of integrated circuit dies are provided in a semiconductor wafer, with each integrated circuit die having: an integrated circuit within the die, a via extending from a first surface to a second surface that opposes the first surface, and first and second electrical contacts at the first surface respectively coupled to the via and to the integrated circuit. Lanes are created in a front side of the wafer between the dies, and a portion of the back side of the wafer is removed to expose the lanes. A further contact and/or via is also exposed at the backside, with the via providing an electrical signal path for coupling electrical signals through the integrated circuit die (e.g., bypassing circuitry therein).

Vertical packaging configurations for ultrasound chips are described. Vertical packaging may involve use of integrated interconnects other than wires for wire bonding. Examples of such integrated interconnects include edge-contact vias, through silicon vias and conductive pillars. Edge-contact vias are vias defined in a trench formed in the ultrasound chip. Multiple vias may be provided for each trench, thus increasing the density of vias. Such vias enable electric access to the ultrasound transducers. Through silicon vias are formed through the silicon handle and provide access from the bottom surface of the ultrasound chip. Conductive pillars, including copper pillars, are disposed around the perimeter of an ultrasound chip and provide access to the ultrasound transducers from the top surface of the chip. Use of these types of packaging techniques can enable a substantial reduction in the dimensions of an ultrasound device.

Provided is an integrated fan-out (InFO) package structure including a first die, a second die, a third die, a protective layer, and an interconnect structure. The first die has a first surface and a second surface opposite to each other. The first die has a plurality of through substrate vias (TSVs) protruding from the second surface. The second die and the third die are bonded on the first surface of the first die. The protective layer laterally surrounds protrusions of the plurality of TSVs that protrude from the second surface. The interconnect structure are disposed on the protective layer and electrically connected to the plurality of TSVs. The interconnect structure includes a polymer layer covering the protective layer.