A packaged electronic component comprising: an electronic component housed within a package comprising a front part of a package comprising an inner section with a front cavity therein opposite the electronic component defined by the raised frame and an outer section sealing said cavity; and a back part of the package comprising a back cavity in an inner back section, and an outer back section sealing the cavity, said back package further comprising a first and a second via through the back end around said at least one back cavity for coupling to front and back electrodes of the electronic component; the vias terminating in external contact pads adapted to couple the package in a flip chip configuration to a circuit board.

Microfeature workpieces having alloyed conductive structures, and associated methods are disclosed. A method in accordance with one embodiment includes applying a volume of material to a bond pad of a microfeature workpiece, with the volume of material including a first metallic constituent and the bond pad including a second constituent. The method can further include elevating a temperature of the volume of material while the volume of material is applied to the bond pad to alloy the first metallic constituent and the second metallic constituent so that the first metallic constituent is alloyed generally throughout the volume of material. A thickness of the bond pad can be reduced from an initial thickness T1 to a reduced thickness T2.

A semiconductor device includes an electrode material diffusion suppression layer provided either between a gate electrode and a gate insulation film, between Al-containing ohmic electrodes and an Au interconnection, and below the gate electrode and above the Al-containing ohmic electrodes, the electrode material diffusion suppression layer having a structure wherein a first the TaN layer, a Ta layer, and a second the TaN layer are stacked in sequence.

A package includes an interposer, which includes a first substrate free from through-vias therein, redistribution lines over the first substrate, and a first plurality of connectors over and electrically coupled to the redistribution lines. A first die is over and bonded to the first plurality of connectors. The first die includes a second substrate, and through-vias in the second substrate. A second die is over and bonded to the plurality of connectors. The first die and the second die are electrically coupled to each other through the redistribution lines. A second plurality of connectors is over the first die and the second die. The second plurality of connectors is electrically coupled to the first plurality of connectors through the through-vias in the second substrate.

A package includes an interposer, which includes a first substrate free from through-vias therein, redistribution lines over the first substrate, and a first plurality of connectors over and electrically coupled to the redistribution lines. A first die is over and bonded to the first plurality of connectors. The first die includes a second substrate, and through-vias in the second substrate. A second die is over and bonded to the plurality of connectors. The first die and the second die are electrically coupled to each other through the redistribution lines. A second plurality of connectors is over the first die and the second die. The second plurality of connectors is electrically coupled to the first plurality of connectors through the through-vias in the second substrate.

An integrated circuit structure includes a two-tier die including a first tier and a second tier over and bonded to the first tier. The first tier includes a first substrate including a semiconductor material, an active device at a surface of the first substrate, and a first interconnect structure over the first substrate, wherein the first tier is free from passive devices therein. The second tier includes a second substrate bonded to and in contact with the first interconnect structure, and a second interconnect structure over the second substrate, wherein metal lines in the second interconnect structure are electrically coupled to the first interconnect structure. The second tier further includes a plurality of through-vias penetrating through the second substrate, wherein the plurality of through-vias lands on metal pads in a top metal layer of the first interconnect structure, and a passive device in the second interconnect structure.

In accordance with certain embodiments, electronic devices feature a polymeric binder, a frame defining an aperture therethrough, and a semiconductor die (e.g., a light-emitting or a light-detecting element) suspended in the binder and within the aperture of the frame.

Image sensor and method of manufacturing the same are provided. The image sensor includes a semiconductor substrate including a pixel area, a voltage connection area, and a pad area, a plurality of photoelectric conversion devices in the pixel area, an anti-reflective layer on a back side of the semiconductor substrate and on the plurality of photoelectric conversion devices, a device isolation structure between the plurality of photoelectric conversion devices, at least one voltage connection structure in the voltage connection area, and electrically connected to the device isolation structure, at least one voltage applying device electrically connected to the at least one voltage connection structure, an internal circuit including at least one conductive inner wire and at least one conductive inner via in an insulating layer, and a through via structure in the pad area.

Methods of singulation and bonding, as well as structures formed thereby, are disclosed. A method includes singulating a first chip and after the singulating the first chip, bonding the first chip to a second chip. The first chip includes a first semiconductor substrate and a first interconnect structure on a front side of the first semiconductor substrate. The singulating the first chip includes etching through a back side of the first semiconductor substrate through the first interconnect structure.

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.