A semiconductor structure includes an interposer substrate having an upper surface, a lower surface opposite to the upper surface, and a device region. A first redistribution layer is formed on the upper surface of the interposer substrate. A guard ring is formed in the interposer substrate and surrounds the device region. At least a through-silicon via (TSV) is formed in the interposer substrate. An end of the guard ring and an end of the TSV that are near the upper surface of the interposer substrate are flush with each other, and are electrically connected to the first redistribution layer.

The present disclosure relates to thin-form-factor reconstituted substrates and methods for forming the same. The reconstituted substrates described herein may be utilized to fabricate homogeneous or heterogeneous high-density 3D integrated devices. In one embodiment, a silicon substrate is structured by direct laser patterning to include one or more cavities and one or more vias. One or more semiconductor dies of the same or different types may be placed within the cavities and thereafter embedded in the substrate upon formation of an insulating layer thereon. One or more conductive interconnections are formed in the vias and may have contact points redistributed to desired surfaces of the reconstituted substrate. The reconstituted substrate may thereafter be integrated into a stacked 3D device.

An electronic device includes: (i) a first chiplet including a first seal ring, which is disposed in metal layers embedded between a first surface of the first chiplet, and a first substrate of the first chiplet, (ii) a second chiplet including a second seal ring, which is disposed in metal layers embedded between a second surface of the second chiplet, and a second substrate of the second chiplet, and (iii) a third seal ring, which surrounds the first and second chiplets and is disposed in a dielectric substrate extrinsic to the metal layers and overlaying the first and second surfaces of the first and second chiplets.

A die dipping structure includes a plate including a first recessed portion having a first depth and filled with a first flux material. The plate further includes a second recessed portion, isolated from the first recessed portion, with a second depth and filled with a second flux material. The second depth is different from the first depth. The die dipping structure further includes a motor configured to move the plate so as to simultaneously dip a first die and a second die into the flux of the first recessed portion and the flux of the second recessed portion, respectively.

Example embodiments provide a package substrate including a lid structure. The package substrate includes a substrate, a semiconductor element arranged on one surface of the substrate, and a lid surrounding at least a portion of the semiconductor element. The lid includes a region extending outwardly beyond the outer periphery of the substrate.

A method for producing a semiconductor apparatus capable of producing a semiconductor apparatus with improved transmission loss characteristic using an interposer substrate in which semiconductor devices formed on a silicon single crystal substrate are connected to each other by a through electrode, the method including: a step of providing the silicon single crystal substrate containing a dopant; a step of forming the semiconductor devices and the through electrode on the silicon single crystal substrate to obtain the interposer substrate; and a step of irradiating a particle beam to at least around a formation part for the through electrode on the silicon single crystal substrate to deactivate the dopant in a region around the formation part for the through electrode.

A package includes an integrated circuit. The integrated circuit includes a first chip, a second chip, a third chip, and a fourth chip. The second chip and the third chip are disposed side by side on the first chip. The second chip and the third chip are hybrid bonded to the first chip. The fourth chip is fusion bonded to at least one of the second chip and the third chip.

A dual-sided embedded multi-die interconnect bridge provides power and source conduits from the bridge bottom at a silicon portion, in short paths to dice on a die side of an integrated-circuit package substrate. Signal traces are in a metallization on the silicon portion of the dual-sided EMIB. Power, ground and signal vias all emanate from the dual-sided embedded multi-die interconnect bridge, with power and ground entering the bridge from central regions of the silicon portion.

An interposer includes: a base substrate; an interconnection structure on a top surface of the base substrate and including a metal interconnection pattern; an upper passivation layer on the interconnection structure and having compressive stress; a lower passivation layer under a bottom surface of base substrate, the lower passivation layer having compressive stress that is less than the compressive stress of the upper passivation layer; a lower conductive layer under the lower passivation layer; and a through electrode penetrating the base substrate and the lower passivation layer. The through electrode electrically connects the lower conductive layer to the metal interconnection pattern of the interconnection structure.

The present disclosure relates to micro-via structures for interconnects in advanced wafer level semiconductor packaging. The methods described herein enable the formation of high-quality, low-aspect-ratio micro-via structures with improved uniformity, thus facilitating thin and small-form-factor semiconductor devices having high I/O density with improved bandwidth and power.