A semiconductor device includes a substrate including a substrate top surface; interconnects connected to the substrate and extending above the substrate top surface; a die attached over the substrate, wherein the die includes a die bottom surface that connects to the interconnects for electrically coupling the die and the substrate; and a metal enclosure directly contacting and vertically extending between the substrate top surface and the die bottom surface, wherein the metal enclosure peripherally surrounds the interconnects.

Methods of fabricating semiconductor device packages may involve forming trenches in a first wafer. A dielectric material may be placed over a first active surface. Electrically conductive elements may be operatively connected to bond pads of a second wafer with the dielectric material interposed between the first wafer and the second wafer. Force may be applied to the first wafer and the second wafer while exposing the first wafer and the second wafer to an elevated temperature. Portions of the dielectric material may flow into the trenches. The elevated temperature may be reduced to at least partially solidify the dielectric material. A thickness of the first wafer may be reduced to reveal the portions of the dielectric material in the trenches. The first wager may be singulated and the second wafer may be singulated to form semiconductor dice.

A method of manufacturing a semiconductor device in which a prescribed target lamination number of semiconductor chips are laminated on a substrate, the method includes: a first lamination step of laminating while temporarily bonding one or more semiconductor chips on the substrate to thereby form a first chip laminate body; a first permanent bonding step of pressurizing while heating from the upper side of the first chip laminate body to thereby collectively and permanently bond the one or more semiconductor chips; a second lamination step of sequentially laminating while temporarily bonding two or more semiconductor chips on the permanently bonded semiconductor chips to thereby form a second chip laminate body; and a second permanent bonding step of pressurizing while heating from the upper side of the second chip laminate body to thereby collectively permanently bond the two or more semiconductor chips.

A substrate bonding apparatus that bonds a first substrate and a second substrate together, comprising a joining section that joins the first substrate and second substrate together aligned to each other for stacking; a detecting section that detects an uneven state on at least one of the first substrate and second substrate prior to joining by the joining section; and a determining section that determines whether the uneven state detected by the detecting section satisfies a predetermined condition, wherein the joining section does not join the first substrate and the second substrate if it is determined by the determining section that the uneven state does not satisfy the predetermined condition.

A multi-layer wafer and method of manufacturing such wafer are provided. The method comprises applying a stress compensating oxide layer to each of two heterogeneous wafers, applying at least one bonding oxide layer to at least one of the two heterogeneous wafers, chemical-mechanical polishing the at least one bonding oxide layer, and low temperature bonding the two heterogeneous wafers to form a multi-layer wafer pair. The multi-layer wafer comprises two heterogeneous wafers, each of the heterogeneous wafers having a stress compensating oxide layer and at least one bonding oxide layer applied to at least one of the two heterogeneous wafers. The two heterogeneous wafers are low temperature bonded together to form the multi-layer wafer.

A process and resultant article of manufacture made by such process comprises forming through vias needed to connect a bottom device layer in a bottom silicon wafer to the one in the top device layer in a top silicon wafer comprising a silicon-on-insulator (SOI) wafer. Through vias are disposed in such a way that they extend from the middle of the line (MOL) interconnect of the top wafer to the buried oxide (BOX) layer of the SOI wafer with appropriate insulation provided to isolate them from the SOI device layer.

A method includes vacuum annealing on a substrate having at least one solder bump to reduce voids at an interface of the at least one solder bump. A die is mounted over the substrate.

An article of manufacture is formed by preparing a first silicon-on-insulator (SOI) wafer with first bonding pads at a first top or back-end-of-line (BEOL) surface thereof, preparing a second SOI wafer with second bonding pads at a second BEOL surface thereof, and attaching the first and second SOI wafers by bonding their bonding pads together, thereby producing a sandwiched wafer with first and second bottom or front-end-of-line (FEOL) surfaces facing outward and with first and second BEOL surfaces facing each other near the midline of the sandwiched wafer. The first SOI wafer then is prepared for packaging by first removing the silicon substrate from the first FEOL surface to reveal a buried oxide (BOX) layer, then fabricating interconnects atop the BOX layer and forming input output pads atop the interconnects.

A connecting device for connecting a circuit chip to a substrate is provided. The connecting device includes: a main body having a first opening and a second opening; a vibration part on the main body, the vibration part being configured to vibrate the main body; and an intake part coupled with the first and second openings to adsorb the circuit chip to the main body. Both the first and second openings are open at a surface of the main body to which the circuit chip is adsorbed, and the second opening is arranged in the first opening on a plane.

A semiconductor device includes a first die; a second die attached over the first die; a metal enclosure directly contacting and extending between the first die and the second die, wherein the first metal enclosure is continuous and encircles a set of one or more internal interconnects, wherein the first metal enclosure is configured to electrically connect to a first voltage level; and a second metal enclosure directly contacting and extending between the first die and the second die, wherein the second metal enclosure is continuous and encircles the first metal enclosure and is configured to electrically connect to a second voltage level; wherein the first metal enclosure and the second metal enclosure are configured to provide an enclosure capacitance encircling the set of one or more internal interconnects for shielding signals on the set of one or more internal interconnects.