Abstract: Implementations of a semiconductor substrate may include a plurality of die including at least one contact; and a plurality of portions of an encapsulant on a surface of the semiconductor substrate, wherein each portion of the plurality of portions extends immediately above a plane of the at least one contact.

Abstract: Implementations of a semiconductor device may include a first largest planar surface, a second largest planar surface and a thickness between the first largest planar surface and the second largest planar surface; and one of a permanent die support structure, a temporary die support structure, or any combination thereof coupled to one of the first largest planar surface, the second largest planar surface, the thickness, or any combination thereof. The first largest planar surface, the second largest planar surface, and the thickness may be formed by at least two semiconductor die. The warpage of one of the first largest planar surface or the second largest planar surface may be less than 200 microns.

Abstract: Implementations of a semiconductor package may include a singulated die and a passivating material of a predetermined thickness across a majority of a singulated surface of the singulated die on at least one singulated surface of the singulated die.

Abstract: Implementations of a semiconductor device may include a first largest planar surface, a second largest planar surface and a thickness between the first largest planar surface and the second largest planar surface; and one of a permanent die support structure, a temporary die support structure, or any combination thereof coupled to one of the first largest planar surface, the second largest planar surface, the thickness, or any combination thereof. The first largest planar surface, the second largest planar surface, and the thickness may be formed by at least two semiconductor die. The warpage of one of the first largest planar surface or the second largest planar surface may be less than 200 microns.

Abstract: Implementations of a semiconductor device may include a semiconductor die comprising a first largest planar surface, a second largest planar surface and a thickness between the first largest planar surface and the second largest planar surface; and a temporary die support structure coupled to one of the first largest planar surface, the second largest planar surface, the thickness, or any combination thereof. The thickness may be between 0.1 microns and 125 microns. The warpage of the semiconductor die may be less than 200 microns.

Abstract: Implementations of a curved die system may include a semiconductor die; and a die curvature support structure including an organic material coupled to a surface of the semiconductor die. The die curvature support structure may induce warpage greater than 200 microns in the surface of the semiconductor die. The die curvature support structure may be configured to induce warpage prior to coupling the semiconductor die to a correspondingly curved substrate.

Abstract: Implementations of a packaging system may include a wafer; and a curvature adjustment structure coupled thereto where the curvature adjustment structure may be configured to alter a curvature of a largest planar surface of the wafer.

Abstract: A method of forming a semiconductor package. Implementations include forming on a die backside an intermediate metal layer having multiple sublayers, each including a metal selected from the group consisting of titanium, nickel, copper, silver, and combinations thereof. A tin layer is deposited onto the intermediate metal layer and is then reflowed with a silver layer of a substrate to form an intermetallic layer having a melting temperature above 260 degrees Celsius and including an intermetallic consisting of silver and tin and/or an intermetallic consisting of copper and tin. Another method of forming a semiconductor package includes forming a bump on each of a plurality of exposed pads of a top side of a die, each exposed pad surrounded by a passivation layer, each bump including an intermediate metal layer as described above and a tin layer coupled to the intermediate metal layer is reflowed to form an intermetallic layer.

Abstract: A method includes applying a sintering precursor material layer to each of a first surface and a second surface of a ceramic tile, and assembling a precursor assembly of a direct bonded copper (DBC) substrate by coupling a first leadframe on the sinter precursor material layer on the first surface of the ceramic tile and a second leadframe on the second surface of the sinter precursor material layer on a second surface of the ceramic tile such that the ceramic tile is disposed between the first leadframe and the second leadframe. The method further includes sinter bonding the first leadframe and the second leadframe to the ceramic tile to form a sinter bonded DBC substrate.

Abstract: A method of forming a semiconductor package. Implementations include forming on a die backside an intermediate metal layer having multiple sublayers, each including a metal selected from the group consisting of titanium, nickel, copper, silver, and combinations thereof. A tin layer is deposited onto the intermediate metal layer and is then reflowed with a silver layer of a substrate to form an intermetallic layer having a melting temperature above 260 degrees Celsius and including an intermetallic consisting of silver and tin and/or an intermetallic consisting of copper and tin. Another method of forming a semiconductor package includes forming a bump on each of a plurality of exposed pads of a top side of a die, each exposed pad surrounded by a passivation layer, each bump including an intermediate metal layer as described above and a tin layer coupled to the intermediate metal layer is reflowed to form an intermetallic layer.

Abstract: A method for forming a through-substrate via structure includes providing a substrate and providing a conductive via structure adjacent to a first surface of the substrate. The method includes providing a recessed region on an opposite surface of the substrate towards the conductive via structure. The method includes providing an insulator in the recessed region and providing a conductive region extending along a first sidewall surface of the recessed region in the cross-sectional view. In some examples, the first conductive region is provided to be coupled to the conductive via structure and to be further along at least a portion of the opposite surface of the substrate outside of the recessed region. The method includes providing a protective structure within the recessed region over a first portion of the first conductive region but not over a second portion of the first conductive region that is outside of the recessed region.

Abstract: A semiconductor baseplate is disclosed. Specific implementations of a baseplate may include a planar portion including a plurality of recesses therein, the planar portion may be made of a first material, and a plurality of pegs where each peg of the plurality of pegs may be configured to fit within each recess of the plurality of recesses, the plurality of pegs may be made of a second material, where the first material and the second material may be bonded together.

Abstract: A through-substrate vias structure includes a substrate having opposing first and second major surfaces. One or more conductive via structures are disposed extending from the first major surface to a first vertical distance within the substrate. A recessed region extends from the second major surface to a second vertical distance within the substrate and adjoining a lower surface of the conductive via. In one embodiment, the second vertical distance is greater than the first vertical distance. A conductive region is disposed within the recessed region and is configured to be in electrical and/or thermal communication with the conductive via.

Abstract: A semiconductor device has a first semiconductor die and second semiconductor die with a conductive layer formed over the first semiconductor die and second semiconductor die. The second semiconductor die is disposed adjacent to the first semiconductor die with a side surface and the conductive layer of the first semiconductor die contacting a side surface and the conductive layer of the second semiconductor die. An interconnect, such as a conductive material, is formed across a junction between the conductive layers of the first and second semiconductor die. The conductive layer may extend down the side surface of the first semiconductor die and further down the side surface of the second semiconductor die. An extension of the side surface of the first semiconductor die can interlock with a recess of the side surface of the second semiconductor die. The conductive layer extends over the extension and into the recess.

Abstract: In a general aspect, an apparatus can include a metal layer, a first semiconductor die, a second semiconductor die, a molding compound, a first electrical contact and a second electrical contact. The first semiconductor die can have a first side disposed on the metal layer. The second semiconductor die can have a first side disposed on the metal layer. The metal layer can electrically couple the first side of the first semiconductor die with the first side of the second semiconductor die. The molding compound can at least partially encapsulate the metal layer, the first semiconductor die and the second semiconductor die. The first electrical contact can be to a second side of the first semiconductor die and disposed on a surface of the apparatus. The second electrical contact can be to a second side of the second semiconductor die and disposed on the surface of the apparatus.

Abstract: Implementations of a semiconductor package may include a semiconductor die including a first side and a second side where the first side of the semiconductor die includes one or more electrical contacts; a layer of metal coupled to the second side of the semiconductor; and a stress balance structure coupled to one of the layer of metal or around the one or more electrical contacts.

Abstract: A method for fabricating a chip scale package, comprising: providing a wafer; applying a polymer resin on at least part of a first surface of the wafer and to one or more sides of the wafer; and applying a compression mold on at least part of a second surface of the wafer and to one or more sides of the wafer, said first and second surfaces opposing each other.

Abstract: A semiconductor device has a first semiconductor die with a base material. A covering layer is formed over a surface of the base material. The covering layer can be made of an insulating material or metal. A trench is formed in the surface of the base material. The covering layer extends into the trench to provide the cantilevered protrusion of the covering layer. A portion of the base material is removed by plasma etching to form a cantilevered protrusion extending beyond an edge of the base material. The cantilevered protrusion can be formed by removing the base material to the covering layer, or the cantilevered protrusion can be formed within the base material under the covering layer. A second semiconductor die is disposed partially under the cantilevered protrusion. An interconnect structure is formed between the cantilevered protrusion and second semiconductor die.

Abstract: One illustrative method embodiment includes: providing a direct bonded copper (DBC) substrate including a plurality of copper traces; providing a guide plate having protrusions on a surface of the guide plate; mounting hollow bush rings onto the protrusions; mounting the bush rings onto the copper traces by aligning the protrusions of the guide plate with solder units on said copper traces; attaching the bush rings and one or more dies to the copper traces by simultaneously reflowing said solder units and other solder units positioned between the dies and the copper traces; and after said simultaneous reflow, removing the protrusions from the bush rings.

Abstract: A method includes placing a coupling mechanism material layer on a backside of a wafer having power devices fabricated on a frontside thereof, and placing conductive spacer blocks on the coupling mechanism material layer on a backside of the selected wafer. The method further includes activating the coupling mechanism material to bond the conductive spacer blocks to the backside of the selected wafer, and singulating the wafer to separate the vertical device stacks, each of the singulated vertical device stacks including a device die bonded to, or fused with, a conductive spacer block.