Abstract: A stackable microelectronic package includes a first microelectronic die attached to and electrically connecting with a first substrate. A second microelectronic die is attached to the first die on one side, and to a second substrate on the other side. Electrical connections are made between the first die and the first substrate, between the second die and the second substrate, and between the first and second substrates, e.g., via wire bonding. The electrical connecting elements are advantageously encased in a molding compound. Exposed contacts on the first and/or second substrates, not covered by the molding compound, provide for electrical connections between the package, and another package stacked onto the package. The package may avoid coplanarity factors, can be manufactured using existing equipment, allows for intermediate testing, and can also offer a thinner package height.

Abstract: A method for densifying thermoplastics, particularly polyimides, for use in conjunction with electronic circuits while producing improved physical properties and a high degree of crystallinity, involves variable frequency microwave (VFM) processing at temperatures typically 100° C. below the glass transition temperature or lower, for times of about 50 to 100 minutes. It is particularly applicable to polymers based on BPDA-PPD, but may also be generally applied to other intentionally designed polyimide structures with the same features. The invention enables the creation of layered structures involving integrated circuits with small feature sizes and overcoatings of polymers with high Tg and other desirable properties.

Abstract: An integrated circuit includes first and second active regions extending in a first direction, a first gate line extending in a second direction substantially perpendicular to the first direction and crossing the first and second active regions, and a first contact jumper including a first conductive pattern intersecting the first gate line above the first active region and a second conductive pattern extending in the second direction above the first gate line and connected to the first conductive pattern.

Abstract: A semiconductor chip having a core region and an I/O region which surrounds the core region is provided with a plurality of external connection pads connected to I/O cells. The plurality of external connection pads include a first pad group comprised of the external connection pads connected to the same node, and a second pad group comprised of the external connection pads connected to respective different nodes. In first and second pad groups, the external connection pads are arranged in an X direction along an external side of the semiconductor chip, and a pad arrangement pitch in the first pad group is smaller than that in the second pad group.

Abstract: A manufacturing method of a semiconductor structure includes at least the following steps. A semiconductor device having a first surface and a second surface opposite to the first surface is provided. A plurality of through semiconductor vias (TSV) embedded in the semiconductor device is formed. A first seal ring is formed over the first surface of the semiconductor device. The first seal ring is adjacent to edges of the first surface and is physically in contact with the TSVs. A second seal ring is formed over the second surface of the semiconductor device. The second seal ring is adjacent to edges of the second surface and is physically in contact with the TSVs.

Abstract: Semiconductor devices, methods of manufacture thereof, and semiconductor device packages are disclosed. In one embodiment, a semiconductor device includes an insulating material layer having openings on a surface of a substrate. One or more insertion bumps are disposed over the insulating material layer. The semiconductor device includes signal bumps having portions that are not disposed over the insulating material layer.

Abstract: A stack package includes a first sub-package, a second sub-package stacked on the first sub-package. The first sub-package is configured to include first and second semiconductor dies, a first flexible bridge die disposed between the first and second semiconductor dies.

Abstract: A semiconductor device including conductive lines is disclosed. First conductive lines each comprise a first portion, a second portion, and an enlarged portion, the enlarged portion connecting the first portion and the second portion of the first conductive line. The semiconductor device includes second conductive lines, at least some of the second conductive lines disposed between a pair of the first conductive lines, each second conductive line including a larger cross-sectional area at an end portion of the second conductive line than at other portions thereof. The semiconductor device includes a pad on each of the first conductive lines and the second conductive lines, wherein the pad on each of the second conductive lines is on the end portion thereof and the pad on each of the first conductive lines is on the enlarged portion thereof.

Abstract: Semiconductor devices are provided including a plurality of nonlinear bit lines formed on a substrate including a plurality of active areas; a plurality of word lines that pass through the plurality of active areas; an integral spacer that covers two sidewalls of the plurality of nonlinear bit lines and defines a plurality of spaces that expose two adjacent ones of the plurality of active areas; two conductive patterns that respectively abut on the two adjacent active areas in one of the plurality of spaces that is selected; and a contact separating insulation layer that is formed between the two conductive patterns in the one selected space.

Abstract: A die and a substrate are provided. The die comprises at least one integrated circuit chip, and the substrate comprises first and second subsets of conductive pillars extending at least partially therethrough. Each of the first subset of conductive pillars comprises a protrusion bump pad protruding from a surface of the substrate, and the second subset of conductive pillars each partially form a trace recessed within the surface of the substrate. The die is coupled to the substrate via a plurality of conductive bumps each extending between one of the protrusion bump pads and the die.

Abstract: Semiconductor packages with electromagnetic interference supported stacked die and a method of manufacture therefor is disclosed. The semiconductor packages may house a stack of dies in a system in a package (SiP) implementation, where one or more of the dies may be wire bonded to a semiconductor package substrate. The dies may be stacked in a partially overlapping, and staggered manner, such that portions of some dies may protrude out over an edge of a die that is below it. This dies stacking may define a cavity, and in some cases, wire bonds may be made to the protruding portions of the die. Underfill material may be provided in the cavity and cured to form an underfill support. Wire bonding of the bond pads overlying the cavity formed by the staggered stacking of the dies may be performed after the formation of the underfill support.

Abstract: A semiconductor module includes a die pad frame; a semiconductor chip disposed in a chip region on an upper surface of the die pad frame, the semiconductor chip having an upper surface on which a first electrode is disposed and a lower surface on which a second electrode is disposed; a conductive connection member for die pad disposed between the second electrode of the semiconductor chip and the upper surface of the die pad frame, the conductive connection member for die pad electrically connecting the second electrode of the semiconductor chip and the upper surface of the die pad frame; a first clip frame disposed on the upper surface of the semiconductor chip; a first clip conductive connection member disposed between the first electrode on the semiconductor chip and a lower surface of the first clip frame, the first clip conductive connection member electrically connecting the first electrode of the semiconductor chip and the lower surface of the first clip frame; and a sealing resin for sealing the semic

Abstract: A semiconductor module includes: a first lead frame connected to a plurality of semiconductor chips in a first arm circuit; a second lead frame connected to a plurality of semiconductor chips in a second arm circuit; a first main terminal connected to the first lead frame; and a second main terminal connected to the second lead frame, wherein each of the first lead frame and second lead frame has a facing part, a first terminal connection portion connected to the first main terminal is provided at a first end portion of the first lead frame, a second terminal connection portion connected to the second main terminal is provided at a second end portion of the second lead frame, and the first terminal connection portion and second terminal connection portion are arranged on opposite sides when viewed from the facing parts of the first lead frame and second lead frame.

Abstract: A method of making a semiconductor component includes etching a substrate to define an opening. The method further includes depositing a first dielectric liner in the opening, wherein the first dielectric liner has a first stress. The method further includes depositing a second dielectric liner over the first dielectric liner, wherein the second dielectric liner has a second stress, and a direction of the first stress is opposite a direction of the second stress. The method further includes depositing a conductive material over the second dielectric liner.

Abstract: Semiconductor device packages for incorporation into semiconductor device assemblies may include a substrate including an array of electrically conductive elements located on a lower surface of the substrate. A window may extend through the substrate from the lower surface to an upper surface of the substrate. The array of electrically conductive elements may at least partially laterally surround a periphery of the window, and the substrate may extend laterally beyond the array of electrically conductive elements. At least a portion of a heat-management structure may be located within the window. At least a portion of an outer periphery of an underlying substrate may laterally overlap with an inner portion of the substrate defining the periphery of the window.

Abstract: A semiconductor module includes a die pad frame; a semiconductor chip disposed in a chip region on an upper surface of the die pad frame, the semiconductor chip having an upper surface on which a first electrode is disposed and a lower surface on which a second electrode is disposed; a conductive connection member for die pad disposed between the second electrode of the semiconductor chip and the upper surface of the die pad frame, the conductive connection member for die pad electrically connecting the second electrode of the semiconductor chip and the upper surface of the die pad frame; and a sealing resin for sealing the semiconductor chip, the die pad frame, and the conductive connection member for die pad.

Abstract: A semiconductor structure and a method for forming the same are provided. The semiconductor structure includes a gate structure, a source/drain structure, a first contact plug and a first via plug. The gate structure is positioned over a fin structure. The source/drain structure is positioned in the fin structure and adjacent to the gate structure. The first contact plug is positioned over the source/drain structure. The first via plug is positioned over the first contact plug. The first via plug includes a first group IV element.

Abstract: A semiconductor device includes: a semiconductor element; a support as a metallic member that includes a metallized layer having a first component as an iron group element and a second component as a periodic table group five or group six transition metal element other than chromium provided at an outermost surface of the support, and is arranged such that the outermost surface faces the semiconductor element; a joint material that is arranged between the outermost surface of the support and the semiconductor element, and is joined with the outermost surface to fix the semiconductor element to the support; and a molding resin that is arranged to cover a joint body having the support, the joint material and the semiconductor element.

Abstract: A chip package assembly and method for fabricating the same are provided which utilize a composite stiffener selected to provide excellent resistance to warpage without detrimentally imposing excessive stress on a package substrate of the package assembly. In one example, the chip package assembly includes an integrated circuit die stacked on a top surface of a package substrate, and a composite stiffener coupled to a first edge of the package substrate. The composite stiffener includes a first stiffener member and a second stiffener member. The first stiffener member has a bottom surface bonded to the top surface of the package substrate. The second stiffener member is disposed over the first stiffener member. The second stiffener member has a bottom surface bonded to the top surface of the package substrate. The second stiffener member has a Young's modulus that is less than a Young's modulus of the first stiffener member.

Abstract: A semiconductor package device includes: (1) a substrate having a top surface; (2) a passive component disposed on the substrate and having a top surface; (3) an active component disposed on the substrate and having a top surface; and (4) a package body disposed on the substrate, the package body including a first portion covering the active component and the passive component, and a second portion covering the passive component, wherein a top surface of the second portion of the package body is higher than a top surface of the first portion of the package body, and the first portion and the second portion of the package body include different materials.