A method includes bonding a first package component over a second package component. The second package component includes a plurality of dielectric layers, and a plurality of redistribution lines in the plurality of dielectric layers. The method further includes dispensing a stress absorber on the second package component, curing the stress absorber, and forming an encapsulant on the second package component and the stress absorber.

The present invention discloses an elastic heat spreader for chip packaging, a packaging structure and a packaging method. The heat spreader includes a top cover plate and a side cover plate that extends outward along an edge of the top cover plate, wherein the top cover plate is configured to be placed on a chip, and at least a partial region of the side cover plate is an elastic member; and the elastic member at least enables the side cover plate to be telescopic in a direction perpendicular to the top cover plate. According to the present invention, a following problem is solved: delamination between the heat spreader and a substrate as well as the chip due to stress generated by different thermal expansion coefficients of the substrate, the heat spreader and the chip in a packaging process of a large-size product.

To provide a superconducting device capable of more accurately arranging a non-contact coupling circuit of a superconducting integrated circuit chip and a non-contact coupling circuit of a circuit board. The chip has a first electrode made of a first superconducting material and a first non-contact coupling circuit on a surface thereof. The board has a second electrode made of a second superconducting material and a second non-contact coupling circuit on a surface thereof, and is arranged to face the chip. The second electrode has a protrusion protruding toward the chip. The protrusion includes a flat upper surface. The first electrode has a flat surface and a first recess. The first recess is arranged to face the upper surface to be located inside the upper surface of the protrusion. A third superconducting material connecting the upper surface and the first recess.

A display includes a wiring pad and a dummy pad on a first substrate. A first planarization layer is disposed on the wiring pad and the dummy pad. A first pad electrode layer is connected to the wiring pad and a second pad electrode layer is connected to the dummy pad. The first and second pad electrode layers are disposed on the first planarization layer. A first insulating layer covers the first and second pad electrode layers. A first pad electrode upper layer is disposed on the first pad electrode layer. A second pad electrode upper layer is disposed on the second pad electrode layer. The wiring pad, the first pad electrode layer, and the first pad electrode upper layer are electrically connected. The dummy pad, the second pad electrode layer, and the second pad electrode upper layer are electrically connected.

A semiconductor package includes a support wiring structure, a semiconductor chip on the support wiring structure, a connection structure on the support wiring structure and spaced apart from the semiconductor chip in a horizontal direction, an interposer including a central portion and an outer portion and having a recess portion provided on a lower surface of the central portion facing the semiconductor chip, wherein the central portion is on the semiconductor chip and the connection structure is connected to the outer portion, and a metal plate disposed along a portion of a surface of the recess portion inside the interposer, wherein the metal plate extends along a side surface of the outer portion of the interposer and the lower surface of the central portion of the interposer, and the metal plate has a cavity passing through a vicinity of a center of the metal plate planarly.

A chip package structure is provided. The chip package structure includes a first redistribution structure having a first surface and a second surface. The first redistribution structure includes a first pad and a second pad, the first pad is adjacent to the first surface, and the second pad is adjacent to and exposed from the second surface. The chip package structure includes a chip package bonded to the first pad through a first bump, wherein a first width of the first pad decreases in a first direction away from the chip package, and a second width of the second pad decreases in the first direction. The chip package structure includes a second bump over the second pad.

A method of forming one or more semiconductor packages includes mounting one or more semiconductor dies on the metal strip such that the one or more semiconductor dies are in a flip chip arrangement whereby terminals of the one or more semiconductor dies face the upper surface of the metal strip, forming an electrically insulating encapsulant material on the upper surface of the metal strip that encapsulates the one or more semiconductor dies, and forming package terminals that are electrically connected with the terminals of the one or more semiconductor dies, wherein the package terminals are formed from the metal strip or from metal that is deposited after removing the metal strip.

A method for forming a package structure is provided. The method includes transporting a first package component into a processing chamber. The method includes positioning the first package component on a chuck table. The method includes using the chuck table to heat the first package component. The method includes holding a second package component with a bonding head. The bonding head communicates with a plurality of vacuum devices via a plurality of vacuum tubes, and the vacuum devices each operate independently. The method also includes bonding the first package component and the second package component in the processing chamber to form the package structure.

A method of fabricating a semiconductor device includes forming a protective structure on at least one die on a substrate. The protective structure exposes one or more electrical contacts on a first surface of the at least one die. Respective terminals are formed on the one or more electrical contacts exposed by the protective structure. Related packages and fabrication methods are also discussed.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a first die having a surface; a template structure having a first surface and an opposing second surface, wherein the first surface of the template structure is coupled to the surface of the first die, and wherein the template structure includes a cavity at the first surface and a through-template opening extending from a top surface of the cavity to the second surface of the template structure; and a second die within the cavity of the template structure and electrically coupled to the surface of the first die by interconnects having a pitch of less than 10 microns between adjacent interconnects.