A bonded body is provided including: a bonding layer containing Cu; and a semiconductor element bonded to the bonding layer. The bonding layer includes an extending portion laterally extending from a peripheral edge of the semiconductor element. In a cross-sectional view in a thickness direction, the extending portion rises from a peripheral edge of a bottom of the semiconductor element or from the vicinity of the peripheral edge of the bottom of the semiconductor element, and includes a side wall substantially spaced apart from a side of the semiconductor element. Preferably, the extending portion does not include any portion where the side wall and the side of the semiconductor element are in contact with each other. A method for manufacturing a bonded body is also provided.

An integrated circuit (IC) die structure comprises a substrate material comprising silicon. Integrated circuitry is over a first side of the substrate material. A composite layer is in direct contact with a second side of the substrate material. The second side is opposite the first side. The composite layer comprises a first constituent material associated with a first linear coefficient of thermal expansion (CTE), and a first thermal conductivity exceeding that of the substrate. The composite layer also comprises a second constituent material associated with a second CTE that is lower than the first, and a second thermal conductivity exceeding that of the substrate.

A multi-chip package includes multiple IC die interconnected to a package substrate. An integrated heat spreader (IHS) is located over one or more primary IC die, but is absent from over one or more secondary IC die. Thermal cross-talk between IC dies and/or thermal performance of individual IC dies may be improved by constraining the dimensions of the IHS to be over less than all IC die of the package. A first thermal interface material (TIM) may be between the IHS and the primary IC die, but absent from over the secondary IC die. A second TIM may be between a heat sink and the IHS and also between the heat sink and the secondary IC die. The heat sink may be segmented, or have a non-planarity to accommodate differences in z-height across the IC die and/or as a result of constraining the dimensions of the IHS to be over less than all IC die.

A multi-chip package includes multiple IC die interconnected to a package substrate. An integrated heat spreader (IHS) is located over one or more primary IC die, but is absent from over one or more secondary IC die. Thermal cross-talk between IC dies and/or thermal performance of individual IC dies may be improved by constraining the dimensions of the IHS to be over less than all IC die of the package. A first thermal interface material (TIM) may be between the IHS and the primary IC die, but absent from over the secondary IC die. A second TIM may be between a heat sink and the IHS and also between the heat sink and the secondary IC die. The heat sink may be segmented, or have a non-planarity to accommodate differences in z-height across the IC die and/or as a result of constraining the dimensions of the IHS to be over less than all IC die.

A display module and a manufacturing method thereof are provided. The manufacturing method may include forming an epitaxial film comprising a light emitting layer, a first type semiconductor layer, and a second type semiconductor layer, attaching the epitaxial film to an intermediate substrate comprising a conductive material, patterning the epitaxial film to form a light emitting diode (LED) and coupling the LED to a driving circuit layer through the conductive material.

Embodiments of a microelectronic assembly comprise a microelectronic assembly, comprising: a package substrate; an interposer coupled to the package substrate, the interposer comprising a dielectric material, a conductive pillar) through the dielectric material and a conductive structure at least partially surrounding the conductive pillar, the conductive structure separated from the conductive pillar by the dielectric material; and an integrated circuit (IC) die coupled to the interposer on a side opposite to the package substrate. The conductive pillar conductively couples the IC die to the package substrate, and the conductive structure is coupled to a ground connection.

A multi-chip package includes multiple IC die interconnected to a package substrate. An integrated heat spreader (IHS) is located over one or more primary IC die, but is absent from over one or more secondary IC die. Thermal cross-talk between IC dies and/or thermal performance of individual IC dies may be improved by constraining the dimensions of the IHS to be over less than all IC die of the package. A first thermal interface material (TIM) may be between the IHS and the primary IC die, but absent from over the secondary IC die. A second TIM may be between a heat sink and the IHS and also between the heat sink and the secondary IC die. The heat sink may be segmented, or have a non-planarity to accommodate differences in z-height across the IC die and/or as a result of constraining the dimensions of the IHS to be over less than all IC die.

A multi-chip package includes multiple IC die interconnected to a package substrate. An integrated heat spreader (IHS) is located over one or more primary IC die, but is absent from over one or more secondary IC die. Thermal cross-talk between IC dies and/or thermal performance of individual IC dies may be improved by constraining the dimensions of the IHS to be over less than all IC die of the package. A first thermal interface material (TIM) may be between the IHS and the primary IC die, but absent from over the secondary IC die. A second TIM may be between a heat sink and the IHS and also between the heat sink and the secondary IC die. The heat sink may be segmented, or have a non-planarity to accommodate differences in z-height across the IC die and/or as a result of constraining the dimensions of the IHS to be over less than all IC die.

A method and apparatus are provided that includes an integrated circuit die having an in-chip heat sink, along with an electronic device and a chip package having the same, and methods for fabricating the same. In one example, an integrated circuit die has an in-chip heat sink that separates a high heat generating integrated circuit from another integrated circuit disposed within the die. The in-chip heat sink provides a highly conductive heat transfer path from interior portions of the die to at least one exposed die surface.

A method and apparatus are provided that includes an integrated circuit die having an in-chip heat sink, along with an electronic device and a chip package having the same, and methods for fabricating the same. In one example, an integrated circuit die has an in-chip heat sink that separates a high heat generating integrated circuit from another integrated circuit disposed within the die. The in-chip heat sink provides a highly conductive heat transfer path from interior portions of the die to at least one exposed die surface.