A device comprises a substrate) of a first material with a surface, which is modified by depositing a bi-layer nanoparticle film. The film includes a nanoparticle layer of a second material on top of and in contact with surface, and a nanoparticle layer of a third material on top of and in contact with the nanoparticle layer of the second material. The nanoparticles of the third material adhere to the nanoparticles of the second material. The substrate region adjoining surface comprises an admixture of the second material in the first material. A fourth material contacts and chemically/mechanically bonds to the nanoparticle layer of the third material.

A manufacturing method includes: forming a stacked chip structure, wherein forming the stacked chip structure includes: attaching a semiconductor wafer for first semiconductor chips onto a carrier and attaching second semiconductor chips onto the semiconductor wafer, forming a first heat dissipation pattern on an upper surface of the semiconductor wafer and side surfaces of the second semiconductor chips, and cutting the first heat dissipation pattern and the semiconductor wafer to separate the semiconductor wafer into the first semiconductor chips; mounting the stacked chip structure including at least one of the first semiconductor chips and at least one of the second semiconductor chips on a first interconnection structure; and forming a second heat dissipation pattern on the first interconnection structure.

A copper diffusion-suppressing electrical bond between a first semiconductor wafer or chip or interposer and a second semiconductor wafer or chip or interposer includes a first bond pad metal with a first bond pad metal surface disposed on the first semiconductor wafer or chip or interposer, bonded with a second bond pad metal with a second bond pad metal surface disposed on the second semiconductor wafer or chip or interposer. A copper outdiffusion-suppressing coating such as a titanium, cobalt, nickel/gold, or nickel/palladium/gold layer may be disposed on the first copper bond pad metal surface and/or on the second copper bond pad metal surface. The copper of the bond pad metal may be doped with manganese to form a copper outdiffusion-suppressing surface manganese oxide. The bond pad metal may alternatively be tungsten to prevent copper outdiffusion.

A semiconductor device may include a transistor on a substrate, a first wiring structure on the transistor, a first bonding pad structure on the first wiring structure, a second wiring structure on the first wiring structure and at least partially overlapping the first bonding pad structure in a horizontal direction, a second bonding pad structure on and spaced apart from the second wiring structure and overlapping the first bonding pad structure in the horizontal direction, a bit line structure on the first and second bonding pad structures, a gate structure on the bit line structure, a channel adjacent to the gate structure and in contact with the bit line structure, and a capacitor on the channel.

A semiconductor package includes a wiring structure. A buffer die is disposed on the wiring structure. A logic die is disposed alongside the buffer die on the wiring structure. A first encapsulating material covers at least a portion of each of the buffer die and the logic die. A memory stack is disposed on the buffer die and is electrically connected to the buffer die. A bridge die is disposed so as to extend over at least a portion of each of the buffer die and the logic die, and is electrically connected to each of the buffer die and the logic die. A second encapsulating material covers at least a portion of each of the memory stack and the bridge die. The buffer die and the logic die are disposed at a level that is between those of the wiring structure and the bridge die.

A chip is assembled on an interconnection substrate. A heat dissipation layer made of a thermal interface material is deposited on the chip. A cap is bonded to the substrate with the cap covering the chip and the heat dissipation layer contacting with the cap. An element made of an adhesive material or a solderable material is formed on the chip prior to depositing the heat dissipation layer, or formed on the cap prior to bonding the cap. The element is thus in contact with the cap and with the chip and positioned next to the heat dissipation layer.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a first die and a through-dielectric via (TDV) surrounded by a dielectric material in a first layer, where the TDV has a greater width at a first surface and a smaller width at an opposing second surface of the first layer; a second die, surrounded by the dielectric material, in a second layer on the first layer, where the first die is coupled to the second die by interconnects having a pitch of less than 10 microns, and the dielectric material around the second die has an interface seam extending from a second surface of the second layer towards an opposing first surface of the second layer with an angle of less than 90 degrees relative to the second surface; and a substrate on and coupled to the second layer.

A power chip packaging structure includes: a ceramic substrate; a first and a second top metal layers are formed on the ceramic substrate; a bottom metal layer formed on the ceramic substrate; a power chip having an active surface and a chip back surface. The active surface has a contact pad, and the chip back surface is connected to the first top metal layer. One or more first copper layers are formed on the contact pad, a top surface of the first copper layer has a peripheral region and an arrangement region surrounded by the peripheral region. Multiple second copper layers are formed in the arrangement region and separated from each other. Each of multiple wires is respectively connected to the second copper layer with one end and connected to the second top metal layer with the other end.

A semiconductor device includes: a multilayered wiring layer including an insulation layer (30) and a diffusion prevention layer (21, 22, 23, 24) stacked alternately and including a wiring layer (11, 12, 13) internally; a gap section (50) disposed at least in a portion of the insulation layer (30); and a support section (60) disposed at least in a portion of the gap section (50) and configured to support the multilayered wiring layer.

A semiconductor device has a first semiconductor package, second semiconductor package, and RDL. The first semiconductor package is disposed over a first surface of the RDL and the second semiconductor package is disposed over a second surface of the RDL opposite the first surface of the RDL. A carrier is initially disposed over the second surface of the RDL and removed after disposing the first semiconductor package over the first surface of the RDL. The first semiconductor package has a substrate, plurality of conductive pillars formed over the substrate, electrical component disposed over the substrate, and encapsulant deposited around the conductive pillars and electrical component. A shielding frame can be disposed around the electrical component. An antenna can be disposed over the first semiconductor package. A portion of the encapsulant is removed to planarize a surface of the encapsulant and expose the conductive pillars.