A manufacturing method of a semiconductor apparatus includes preparing an intermediate member that includes a first member having a first substrate comprising a semiconductor element formed thereon, a second member having a second substrate, the second substrate including a part of a circuit electrically connected to the semiconductor element and having a linear expansion coefficient different from that of the first substrate, and a third member having a third substrate showing such a linear expansion coefficient that a difference between itself and the linear expansion coefficient of the first substrate is smaller than a difference between the linear expansion coefficients of the first substrate and the second substrate, and includes bonding the first member and the second member together. A first bonding electrode containing copper electrically connected to the semiconductor element and a second bonding electrode containing copper electrically connected to the circuit are bonded together.

A heat dissipation device includes a substrate with a network of thermally-conductive vias and thermally-conductive layers. The substrate has a first surface and a second surface opposite to the first surface. A heat dissipation interface layer including a stack of a first layer made of a first thermally-conductive material and a second layer made of a second thermally-conductive material. The first material is different from the second material. A surface of the first layer is coplanar with the first surface of the substrate. At least one of the thermally-conductive vias of said network supports and is in contact with the first layer. At least one opening thoroughly crosses the stack of the first and second layers. Material of the substrate fills the opening in the first layer.

The present invention provides a conductive bonded assembly utilizing particles of Ni or an Ni alloy as conductive particles so as to enable firing under non-pressing conditions and further realize an excellent bonding strength, electron migration characteristic, and ion migration characteristic. The conductive bonded assembly of the present invention is a conductive bonded assembly of an electronic component which has a first bondable member (for example, electrode material), a second bondable member (for example, a semiconductor device on an Si or SiC substrate), and a conductive bonding layer bonding these bondable members together, where the bonding layer is an Ni sintered body formed by a sintered body of Ni particles which has a porosity of 30% or less, and, further, can be obtained by heating and sintering the Ni particles at the time of firing where the Ni sintered bonding layer is formed.

A semiconductor device according to the present embodiment includes a circuit board comprising a plurality of electrodes provided on a first surface, a first resin layer provided on the first surface around the electrodes, and a second resin layer provided on the first resin layer. A first semiconductor chip is connected to a first one of the electrodes. A second semiconductor chip is provided above the first semiconductor chip, being larger than the first semiconductor chip, and is connected to a second one of the electrodes via a metal wire. A third resin layer is provided between the first semiconductor chip and the second semiconductor chip and between the second resin layer and the second semiconductor chip, and covers the first semiconductor chip.

A power semiconductor package device and a method of preparation the device are disclosed. The package device includes a die paddle, a first pin, a second pin, and a semiconductor chip attached to the die paddle. A first electrode, a second electrode and a third electrode of the semiconductor chip are connected to the first pin, the second pin and the die paddle respectively. A plastic package body covers the semiconductor chip, the die paddle, the first pin and the second pin. The first pin and the second pin are located near two adjacent corners of the plastic package body. The bottom surface and two side surfaces of each of the first pin and the second pin are exposed from the plastic package body. Locking mechanisms are constructed to prevent the first pin and the second pin from falling off the power semiconductor package device during a manufacturing cutting process. Portions of the first pin, portions of the second pin, and portions of the plastic package body can be cut off. Therefore, the size of the power semiconductor package device is reduced.

A semiconductor arrangement includes a lower semiconductor chip, an upper semiconductor chip arranged over an upper main side of the lower semiconductor chip, a metallization layer arranged on the upper main side of the lower semiconductor chip, and a bonding material which fastens the upper semiconductor chip on the lower semiconductor chip. The metallization layer includes a structure with increased roughness in comparison with the rest of the metallization layer, the structure being arranged along a contour of the upper semiconductor chip.

An electronic device includes a substrate, a plurality of micro semiconductor structure, a plurality of conductive members, and a non-conductive portion. The substrate has a first surface and a second surface opposite to each other. The micro semiconductor structures are distributed on the first surface of the substrate. The conductive members electrically connect the micro semiconductor structures to the substrate. Each conductive member is defined by an electrode of one of the micro semiconductor structures and a corresponding conductive pad on the substrate. The non-conductive portion is arranged on the first surface of the substrate. The non-conductive portion includes one or more non-conductive members, and the one or more non-conductive members are attached to the corresponding one or more conductive members of the one or more micro conductive structures.

Disclosed herein is an electrical connecting structure having nano-twins copper, including a first substrate having a first nano-twins copper layer and a second substrate having a second nano-twins copper layer. The first nano-twins copper layer includes a plurality of first nano-twins copper grains. The second nano-twins copper layer includes a plurality of second nano-twins copper grains. The first nano-twins copper layer is joined with the second nano-twins copper layer. At least a portion of the first nano-twins copper grains extend into the second nano-twins copper layer, or at least a portion of the second nano-twins copper grains extend into the first nano-twins copper layer.

In some examples, an electronic device comprises a first component having a surface, a second component having a surface, and a bond layer positioned between the surfaces of the first and second components to couple the first and second components to each other. The bond layer includes a set of metallic nanowires and a dielectric portion. The dielectric portion comprises a polymer matrix and dielectric nanoparticles.

A method for forming a package structure is provided. The method includes forming a first interconnect structure over a carrier substrate and disposing a first die structure over the first interconnect structure. The method includes forming a dam structure over the first die structure. The method also includes forming a protection layer over a second interconnect structure. The method further includes bonding the second interconnect structure over the dam structure. In addition, the method includes forming a package layer between the first interconnect structure and the second interconnect structure. The method also includes removing the protection layer.