Solid metal foam thermal interface materials and their uses in electronics assembly are described. In one implementation, a method includes: applying a thermal interface material (TIM) between a first device and a second device to form an assembly having a first surface of the TIM in in touching relation with a surface of the first device, and a second surface of the TIM opposite the first surface in touching relation with a surface of the second device, the TIM comprising a solid metal foam and a first liquid metal; and compressing the assembly to form an alloy from the TIM that bonds the first device to the second device.

Aspects of the subject disclosure may include, for example, bonding III-Nitride epitaxial layer(s) to a carrier wafer, wherein the III-Nitride epitaxial layer(s) are grown on a non-native substrate, after the bonding, removing at least a portion of the non-native substrate from the III-Nitride epitaxial layer(s), processing the III-Nitride epitaxial layer(s) to derive an array of III-Nitride islands, establishing a metal layer over the array of III-Nitride islands, resulting in an array of metal-coated III-Nitride islands, arranging the carrier wafer relative to a host wafer to position the array of metal-coated III-Nitride islands on a surface of the host wafer, causing the array of metal-coated III-Nitride islands and the surface of the host wafer to eutectically bond, and removing the carrier wafer to yield an integrated arrangement of III-Nitride islands on the host wafer. Additional embodiments are disclosed.

A semiconductor device according to embodiments includes a first base material having a first side surface, a first semiconductor chip provided above the first base material, a first insulating plate provided between the first base material and the first semiconductor chip, a first metal plate provided between the first insulating plate and the first semiconductor chip, a first bonding material provided between the first metal plate and the first semiconductor chip, the first bonding material bonding the first metal plate and the first semiconductor chip, a second bonding material provided between the first base material and the first insulating material, the second bonding material bonding the first base material and the first insulating plate, a second base material having a second side surface, a second semiconductor chip provided above the second base material, a second insulating plate provided between the second base material and the second semiconductor chip, a second metal plate provided between the second insulating plate and the second semiconductor chip, a third bonding material provided between the second metal plate and the second semiconductor chip, the third bonding material bonding the second metal plate and the second semiconductor chip, a fourth bonding material provided between the second base material and the second insulating plate, the fourth bonding material bonding the second base material and the second insulating plate, and a first base bonding portion provided between the second side surface and the first side surface and bonded to the first side surface and the second side surface.

A system includes a semiconductor substrate having a first cavity. The semiconductor substrate forms a pedestal adjacent the first cavity. A device overlays the pedestal and is bonded to the semiconductor substrate by metal within the first cavity. A plurality of second cavities are formed in a surface of the pedestal beneath the device, wherein the second cavities are smaller than the first cavity. In some of these teachings, the second cavities are voids. In some of these teachings, the metal in the first cavity comprises a eutectic mixture. The structure relates to a method of manufacturing in which a layer providing a mask to etch the first cavity is segmented to enable easy removal of the mask-providing layer from the area over the pedestal.

A system includes a semiconductor substrate having a first cavity. The semiconductor substrate forms a pedestal adjacent the first cavity. A device overlays the pedestal and is bonded to the semiconductor substrate by metal within the first cavity. A plurality of second cavities are formed in a surface of the pedestal beneath the device, wherein the second cavities are smaller than the first cavity. In some of these teachings, the second cavities are voids. In some of these teachings, the metal in the first cavity comprises a eutectic mixture. The structure relates to a method of manufacturing in which a layer providing a mask to etch the first cavity is segmented to enable easy removal of the mask-providing layer from the area over the pedestal.

A method for manufacturing a semiconductor device includes forming a bonding layer on a back-surface of a semiconductor element, mounting the semiconductor element on a base member, and bonding the semiconductor element to the base member by pressing the semiconductor element on the base member. The bonding layer includes tin. The base member includes a plating layer that includes silver and tin. The base member is heated at a prescribed temperature. The semiconductor element is placed on the base member so that the bonding layer contacts the plating layer on the base member.

A semiconductor device according to embodiments includes a first base material having a first side surface, a first semiconductor chip provided above the first base material, a first insulating plate provided between the first base material and the first semiconductor chip, a first metal plate provided between the first insulating plate and the first semiconductor chip, a first bonding material provided between the first metal plate and the first semiconductor chip, the first bonding material bonding the first metal plate and the first semiconductor chip, a second bonding material provided between the first base material and the first insulating material, the second bonding material bonding the first base material and the first insulating plate, a second base material having a second side surface, a second semiconductor chip provided above the second base material, a second insulating plate provided between the second base material and the second semiconductor chip, a second metal plate provided between the second insulating plate and the second semiconductor chip, a third bonding material provided between the second metal plate and the second semiconductor chip, the third bonding material bonding the second metal plate and the second semiconductor chip, a fourth bonding material provided between the second base material and the second insulating plate, the fourth bonding material bonding the second base material and the second insulating plate, and a first base bonding portion provided between the second side surface and the first side surface and bonded to the first side surface and the second side surface.

Disclosed are multi-junction light emitting diode (LED) formed by using eutectic bonding and method of manufacturing the multi-junction LED. The multi-junction LED is formed by stacking a separately formed light emitting structure on another light emitting structure by using eutectic bonding. Since separately grown light emitting structure is stacked on the light emitting structure using the eutectic metal alloy bonding, it is possible to prevent crystal defects occurring between the light emitting structures when sequentially grown. Further, since the eutectic metal alloy can be formed in various patterns, it is possible to control and optimize adhesive strength, transmittance of the light generated in the upper light emitting structure, and resistance.

A system includes a semiconductor substrate having a first cavity. The semiconductor substrate forms a pedestal adjacent the first cavity. A device overlays the pedestal and is bonded to the semiconductor substrate by metal within the first cavity. A plurality of second cavities are formed in a surface of the pedestal beneath the device, wherein the second cavities are smaller than the first cavity. In some of these teachings, the second cavities are voids. In some of these teachings, the metal in the first cavity comprises a eutectic mixture. The structure relates to a method of manufacturing in which a layer providing a mask to etch the first cavity is segmented to enable easy removal of the mask-providing layer from the area over the pedestal.

A photocoupler of an embodiment includes an input terminal, an output terminal, a first MOSFET, a second MOSFET, a semiconductor light receiving element, a semiconductor light emitting element, and a resin layer. The first MOSFET is joined onto the third lead. The second MOSFET is joined onto the fourth lead. The semiconductor light receiving element is joined to each of the first junction region and the second junction region. The semiconductor light receiving element includes a light receiving region provided in a central part of a surface on opposite side from a surface joined to the first and second MOSFET. The resin layer seals the first and second MOSFETs, the semiconductor light receiving element, the semiconductor light emitting element, an upper surface and a side surface of the input terminal, and an upper surface and a side surface of the output terminal.