A method of manufacturing an electronic device includes providing a substrate, forming a solder on the substrate, and bonding a diode to the substrate through the solder, wherein the solder is formed by stacking a plurality of first conductive layers and a plurality of second conductive layers alternately, and the plurality of first conductive layers and the plurality of second conductive layers include different materials.

A method of manufacturing an electronic device includes providing a substrate, forming a solder on the substrate, and bonding a diode to the substrate through the solder, wherein the solder is formed by stacking a plurality of first conductive layers and a plurality of second conductive layers alternately, and the plurality of first conductive layers and the plurality of second conductive layers include different materials.

A structure including a substrate having a conductive pad and a connecting structure disposed on the conductive pad and electrically connected to the conductive pad. The connecting structure includes a first metallic layer disposed on the conductive pad, a first intermetallic compound layer disposed on the first metallic layer, a second intermetallic compound layer disposed on the first intermetallic compound layer and a second metallic layer disposed on the second intermetallic compound layer. The first metallic layer comprises copper. The first intermetallic compound layer comprises a first intermetallic compound. The second intermetallic compound layer comprises a second intermetallic compound different from the first intermetallic compound. The second metallic layer comprises tin. The first intermetallic compound contains copper, tin and one of nickel and cobalt.

A semiconductor device with redistribution layers formed utilizing dummy substrates is disclosed and may include forming a first redistribution layer on a first dummy substrate, forming a second redistribution layer on a second dummy substrate, electrically connecting a semiconductor die to the first redistribution layer, electrically connecting the first redistribution layer to the second redistribution layer, and removing the dummy substrates. The first redistribution layer may be electrically connected to the second redistribution layer utilizing a conductive pillar. An encapsulant material may be formed between the first and second redistribution layers. Side portions of one of the first and second redistribution layers may be covered with encapsulant. A surface of the semiconductor die may be in contact with the second redistribution layer. The dummy substrates may be in panel form. One of the dummy substrates may be in panel form and the other in unit form.

A three dimensional multi-die package includes a first die and second die. The first die includes a contact attached to solder. The second die is thinned by adhesively attaching a handler to a top side of the second die and thinning a bottom side of the second die. The second die includes a multilayer contact of layered metallurgy that inhibits transfer of adhesive thereto. The layered metallurgy includes at least one layer that is wettable to the solder. The multilayer contact may include a Nickel layer, a Copper layer upon the Nickel layer, and a Nickel-Iron layer upon the Copper layer. The multilayer contact may also include a Nickel layer, a Copper-Tin layer upon the Nickel layer, and a Tin layer upon the Copper-Tin layer.

Provided is a multilayer substrate including laminated semiconductor substrates each having a penetrating hole (hereinafter referred to as through hole) having a plated film formed in the inner surface. The multilayer substrate has excellent conduction characteristics and can be manufactured at low cost. Conductive particles are selectively present at a position where the through holes face each other as viewed in a plan view of the multilayer substrate. The multilayer substrate has a connection structure in which the facing through holes are connected by the conductive particles, and the semiconductor substrates each having the through hole are bonded by an insulating adhesive.

A method of manufacturing integrated devices, and a stacked integrated device are disclosed. In an embodiment, the method comprises providing a substrate; mounting at least a first electronic component on the substrate; positioning a handle wafer above the first electronic component; attaching the first electronic component to the substrate via electrical connectors between the first electronic component and the substrate; and while attaching the first electronic component to the substrate, using the handle wafer to apply pressure, toward the substrate, to the first electronic component, to manage planarity of the first electronic component during the attaching. In an embodiment, a joining process is used to attach the first electronic component to the substrate via the electrical connectors. For example, thermal compression bonding may be used to attach the first electronic component to the substrate via the electrical connectors.

A pad is disposed on a substrate. A bump structure is disposed on the pad and electrically connected to the pad. The bump structure includes a first copper layer and a second copper layer sequentially stacked on the pad and a solder ball on the second copper layer. A first X-ray diffraction (XRD) peak intensity ratio of (111) plane to (200) plane of the first copper layer is greater than a second XRD peak intensity ratio of (111) plane to (200) plane of the second copper layer.

A pad is disposed on a substrate. A bump structure is disposed on the pad and electrically connected to the pad. The bump structure includes a first copper layer and a second copper layer sequentially stacked on the pad and a solder ball on the second copper layer. A first X-ray diffraction (XRD) peak intensity ratio of (111) plane to (200) plane of the first copper layer is greater than a second XRD peak intensity ratio of (111) plane to (200) plane of the second copper layer.

A semiconductor device and formation thereof. The semiconductor device includes a first semiconductor structure, a second semiconductor structure, and a plurality of pillars interconnecting the first semiconductor structure and the second semiconductor structure. The plurality of pillars include a first solder layer and a second solder layer, wherein the first solder layer has a higher melting point than the second solder layer.