A method for mounting components on a substrate is provided. The method includes providing a positioning plate which has a plurality of through holes. The method further includes supplying components each having a longitudinal portion on the positioning plate. The method also includes performing a component alignment process to put the longitudinal portions of the components in the through holes. In addition, the method includes connecting a substrate to the components which have their longitudinal portions in the through holes and removing the positioning plate.

Disclosed are semiconductor packages and methods of fabricating the same. The semiconductor package comprises a redistribution substrate including dielectric and redistribution patterns, a first substrate pad on the redistribution substrate and penetrating the dielectric pattern to be coupled to the redistribution pattern, a second substrate pad the redistribution substrate and spaced apart from the first substrate pad, a semiconductor chip on the redistribution substrate, a first connection terminal connecting the first substrate pad to one of chip pads of the semiconductor chip, and a second connection terminal connecting the second substrate pad to another one of the chip pads of the semiconductor chip. A top surface of the second substrate pad is located at a higher level than that of a top surface of the first substrate pad. A width of the second substrate pad is less than that of the first substrate pad.

An integrated circuit structure includes an alignment bump and an active electrical connector. The alignment bump includes a first non-solder metallic bump. The first non-solder metallic bump forms a ring encircling an opening therein. The active electrical connector includes a second non-solder metallic bump. A surface of the first non-solder metallic bump and a surface of the second non-solder metallic bump are substantially coplanar with each other.

A device includes a work piece including a metal bump; and a dielectric layer having a portion directly over the metal bump. The metal bump and a surface of the portion of the dielectric layer form an interface. A metal finish is formed over and contacting the metal bump. The metal finish extends from over the dielectric layer to below the interface.

In some examples, a system comprises a set of nanoparticles and a set of nanowires extending from the set of nanoparticles.

A method is disclosed for electrically bonding a first semiconductor component to a second semiconductor component, both components including arrays of contact areas. In one aspect, prior to bonding, layers of an intermetallic compound are formed on the contact areas of the second component. The roughness of the intermetallic layers is such that the intermetallic layers include cavities suitable for insertion of a solder material in the cavities, under the application of a bonding pressure, when the solder is at a temperature below its melting temperature. The components are aligned and bonded, while the solder material is applied between the two. Bonding takes place at a temperature below the melting temperature of the solder. The bond can be established only by the insertion of the solder into the cavities of the intermetallic layers, and without the formation of a second intermetallic layer.

A stamp for micro-transfer printing includes a support having a support stiffness and a support coefficient of thermal expansion (CTE). A pedestal layer is formed on the support, the pedestal layer having a pedestal layer stiffness that is less than the support stiffness and a pedestal layer coefficient of thermal expansion (CTE) that is different from the support coefficient of thermal expansion (CTE). A stamp layer is formed on the pedestal layer, the stamp layer having a body and one or more protrusions extending from the body in a direction away from the pedestal layer. The stamp layer has a stamp layer stiffness that is less than the support stiffness and a stamp layer coefficient of thermal expansion that is different from the support coefficient of thermal expansion.

The present disclosure relates to an integrated chip structure having a first substrate including a plurality of transistor devices disposed within a semiconductor material. An interposer substrate includes vias extending through a silicon layer. A copper bump is disposed between the first substrate and the interposer substrate. The copper bump has a sidewall defining a recess. Solder is disposed over the copper bump and continuously extending from over the copper bump to within the recess. A conductive layer is disposed between the first substrate and the interposer substrate and is separated from the copper bump by the solder.

A connection arrangement for forming a component carrier structure is disclosed. The connection arrangement includes a first electrically conductive connection element and a second electrically conductive connection element. The first connection element and the second connection element are configured such that, upon connecting the first connection element with the second connection element along a connection direction, a form fit is established between the first connection element and the second connection element that limits a relative motion between the first connection element and the second connection element in a plane perpendicular to the connection direction. A component carrier and a method of forming a component carrier structure are also disclosed.

An electronic device, a package structure and an electronic manufacturing method are provided. The electronic device includes a substrate, a first bump, a second bump and a first reflowable material. The first bump is disposed over the substrate, and has a first width. An end portion of the first bump defines a first recess portion. The second bump is disposed over the substrate, and has a second width less than the first width. The first reflowable material is disposed on the first bump and extends in the first recess portion.