A semiconductor chip, a display device or an electronic device includes a substrate, one or more conductive pads disposed on the substrate, and one or more bumps electrically connected to the one or more conductive pads, in which the one or more bumps includes a metal core, a polymer layer disposed over a surface of the metal core, and a conductive coating layer disposed over a surface of the polymer layer and electrically connected to the one or more conductive pads.

A semiconductor package device includes a carrier, a first electronic component, and a conductive element on the carrier. The first electronic component is over the carrier. The conductive element is on the carrier and electrically connects the first electronic component to the carrier. The conductive element includes at least one conductive particle and a solder material covering the conductive particle, and the conductive particle includes a metal core, a barrier layer covering the metal core, and a metal layer covering the barrier layer.

fan-out wafer level package is disclosed, which comprises: a redistribution layer; a semiconductor chip electrically connected with the redistribution layer through a bump; a protective member protecting the semiconductor chip, wherein a part of the protective member is removed such that the upper surface of the semiconductor chip is exposed in order to dissipate heat and prevent warpage; and an interconnector disposed outside the semiconductor chip at substantially the same level and having a lower part electrically connected with the redistribution layer and an upper part not being covered with the protective member, wherein the interconnector includes a metal core solder ball, the metal core solder ball includes a metal core and a solder buffer between the metal core and the protective member, and the metal core is formed of a combination of copper (Cu), nickel (Ni), and silver (Ag).

A surface mount structure includes a substrate, a sensor, an electrical contact and a package body. The substrate has a first surface and a second surface opposite to the first surface. The sensor is disposed adjacent to the second surface of the substrate. The electrical contact is disposed on the first surface of the substrate. The package body covers the first surface and the second surface of the substrate, a portion of the sensor and a first portion of the electrical contact.

The resin-encapsulated semiconductor device includes a bump electrode (2) formed on an element surface side of a semiconductor chip (1), a conductive layer (3) electrically connected to the bump electrode (2), and a resin encapsulation body (6) covering the semiconductor chip (1), the bump electrode (2), and the conductive layer (3). On a back surface of the semiconductor chip (1) that is flush with a back surface of the resin encapsulation body (6), a metal layer (4) and a laminated film (5) are formed. The laminated film (5) is formed on a front surface of the conductive layer (3). The external terminal (9) is arranged on an inner side of an outer edge of the semiconductor chip (1).

A package-less integrated circuit semiconductor device is produced by laminating first and second insulating films on opposed first and second surfaces of a semiconductor wafer having semiconductor dice integrated therein. Electrically conductive formations towards die pads of the semiconductor dice are provided in vias to the semiconductor wafer opened through the first insulating film laminated on the first surface of the semiconductor wafer. The semiconductor wafer provided with these electrically conductive formations is singulated at separation lines between neighboring semiconductor dice to produce individual semiconductor devices. Each device has: opposed first and second device surfaces having protective portions of the first and second insulating films laminated thereon, and side surfaces extending between the opposed first and second device surfaces, these side surfaces being left uncovered by the first and second insulating films.

A circuit substrate in a chip package is provided. The circuit substrate includes first and second insulating layers covering opposite first and second surfaces of the semiconductor substrate, respectively. The circuit substrate also includes first and second pads disposed in the first and second insulating layers, respectively, and laterally separated from an opening that extends from the first surface to the second surface of the semiconductor substrate. The circuit substrate further includes first and second under bump metallization (UBM) layers disposed on the first and second pads, respectively. The first UBM layer has a surface protruding above the first insulating layer, and the second UBM layer extends from the second pad onto the second insulating layer, and is partially recessed into the second insulating layer to form a concave surface.

A bump structure for electrically coupling semiconductor components is provided. The bump structure includes a first bump on a first semiconductor component and a second bump on a second semiconductor component. The first bump has a first non-flat portion (e.g., a convex projection) and the second bump has a second non-flat portion (e.g., a concave recess). The bump structure also includes a solder joint formed between the first and second non-flat portions to electrically couple the semiconductor components.

Disclosed is a solder particle including a plastic core; a copper-free metal layer which is formed on an external surface of the plastic core; and a solder layer which is formed on the copper-free metal layer and contains not less than 85 wt % tin. Thus, it is possible to provide a solder particle with a copper-free metal layer, which is excellent in strength and conductivity and prevents or minimizes generation of a void during a reflow process or the like.

Disclosed is a solder particle including a plastic core; a copper-free metal layer which is formed on an external surface of the plastic core; and a solder layer which is formed on the copper-free metal layer and contains not less than 85 wt % tin. Thus, it is possible to provide a solder particle with a copper-free metal layer, which is excellent in strength and conductivity and prevents or minimizes generation of a void during a reflow process or the like.