A device includes a substrate and a die. A first side of the die is electrically coupled to the substrate. The device also includes interconnect conductors electrically coupled to the die through conductive paths of the substrate. The device also includes an interposer structure that includes a first side and a second side. The first side includes first contacts electrically coupled to the interconnect conductors, and the second side includes second contacts. The interposer structure also includes a plurality of patterned conductive structures electrically coupled to the first contacts and to second contacts. The device further includes a plurality of conductive posts between a second side of the die and to the first side of the interposer structure and configured to conduct heat from the die to the interposer structure.

A method of forming a semiconductor device is provided. The method includes forming an interposer including a plurality of conductive vias, each conductive via having a first end exposed at a first major side of an interposer substrate and a second end exposed at a second major side of the interposer substrate. A semiconductor die is mounted on the first major side of the interposer substrate. An encapsulant encapsulates the semiconductor die and portions of the first major side of the interposer substrate. A redistribution layer structure is formed over the second major side of the interposer substrate such that the semiconductor die interconnected with the redistribution layer structure by way of the interposer.

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 structure includes a first dielectric layer over a metal line and a redistribution layer (RDL) over the first dielectric layer. The RDL is electrically connected to the metal line. The RDL has a curved top surface and a footing feature, where the footing feature extends laterally from a side surface of the RDL. A second dielectric layer is disposed over the RDL, where the second dielectric layer also has a curved top surface.

A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a first device die; a second device die, stacked on the first device die; and first electrical connectors and second electrical connectors, disposed in between the first and second device dies. A first pitch between the first electrical connectors is greater than a second pitch between the second electrical connectors. The first and second electrical connectors respectively comprise a solder joint and first metallic layers lying at opposite sides of the solder joint and formed of a first metallic material. Each of the second electrical connectors further comprises at least one second metallic layer formed of a second metallic material.

A microelectronic device includes a die with input/output (I/O) terminals, and a dielectric layer on the die. The microelectronic device includes electrically conductive pillars which are electrically coupled to the I/O terminals, and extend through the dielectric layer to an exterior of the microelectronic device. Each pillar includes a column electrically coupled to one of the I/O terminals, and a head contacting the column at an opposite end of the column from the I/O terminal. The head extends laterally past the column in at least one lateral direction. Methods of forming the pillars and the dielectric layer are disclosed.

In a bonding process of a flip chip bonding method, a chip is bonded to contact pads of a substrate by composite bumps which each includes a raiser, a UBM layer and a bonding layer. Before the bonding process, the surface of the bonding layer facing toward the substrate is referred to as a surface to be bonded. During the bonding process, the surface to be bonded is boned to the contact pad and become a bonding surface on the contact pad. The bonding surface has an area greater than that of the surface to be bonded so as to reduce electrical impedance between the chip and the substrate.

A semiconductor package may include a first substrate; a second substrate on the first substrate; at least one chip structure on the second substrate; connection bumps below the first substrate; first bump structures between the first substrate and the second substrate; and second bump structures between the at least one chip structure and the second substrate, wherein each of at least a portion of the first bump structures and the each of at least a portion of the second bump structures includes a pillar bump, a solder ball connecting the pillar bump to one of the upper pads or upper terminals, and a barrier film at least partially covering a side surface of the pillar bump, and wherein a thickness of the barrier film decreases in a direction perpendicular to the side surface of the pillar bump in a portion adjacent to the solder ball.

A chip-size-package type semiconductor device includes a semiconductor layer, pads, and metal redistributions that are located above a top surface of the semiconductor layer and each of which is connected to one or more pads. The metal redistributions include first metal redistributions each of which includes a first portion and a second portion contained within the first portion in a plan view, the second portion being located above the first portion and having an area smaller than an area of the first portion in the plan view. Each of the first metal redistributions includes one or more line-shaped bends in a boundary portion between the first portion and the second portion on a surface of the first metal redistribution, the one or more line-shaped bends each having an interior angle of at least 180 degrees in a cross section of the first metal redistribution.

An electronic device according to the present disclosure includes a semiconductor substrate, a chip, and a bump. The chip has a thermal expansion coefficient different from that of the semiconductor substrate. The bump connects the connection pads provided on the opposing principal surfaces of the semiconductor substrate and the chip. The bump has a porous metal layer and a metal film. The metal film is provided on at least one of a portion between the connection pad provided on the semiconductor substrate and the porous metal layer and a portion between the connection pad provided on the chip and the porous metal layer, and on the side surfaces of the porous metal layer.