The present invention provides a bump structure of chip disposed on a surface of a chip and comprises a plurality of connecting-bump sets. Each connecting-bump set includes a first connecting hum and a second connecting hump. The first connecting bump and the second connecting bump include corresponding blocking structures. While disposing the chip on a board member, the blocking structure of the first connecting bump and the blocking structure of the second connecting bump block the conductive medium and retard the flow of the conductive medium. The conductive medium is forced to flow between the first connecting bump and the second connecting bump and thus preventing the conductive particles in the conductive medium from leaving the surfaces of the connecting bumps. In addition, there is a flow channel between the first and second connecting bumps. One or more width of the flow channel is between 0.1 μm and 8 μm.

A unit pixel including a first light emitting stack; a second light emitting stack disposed under the first light emitting stack, and having an area greater than that of the first light emitting stack; a third light emitting stack disposed under the second light emitting stack, and having an area greater than that of the second light emitting stack, in which at least one of the first through third light emitting stacks includes a side surface having an inclination angle within a range of about 30 degrees to about 70 degrees with respect to a first plane parallel to a top surface of the third light emitting stack.

In some examples, a quad flat no lead (QFN) semiconductor package comprises a flip chip semiconductor die having a surface and circuitry formed in the surface; and a conductive pillar coupled to the semiconductor die surface. The conductive pillar has a distal end relative to the semiconductor die, the distal end having a cavity including a cavity floor and one or more cavity walls circumscribing the cavity floor. The one or more cavity walls are configured to contain solder.

According to an aspect of the inventive concept, there is provided a die-to-wafer bonding structure including a die having a first test pad, a first bonding pad formed on the first test pad, and a first insulating layer, the first bonding pad penetrates the first insulating layer. The structure may further include a wafer having a second test pad, a second bonding pad formed on the second test pad, and a second insulating layer, the second bonding pad penetrates the second insulating layer. The structure may further include a polymer layer surrounding all side surfaces of the first bonding pad and all side surfaces of the second bonding pad, the polymer layer being arranged between the die and the wafer. Additionally, the wafer and the die may be bonded together.

A cryogenic electronic package includes at least two superconducting and/or conventional metal semiconductor structures. Each of the semiconductor structures includes a substrate and a superconducting trace. Additionally, each of the semiconductor structures includes a passivation layer and one or more under bump metal (UBM) structures. The cryogenic electronic package also includes one or more superconducting and/or conventional metal interconnect structures disposed between selected ones of the at least two superconducting semiconductor structures. The interconnect structures are electrically coupled to respective ones of the UBM structures of the semiconductor structures to form one or more electrical connections between the semiconductor structures. A method of fabricating a cryogenic electronic package is also provided.

A cryogenic electronic package includes at least two superconducting and/or conventional metal semiconductor structures. Each of the semiconductor structures includes a substrate and a superconducting trace. Additionally, each of the semiconductor structures includes a passivation layer and one or more under bump metal (UBM) structures. The cryogenic electronic package also includes one or more superconducting and/or conventional metal interconnect structures disposed between selected ones of the at least two superconducting semiconductor structures. The interconnect structures are electrically coupled to respective ones of the UBM structures of the semiconductor structures to form one or more electrical connections between the semiconductor structures. A method of fabricating a cryogenic electronic package is also provided.

A semiconductor device has a semiconductor die and substrate with a plurality of stud bumps formed over the semiconductor die or substrate. The stud bumps include a base portion and stem portion extending from the base portion. The stud bumps include a non-fusible material or fusible material. The semiconductor die is mounted to the substrate with the stud bumps electrically connecting the semiconductor die to the substrate. A width of the base portion is greater than a mating conductive trace formed on the substrate. Alternatively, a vertical interconnect structure, such as a conductive column, is formed over the semiconductor die or substrate. The conductive column can have a tapered sidewall or oval cross sectional area. An underfill material is deposited between the semiconductor die and substrate. The semiconductor die includes a flexible property. The vertical interconnect structure includes a flexible property. The substrate includes a flexible property.

A semiconductor device has a semiconductor die and substrate with a plurality of stud bumps formed over the semiconductor die or substrate. The stud bumps include a base portion and stem portion extending from the base portion. The stud bumps include a non-fusible material or fusible material. The semiconductor die is mounted to the substrate with the stud bumps electrically connecting the semiconductor die to the substrate. A width of the base portion is greater than a mating conductive trace formed on the substrate. Alternatively, a vertical interconnect structure, such as a conductive column, is formed over the semiconductor die or substrate. The conductive column can have a tapered sidewall or oval cross sectional area. An underfill material is deposited between the semiconductor die and substrate. The semiconductor die includes a flexible property. The vertical interconnect structure includes a flexible property. The substrate includes a flexible property.

A semiconductor package includes an interposer, a semiconductor element installed on a first surface of the interposer, bumps formed on a second surface of the interposer, and a chip component installed on the second surface of the interposer. The interposer is a silicon interposer; the semiconductor element is flip-chip mounted on the first surface of the interposer; the chip component is a thin film passive element formed by carrying out a thin film process on a silicon substrate, and a pad being formed on one surface of the thin film passive element; and the pad of the chip component is connected to a land formed on the second surface of the interposer using a conductive bonding material. According to this structure, the reliability of a bond between the interposer and the chip component of the semiconductor package can be ensured while achieving a small size.

A semiconductor package includes an interposer, a semiconductor element installed on a first surface of the interposer, bumps formed on a second surface of the interposer, and a chip component installed on the second surface of the interposer. The interposer is a silicon interposer; the semiconductor element is flip-chip mounted on the first surface of the interposer; the chip component is a thin film passive element formed by carrying out a thin film process on a silicon substrate, and a pad being formed on one surface of the thin film passive element; and the pad of the chip component is connected to a land formed on the second surface of the interposer using a conductive bonding material. According to this structure, the reliability of a bond between the interposer and the chip component of the semiconductor package can be ensured while achieving a small size.