Disclosed are semiconductor packages and their fabrication methods. The semiconductor package comprises a first substrate having first pads on a first surface of the first substrate, a second substrate on the first substrate and having a plurality of second pads on a second surface of the second substrate, and connection terminals between the first substrate and the second substrate and correspondingly coupling the first pad to the second pads. Each of the connection terminals has a first major axis and a first minor axis that are parallel to the first surface of the first substrate and are orthogonal to each other. When viewed in a plan view, the first minor axis of each of the connection terminals is directed toward a center of the first substrate.

A metal bump containing structure is provided which has a substantially flat top surface and enhanced coplanarity with other like metal bump containing structures. The metal bump containing structures include a metal bump having a curved top surface, and a first metal liner located along an outermost sidewall and present at least partially on the curved top surface of the metal bump.

A method of fabricating integrated passive device dies includes forming a first plurality of integrated passive devices on a substrate, forming a plurality of micro-bumps on the first plurality of integrated passive devices such that the plurality of micro-bumps act as electrical connections to the integrated passive devices, and dicing the substrate to form an integrated passive device die including a second plurality of integrated passive devices. The micro-bumps may be formed in an array or staggered configuration and may have a pitch that is in a range from 20 microns to 100 microns. The integrated passive devices may each include a seal ring and the integrated passive device die may have an area that is a multiple of an integrated passive device area. The method may further include dicing the substrate in various ways to generate integrated passive device dies having different sizes and numbers of integrated passive devices.

Disclosed are semiconductor devices and their fabrication methods. The semiconductor device comprises a pad on a semiconductor chip, a protective layer on the semiconductor chip and having an opening that exposes a portion of a top surface of the pad, and a bump structure electrically connected to the pad. The bump structure includes a metal layer on the pad and a solder ball on the metal layer. A first width of the metal layer is about 0.85 times to about 0.95 times a second width of the opening.

A chip-stacked device includes a first chip including a first substrate including a first face, a first conductive film provided in an island form over the first face and electrically connected to a signal line, and a second conductive film provided apart from the first conductive film over the first face and connected to the ground line; a second chip; a first bonding portion covering the first conductive film; and a second bonding portion apart from the first conductive film and the first bonding portion, the second bonding portion located over the second conductive film. The first chip and the second chip are bonded to each other via the first bonding portion and the second bonding portion.

A method of manufacturing a semiconductor device is provided. The method includes forming a redistribution layer (RDL) over a semiconductor die, a portion of the RDL contacting a die pad of the semiconductor die. A non-conductive layer is formed over the RDL. An opening in the non-conductive layer is formed exposing a portion of the RDL. A plurality of plateau regions is formed in the non-conductive layer. A cavity region in the non-conductive layer separates each plateau region of the plurality of plateau regions. A metal layer is deposited over the non-conductive layer and exposed portion of the RDL and etched to expose the plurality of plateau regions through the metal layer. The cavity region remains substantially filled by a portion of the metal layer.

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.

Microelectronic die package structures formed according to some embodiments may include a substrate and a die having a first side and a second side. The first side of the die is coupled to the substrate, and a die backside layer is on the second side of the die. The die backside layer includes a plurality of unfilled grooves in the die backside layer. Each of the unfilled grooves has an opening at a surface of the die backside layer, opposite the second side of the die, and extends at least partially through the die backside layer.

A display device includes: a first substrate; a plurality of light-emitting elements on the first substrate; a second substrate opposite to the first substrate, and including one face facing the first substrate, and an opposite face to the one face; a plurality of grooves at the opposite face of the second substrate; a plurality of wavelength conversion layers, each of the wavelength conversion layers being located in a corresponding groove of the plurality of grooves to convert a wavelength of light emitted from a corresponding light-emitting element of the plurality of light-emitting elements; and a plurality of color filters on the wavelength conversion layers, respectively.

A semiconductor package includes a circuit board, an interposer structure on the circuit board, a first semiconductor chip and a second semiconductor chip on the interposer structure, the first and the second semiconductor chips electrically connected to the interposer structure and spaced apart from each other, and a mold layer between the first and second semiconductor chips, the mold layer separating the first and second semiconductor chips. A slope of a side wall of the mold layer is constant as the side wall extends away from an upper side of the interposer structure, and an angle defined by a bottom side of the mold layer and the side wall of the mold layer is less than or equal to ninety degrees.