A method and apparatus for conducting heat away from a semiconductor die are disclosed. A board assembly is disclosed that includes a first circuit board having an opening extending through the first circuit board. A Chemical Vapor Deposition Diamond (CVDD) window extends within the opening. A layer of thermally conductive paste extends over the CVDD window. A semiconductor die extends over the layer of thermally conductive paste such that a hot-spot on the semiconductor die overlies the CVDD window.

Provided is a semiconductor package including: a first substrate having a first electrode pad and a first protective layer in which a cavity is formed; a first bump pad arranged in the cavity and connected to the first electrode pad; a second substrate facing the first substrate and having a second bump pad; and a bump structure in contact with the first bump pad and the second bump pad, wherein the first electrode pad has a trapezoidal shape, and the first bump pad has a flat upper surface and an inclined side surface extending along a side surface of the first electrode pad.

A display apparatus is provided. The display apparatus includes a display substrate and a plurality of pads arranged above the display substrate. Each of the plurality of pads includes a first conductive layer, at least a portion of which is covered by an insulating film, a second conductive layer arranged above the first conductive layer, and a clamping portion formed in the second conductive layer.

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 wiring design method and a wiring structure for a package substrate in a flip chip, and a flip chip. The wiring design method includes: arranging bump pads in an array of rows and columns, wherein the bump pads are configured to bond with conductive bumps on a flip chip die, and the bump pads comprise signal pads and non-signal pads; providing the non-signal pad with a via hole; and using a layer of wiring to lead a subset of the signal pads out of an orthographic projection region of the flip chip die on the package substrate, wherein the subset of the signal pads is configured to carry all functional signals required by design specifications of the flip chip die for the array of the bump pads.

A method for forming a board assembly includes identifying a location of a hot-spot on a semiconductor die and cutting an opening in a circuit board corresponding to the location of the identified hot-spot. A Chemical Vapor Deposition Diamond (CVDD) window is inserted into the opening. A layer of thermally conductive paste is applied over the CVDD window. The semiconductor die is placed over the layer of thermally conductive paste such that the CVDD window underlies the hot-spot and such that a surface of the semiconductor die is in direct contact with the layer of thermally conductive paste.

A semiconductor package including a first die, through electrodes penetrating the first die, a first pad on a top surface of the first die and coupled to a through electrode, a second die on the first die, a second pad on a bottom surface of the second die, a first connection terminal connecting the first pad to the second pad, and an insulating layer that fills a region between the first die and the second die and encloses the first connection terminal. The first connection terminal includes an intermetallic compound made of solder material and metallic material of the first and second pads. A concentration of the metallic material in the first connection terminal is substantially constant regardless of a distance from the first pad or the second pad.

A light-emitting device includes a carrier substrate, a flip-chip light-emitting diode (LED) mounted onto the carrier substrate, and an electrode unit disposed between the carrier substrate and the flip-chip LED. The electrode unit includes first and second connecting electrodes that have opposite conductivity. Each of the first and second connecting electrodes includes an intermediate metal layer and a binding layer that are sequentially disposed on the flip-chip LED in such order. The binding layer includes a first portion being adjacent to the carrier substrate and forming an eutectic system with tin, and a second portion located between the first portion and the intermediate metal layer.

A stacked semiconductor device encompasses a mother-plate having a mounting-main surface and a bottom-main surface, an onboard-element having a connection face facing to the mounting-main surface, a parent bump provided on the mother-plate, having a mother-site wall made of a layer of conductor, mother-site wall is perpendicular to the mounting-main surface, and a repair bump provided on the onboard-element at a side of the connection face, having a repair-site wall made of a layer of conductor having different hardness from the mother-site wall, the repair-site wall is perpendicular to the connection face, configure to bite each other with the parent bump at an intersection between the mother-site wall and the repair-site wall conductor.

A chip package structure is provided. The chip package structure includes a redistribution structure and a first chip structure over the redistribution structure. The chip package structure also includes a first solder bump between the redistribution structure and the first chip structure and a first molding layer surrounding the first chip structure. The chip package structure further includes a second chip structure over the first chip structure and a second molding layer surrounding the second chip structure. In addition, the chip package structure includes a third molding layer surrounding the first molding layer, the second molding layer, and the first solder bump. A portion of the third molding layer is between the first molding layer and the redistribution structure.