A semiconductor device includes a first interconnect structure over first substrate, a first bonding layer over the first interconnect structure, multiple first bonding pads disposed in a first region of the first bonding layer, the first bonding pads having a first pitch, and multiple second bonding pads disposed in a second region of the first bonding layer, the second region extending between a first edge of the first bonding layer and the first region, the second bonding pads having the first pitch, the multiple second bonding pads including multiple pairs of adjacent second bonding pads, wherein the second bonding pads of each respective pair are connected by a first metal line.

The disclosure provides a chip and a display module with the same. The chip comprises a body, wherein the body is provided with a plurality of junctions which are arranged at intervals in a first direction, at least one junction comprises a first sub junction and a second sub junction which are arranged in a second direction and formed into an integrated structure, a width of the first sub junction is greater than a width of the second sub junction in the first direction, and the second direction is perpendicular to the first direction.

The semiconductor device has the CSP structure, and may include a plurality of electrode pads formed on a semiconductor integrated circuit in order to input/output signals from/to exterior; solder bumps for making external lead electrodes; and rewiring. The solder bumps may be arranged in two rows along the periphery of the semiconductor device. The electrode pads may be arranged inside the outermost solder bumps so as to be interposed between the two rows of solder bumps. Each trace of the rewiring may be extended from an electrode pad, and may be connected to any one of the outermost solder bumps or any one of the inner solder bumps.

An electronic module includes a substrate that includes a first main surface and a second main surface, at least one first electronic component that includes electrodes on a mounting surface thereof on the substrate and that includes a hollow portion, at least one second electronic component that includes electrodes on a mounting surface thereof on the substrate and that includes no hollow portion, and a sealing resin. The at least one first electronic component is mounted on the first main surface of the substrate and sealed with the sealing resin. The at least one second electronic component is mounted on the second main surface of the substrate and is not sealed with the sealing resin.

A semiconductor device, an integrated fan-out package and a method of forming the same are disclosed. In some embodiments, a semiconductor device includes a substrate, a conductive layer, a passivation layer and a bump structure. The substrate has at least one electronic component therein. The conductive layer has a plurality of lines patterns over and electrically connected to the at least one electronic component. The passivation layer is over the conductive layer. The bump structure has a plurality of protruding parts penetrating through the passivation layer and electrically connected to the lines patterns of the conductive layer.

The present application discloses a semiconductor device with slanted conductive layers and a method for fabricating the semiconductor device with the slanted conductive layers. The semiconductor device includes a substrate, a first insulating layer positioned above the substrate, first slanted conductive layers positioned in the first insulating layer, and a top conductive layer positioned covering the first slanted conductive layers.

The present application discloses a semiconductor device with slanted conductive layers and a method for fabricating the semiconductor device with the slanted conductive layers. The semiconductor device includes a substrate, a first insulating layer positioned above the substrate, first slanted conductive layers positioned in the first insulating layer, and a top conductive layer positioned covering the first slanted conductive layers.

A semiconductor device includes: a semiconductor element having an element main surface and an element back surface spaced apart from each other in a thickness direction, and including a plurality of main surface electrodes arranged on the element main surface; a die pad on which the semiconductor element is mounted; a plurality of leads including at least one first lead arranged on one side in a first direction orthogonal to the thickness direction with respect to the die pad, and arranged around the die pad when viewed in the thickness direction; a plurality of connecting members including a first connecting member, and configured to electrically connect the plurality of main surface electrodes and the plurality of leads; and a resin member configured to seal the semiconductor element, a part of the die pad, parts of the plurality of leads, and the plurality of connecting members.

A semiconductor device includes: a semiconductor element having an element main surface and an element back surface spaced apart from each other in a thickness direction and including a plurality of main surface electrodes arranged on the element main surface; a die pad on which the semiconductor element is mounted; a plurality of leads including at least one first lead and at least one second lead and arranged around the die pad when viewed in the thickness direction; a plurality of connecting members including a first connecting member and a second connecting member and configured to electrically connect the plurality of main surface electrodes and the plurality of leads; and a resin member configured to seal the semiconductor element, a part of the die pad, parts of the plurality of leads, and the plurality of connecting members and having a rectangular shape when viewed in the thickness direction.

Provided is a method of fabricating a hybrid element, the method including forming a plurality of first elements on a first substrate, separating a plurality of second elements grown on a second substrate from the second substrate, a material of the second substrate being different from a material of the first substrate, and transferring the plurality of second elements, separated from the second substrate, onto the first substrate, wherein, in the transferring, the plurality of second elements are spaced apart from each other by a fluidic self-assembly method, and wherein each of the plurality of second elements includes a shuttle layer grown on the second substrate, an element layer grown on the shuttle layer, and an electrode layer on the element layer.