A die stack structure including a first die, an encapsulant, a redistribution layer and a second die is provided. The encapsulant laterally encapsulates the first die. The redistribution layer is disposed below the encapsulant, and electrically connected with the first die. The second die is disposed between the redistribution layer and the first die, wherein the first and second dies are electrically connected with each other, the second die comprises a body portion having a first side surface, a second side surface and a curved side surface therebetween, and the curved side surface connects the first side surface and the second side surface.

A chip package includes a semiconductor substrate, a supporting element, an antenna layer, and a redistribution layer. The semiconductor substrate has an inclined sidewall and a conductive pad that protrudes from the inclined sidewall. The supporting element is located on the semiconductor substrate, and has a top surface facing away from the semiconductor substrate, and has an inclined sidewall adjoining the top surface. The antenna layer is located on the top surface of the supporting element. The redistribution layer is located on the inclined sidewall of the supporting element, and is in contact with a sidewall of the conductive pad and an end of the antenna.

Implementations of a method of forming a semiconductor package may include forming a plurality of notches into the first side of a semiconductor substrate; forming an organic material over the first side of the semiconductor substrate and into the plurality of notches; forming a cavity into each of a plurality of semiconductor die included in the semiconductor substrate; applying a backmetal into the cavity in each of the plurality of semiconductor die included in the semiconductor substrate; and singulating the semiconductor substrate through the organic material into a plurality of semiconductor packages.

A semiconductor structure and a manufacturing method thereof are provided. The semiconductor structure for optically coupling a fiber includes a photonic die, an electronic die disposed on and electrically coupled to the photonic die, and an insulating layer disposed on the photonic die and extending along sidewalls of the electronic die. The photonic die includes a first portion and a second portion connected to the first portion, an optical device of the photonic die optically coupled to the fiber is within the first portion, and the second portion extends beyond lateral extents of the first portion.

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.

A package structure including an organic interposer substrate, a semiconductor die, conductive bumps, an underfill, and an insulating encapsulation is provided. The organic interposer substrate includes stacked organic dielectric layers and conductive wirings embedded in the stacked organic dielectric layers. The semiconductor die is disposed over and electrically connected to the conductive wirings of the organic interposer substrate, and the semiconductor die includes chamfered edges. The conductive bumps are disposed between the semiconductor die and the organic interposer substrate, and the semiconductor die is electrically connected to the organic interposer substrate through the conductive bumps. The underfill is disposed between the semiconductor die and the organic interposer substrate, wherein the underfill encapsulates the conductive bumps and is in contact with the chamfered edges of the at least one semiconductor die. The insulating encapsulation covers the organic interposer substrate and laterally encapsulates the least one semiconductor die and the underfill.

A semiconductor device comprises a first chip and a second chip bonded via a plurality of bonding electrodes. The first chip comprises: a first substrate; a first semiconductor element; and a first bonding electrode which is one of the plurality of bonding electrodes and is electrically connected to the first semiconductor element. The second chip comprises: a second substrate; a second semiconductor element; and a second bonding electrode which is one of the plurality of bonding electrodes and is electrically connected to the second semiconductor element. The second substrate comprises: a pair of first regions which are provided in both end portions; and a pair of second regions which are provided in both end portions. Viewed from a third direction, portions provided in the first region and the second region of the second substrate do not overlap the first substrate.

A method comprises the steps of providing a wafer; applying a redistribution layer, grinding a back side of the wafer; depositing a metal layer; and applying a singulation process. A semiconductor package comprises a metal-oxide-semiconductor field-effect transistor (MOSFET), a redistribution layer, and a metal layer. The MOSFET comprises a source electrode, a gate electrode, a drain electrode and a plurality of partial drain plugs. The source electrode, the gate electrode, and the drain electrode are positioned at a front side of the MOSFET.

A semiconductor device according to the invention of the present application includes a support, a semiconductor chip provided on the support and a die bond material for bonding a back surface of the semiconductor chip to the support, wherein a plurality of cutouts is formed at edges formed between the back surface and side surfaces of the semiconductor chip connected to the back surface, and the die bond material is provided integrally over the plurality of cutouts.

An electronic device is provided, the electronic device includes a driving substrate, the driving substrate includes a plurality of circular grooves and a plurality of rectangular grooves, a plurality of disc-shaped light-emitting units, at least one disc-shaped light-emitting unit is disposed in at least one circular groove, and the at least one disc-shaped light-emitting unit includes an alignment element positioned on a top surface of the at least one disc-shaped light-emitting unit, a diameter of the at least one disc-shaped light-emitting unit is defined as R, a diameter of the alignment element is defined as r, a width of at least one rectangular groove among the rectangular grooves is defined as w, and a height of the at least one rectangular groove is defined as H, and the at least one disc-shaped light-emitting unit and the at least one rectangular groove satisfy the condition of (R+r)/2>(w.sup.2+H.sup.2).sup.1/2.