Abstract: A method of predicting a temperature includes operatively coupling a temperature prediction circuit to a device including a semiconductor chip, determining a correlation between a current and voltage of the temperature prediction circuit, and predicting a temperature with respect to power applied to the device using the determined correlation.

Abstract: Methods of fabricating semiconductor packages are provided. One of the methods includes forming a protection layer including metal on a first surface of a substrate to cover a semiconductor device disposed on the first surface of the substrate, attaching a support substrate to the protection layer by using an adhesive member, processing a second surface of the substrate opposite to the protection layer to remove a part of the substrate, and detaching the support substrate from the substrate.

Abstract: A semiconductor device, a semiconductor package, and a package stack structure include a semiconductor substrate, a first bonding pad disposed on a first surface of the semiconductor substrate, and a first pillar disposed on the first bonding pad. An upper surface of the first pillar has a concave shape. Side surfaces of the first pillar are substantially planar.

Abstract: A photonic integrated circuit is provided. The photonic integrated circuit includes a substrate having a through hole interconnecting a first surface and a second surface; a transmission wire passing through the through hole and including an optical transmission structure and an electrical transmission structure; and an optical-to-electrical converter connected to the optical transmission structure of the transmission wire on the first surface.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate having a first surface, and a second surface opposite to the first surface. The second surface defines a redistribution trench. The substrate has a via hole extending therethrough. The semiconductor device also includes a through via disposed in the via hole. The through via may include a via hole insulating layer, a barrier layer, sequentially formed on an inner wall of the via hole. The through via may further include a conductive connector adjacent the barrier layer. The semiconductor device additionally includes an insulation layer pattern formed on the second surface of the substrate. The insulation layer pattern defines an opening that exposes a region of a top surface of the through via. The semiconductor devices includes a redistribution layer disposed in the trench and electrically connected to the through via. The insulation layer pattern overlaps a region of the conductive connector.

Abstract: Embodiments of the inventive aspect include a method of manufacturing a semiconductor package including a plurality of stacked semiconductor chips in which edges of a semiconductor wafer substrate may be prevented from being damaged or cracked when the semiconductor package is manufactured at a wafer level, while a diameter of a molding element is greater than a diameter of the semiconductor wafer substrate. The molding element may cover a surface of the wafer substrate and the plurality of stacked semiconductor chips. Embodiments may include a wafer level semiconductor package including a circular substrate having a first diameter, a circular passivation layer attached to the circular substrate, the passivation layer having the first diameter, and a circular molding element covering surfaces of the plurality of semiconductor chips, and covering an active area of the substrate. The circular molding element may have a second diameter that is greater than the first diameter.

Abstract: A semiconductor package having an upper surface, a lower surface, and at least one side surface is provided. The semiconductor package includes a mold member disposed on the upper surface and at least one side surface of a semiconductor chip included in the semiconductor package. A marking pattern in the semiconductor package having information about the semiconductor chip is formed on at least one side surface of the mold member.

Abstract: A non-conductive material layer, selected from a non-conductive film and a non-conductive polymer paste, and containing a dispersion of zinc (Zn) particles is disclosed, together with semiconductor packages including the non-conductive material layer. The non-conductive material layer contains zinc (Zn) particles having an average particle diameter of about 1 nm to about 200 nm in a non-conductive polymer base material of a film type, and a semiconductor package includes the non-conductive film. By using the non-conductive film and/or the non-conductive paste containing the zinc dispersion, e a semiconductor package having excellent electric connection properties and high reliability may be manufactured through simple processes at low manufacturing costs.

Abstract: Provided are semiconductor packages having through electrodes and methods of fabricating the same. The method may include may include forming a wafer-level package including first semiconductor chips stacked on a second semiconductor chip, forming a chip-level package including fourth semiconductor chips stacked on a third semiconductor chip stacking a plurality of the chip-level packages on a back surface of the second semiconductor substrate of the wafer-level package, polishing the first mold layer of the wafer-level package and the first semiconductor chips to expose a first through electrodes of the first semiconductor chip, and forming outer electrodes on the polished first semiconductor chips to be connected to the first through electrodes, respectively.

Abstract: Methods of fabricating semiconductor packages are provided. One of the methods includes forming a protection layer including metal on a first surface of a substrate to cover a semiconductor device disposed on the first surface of the substrate, attaching a support substrate to the protection layer by using an adhesive member, processing a second surface of the substrate opposite to the protection layer to remove a part of the substrate, and detaching the support substrate from the substrate.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate having a first surface, and a second surface opposite to the first surface. The second surface defines a redistribution trench. The substrate has a via hole extending therethrough. The semiconductor device also includes a through via disposed in the via hole. The through via may include a via hole insulating layer, a barrier layer, sequentially formed on an inner wall of the via hole. The through via may further include a conductive connector adjacent the barrier layer. The semiconductor device additionally includes an insulation layer pattern formed on the second surface of the substrate. The insulation layer pattern defines an opening that exposes a region of a top surface of the through via. The semiconductor devices includes a redistribution layer disposed in the trench and electrically connected to the through via. The insulation layer pattern overlaps a region of the conductive connector.

Abstract: In one embodiment, a semiconductor package includes a circuit substrate, a plurality of semiconductor chips stacked on the circuit substrate, insulating adhesive patterns interposed between the semiconductor chips, a heat slug provided on an uppermost semiconductor chip and adhered to the uppermost semiconductor chip by a heat dissipative adhesive pattern, and a mold structure provided on the circuit substrate to cover sidewalls of the semiconductor chips, the insulating adhesive patterns, the heat dissipative adhesive pattern and the heat slug. A failure of the semiconductor package during a manufacturing process of the mold structure may be reduced. The semiconductor package may therefore have good operating characteristics and reliability.

Abstract: Provided are an initiator and a method for debonding a wafer supporting system. The initiator for debonding a wafer supporting system includes a rotation chuck having an upper surface on which a wafer supporting system (WSS), which includes a carrier wafer, a device wafer, and a glue layer for bonding the carrier wafer and the device wafer to each other, is seated to rotate the wafer supporting system, a detecting module detecting a height and a thickness of the glue layer and a laser module generating a fracture portion on the glue layer through irradiating a side surface of the glue layer with a laser on the basis of the height and the thickness of the glue layer.

Abstract: A semiconductor package includes a package base substrate, at least one first semiconductor chip disposed on the package base substrate, and at least one stacked semiconductor chip structure disposed on the package base substrate adjacent to the at least one first semiconductor chip. The at least one stacked semiconductor chip includes a plurality of second semiconductor chips. A penetrating electrode region including a plurality of penetrating electrodes is disposed adjacent to an edge of the at least one stacked semiconductor chip structure.

Abstract: A retainer for a wafer carrier comprising: a body including a plurality of slots configured to receive side surfaces of wafers; and for each of the slots, a supporting structure formed on a sidewall of the slot and configured to make contact with the side surfaces of a corresponding wafer, the supporting structure being spaced apart from an upper corner of the side surface of the corresponding wafer.

Abstract: Provided are semiconductor packages having through electrodes and methods of fabricating the same. The method may include may include forming a wafer-level package including first semiconductor chips stacked on a second semiconductor chip, forming a chip-level package including fourth semiconductor chips stacked on a third semiconductor chip stacking a plurality of the chip-level packages on a back surface of the second semiconductor substrate of the wafer-level package, polishing the first mold layer of the wafer-level package and the first semiconductor chips to expose a first through electrodes of the first semiconductor chip, and forming outer electrodes on the polished first semiconductor chips to be connected to the first through electrodes, respectively.

Abstract: Semiconductor devices and methods for manufacturing a semiconductor device include a first semiconductor substrate in which a first scribe line region and a first chip region are defined, a first alignment mark inside the first semiconductor substrate and in the first scribe line region so as to be spaced apart from an upper side of the first semiconductor substrate, a second semiconductor substrate on the first semiconductor substrate and in which a second scribe line region and a second chip region are defined, and a second alignment mark inside the second semiconductor substrate and in the second scribe line region so as to be spaced apart from an upper side of the second semiconductor substrate, wherein the second semiconductor substrate is on the first semiconductor substrate so that positions of the first alignment mark and the second alignment mark correspond to each other.

Abstract: A semiconductor device, a semiconductor package, and a package stack structure include a semiconductor substrate, a first bonding pad disposed on a first surface of the semiconductor substrate, and a first pillar disposed on the first bonding pad. An upper surface of the first pillar has a concave shape. Side surfaces of the first pillar are substantially planar.

Abstract: A method of manufacturing a semiconductor package includes forming a bonding layer on a carrier substrate, bonding an inner substrate to the carrier substrate, removing the carrier substrate, and forming a gap-filling portion by removing a portion of the bonding layer to expose a portion of a solder ball provided in the inner substrate. The inner substrate may be mounted on a package substrate and a semiconductor chip may be mounted on the inner substrate.

Abstract: Embodiments of the inventive aspect include a method of manufacturing a semiconductor package including a plurality of stacked semiconductor chips in which edges of a semiconductor wafer substrate may be prevented from being damaged or cracked when the semiconductor package is manufactured at a wafer level, while a diameter of a molding element is greater than a diameter of the semiconductor wafer substrate. The molding element may cover a surface of the wafer substrate and the plurality of stacked semiconductor chips. Embodiments may include a wafer level semiconductor package including a circular substrate having a first diameter, a circular passivation layer attached to the circular substrate, the passivation layer having the first diameter, and a circular molding element covering surfaces of the plurality of semiconductor chips, and covering an active area of the substrate. The circular molding element may have a second diameter that is greater than the first diameter.