A 3D semiconductor device including: a first level including a plurality of first metal layers; a second level, where the second level overlays the first level, where the second level includes at least one single crystal silicon layer, where the second level includes a plurality of transistors, where each transistor of the plurality of transistors includes a single crystal channel, where the second level includes a plurality of second metal layers, where the plurality of second metal layers include interconnections between the transistors of the plurality of transistors, and where the second level is overlaid by a first isolation layer; and a connective path between the plurality of transistors and the plurality of first metal layers, where the connective path includes a via disposed through at least the single crystal silicon layer, and where the via includes contact with at least one of the plurality of transistors.

A fan-out wafer-level package comprising at least one integrated circuit, an internal heat spreader thermally connected to the integrated circuit either directly or via an interface layer having a thickness in sub-μm range preferably in the range of 20 nm to 500 nm, wherein the internal heat spreader is embedded in the fan-out wafer-level package.

According to an aspect of the present disclosure, a display device includes a substrate including a display area in which a plurality of sub-pixels are disposed, and a non-display area. The display device includes a plurality of signal lines extending from the display area to the non-display area and configured to transmit an alternating current voltage. The display device includes a semiconductor layer disposed between the substrate and the plurality of signal lines and overlapping the plurality of signal lines.

A semiconductor package includes a base film, a semiconductor die on the base film, metal studs on the semiconductor die, shielding pillars on the base film and around the semiconductor die, a first molding compound encapsulating the semiconductor die, the metal studs, and the shielding pillars, a first re-distribution structure on the first molding compound, a second molding compound on the first re-distribution structure, through-mold-vias in the second molding compound, and a second re-distribution structure on the second molding compound and electrically connected to the through-mold-vias. The second re-distribution structure comprises an antenna.

A semiconductor device, the device comprising: a plurality of transistors, wherein at least one of said plurality of transistors comprises a first single crystal source, channel, and drain, wherein at least one of said plurality of transistors comprises a second single crystal source, channel, and drain, wherein said second single crystal source, channel, and drain is disposed above said first single crystal source, channel, and drain, wherein at least one of said plurality of transistors comprises a third single crystal source, channel, and drain, wherein said third single crystal source, channel, and drain is disposed above said second single crystal source, channel, and drain, wherein at least one of said plurality of transistors comprises a fourth single crystal source, channel, and drain, and wherein said third single crystal channel is self-aligned to said fourth single crystal channel being processed following the same lithography step.

A semiconductor device, the device including: a first level including control circuits, where the control circuits include a plurality of first transistors and a plurality of metal layers; and a memory level disposed on top of the first level, where the memory level includes an array of memory cells, where each of the memory cells includes at least one second transistor, where the control circuits control access to the array of memory cells, where the first level is bonded to the memory level, where the bonded includes oxide to oxide bonding regions and a plurality of metal to metal bonding regions, and where at least a portion of the array of memory cells is disposed directly above at least one of the plurality of metal to metal bonding regions.

This invention relates to an exfoliation layer composed of a cationic polymer electrolyte or organosilane and negatively charged phyllosilicate sheet-shaped nanoparticles, and to a method of manufacturing the exfoliation layer, including a) negatively charging the surface of a substrate, b) applying a cationic polymer electrolyte or performing a silanization process, and c) negatively charging and applying phyllosilicate. Since the exfoliation layer of the invention has an effect of reducing bonding force due to the sheet-shaped nanoparticles therein, the exfoliation layer enables a flexible display to be temporarily fixed on a supporting substrate upon fabrication of the flexible display and to then be easily separated after the completion of the fabrication thereof.

A semiconductor package including a redistribution substrate with a first insulating layer, one or more second insulating layers on the first insulating layer, and a plurality of redistribution layers. The first insulating layer includes a first photosensitive resin having an elongation of 60% or more and toughness of 70 mJ/mm.sup.3 or more. The one or more second insulating layers include a second photosensitive resin having an elongation in a range of 10% to 40% and toughness of 40 mJ/mm.sup.3.

A flexible board is disclosed. The flexible board comprises a flexible baseplate, a scattering structure that is arranged on at least one surface of the flexible baseplate, a buffer layer that is arranged at one side of the scattering structure far from the flexible baseplate, and an active layer that is arranged at one side of the buffer layer far from the flexible baseplate. The flexible board according to the present disclosure has an apparent advantage in protecting the active layer.

The present invention provides processes for manufacturing a plurality of discrete integrated circuits (ICs) on a carrier, the process comprising the steps of: providing a carrier for a flexible substrate; depositing a flexible substrate of uniform thickness on said carrier; removing at least a portion of the thickness of the flexible substrate from at least a portion of the IC connecting areas to form channels in the flexible substrate and a plurality of IC substrate units spaced apart from one another on the carrier by said channels; forming an integrated circuit on at least one of the IC substrate units.