Aspects include a method of fabricating a semiconductor structure including providing a semiconductor layer, scribing the semiconductor layer to provide one or more scribe lines, disposing a flexible support layer on the semiconductor layer, and applying a force to the scribed semiconductor layer so as to induce cracks along the scribe lines.

Integrated circuit devices and methods of forming the same are provided. A method according to the present disclosure includes providing a workpiece including a semiconductor substrate, a first ILD layer over the semiconductor substrate, and a first metal feature in the first ILD layer; depositing a second metal feature over the workpiece such that the second metal feature is electrically coupled to the first metal feature; patterning the second metal feature to form a first trench adjacent to the first metal feature; depositing a blocking layer over the workpiece, wherein the blocking layer selectively attaches to the first ILD layer; depositing a barrier layer over the workpiece, wherein the barrier layer selectively forms over the second metal feature relative to the first ILD layer; and depositing a second ILD layer over the workpiece.

A semiconductor device package and a method for manufacturing the same are provided. The semiconductor device package includes a circuit layer and an antenna module. The circuit layer has a first surface, a second surface opposite to the first surface and a lateral surface. The lateral surface extends between the first surface and the second surface. The circuit layer has an interconnection structure. The antenna module has an antenna pattern layer and is disposed on the first surface of the circuit layer. The lateral surface of the circuit layer is substantially coplanar with a lateral surface of the antenna module.

There is provided a solid-state imaging device including: a first substrate including a first semiconductor substrate and a first wiring layer, the first semiconductor substrate having a pixel unit with pixels; a second substrate including a second semiconductor substrate and a second wiring layer, the second semiconductor substrate having a circuit with a predetermined function; and a third substrate including a third semiconductor substrate and a third wiring layer, the third semiconductor substrate having a circuit with a predetermined function, the first, second, and third substrates being stacked in this order, the first substrate and the second substrate being bonded together with the first wiring layer and the second wiring layer opposed to each other, a first coupling structure on bonding surfaces of the first substrate and the second substrate, and including an electrode junction structure with electrodes formed on the respective bonding surfaces in direct contact with each other.

A thin film transistor, a manufacturing method thereof, an array substrate, and a display panel are provided. The thin film transistor includes a semiconductor layer, a source and a drain. The semiconductor layer includes an active layer and a superhydrophobic layer. The active layer includes a source contact, a drain contact and a channel portion. The source corresponds to the source contact, and the drain corresponds to the drain contact. The superhydrophobic layer is disposed on a surface of the active layer proximal to the source and the drain. The superhydrophobic layer includes a plurality of multi-level nanostructures protruding from the surface of the active layer, and the superhydrophobic layer at least covers a channel portion of the active layer.

Implementations of a silicon-on-insulator (SOI) die may include a silicon layer including a first side and a second side, and an insulative layer coupled directly to the second side of the silicon layer. The insulative layer may not be coupled to any other silicon layer.

Implementations of a silicon-on-insulator (SOI) die may include a silicon layer including a first side and a second side, and an insulative layer coupled directly to the second side of the silicon layer. The insulative layer may not be coupled to any other silicon layer.

Die-substrate assemblies having sinter-bonded backside via structures, and methods for fabricating such die-substrate assemblies, are disclosed. In embodiments, the method includes obtaining an integrated circuit (IC) die having a backside over which a backmetal layer is formed and into which a plated backside via extends. The IC die is attached to an electrically-conductive substrate by: (i) applying sinter precursor material over the backmetal layer and into the plated backside via; (ii) positioning a frontside of the electrically-conductive substrate adjacent the plated backmetal layer and in contact with the sinter precursor material; and (iii) sintering the sinter precursor material to yield a sintered bond layer attaching and electrically coupling the IC die to the frontside of the electrically-conductive substrate through the backmetal layer and through the plated backside via. The sintered bond layer contacts and is metallurgically bonded to the backside via lining.

To more reliably suppress deterioration in characteristics due to signals (distortions) other than input and output waves while suppressing manufacturing cost. A semiconductor device according to the present disclosure includes a circuit substrate including an insulating film layer located above a predetermined semiconductor substrate and a semiconductor layer located above the insulating film layer, a plurality of passive elements provided on the circuit substrate and electrically connected with one another, and an electromagnetic shield layer locally provided in the insulating film layer corresponding to a portion where at least one of the plurality of passive elements is provided, and the electromagnetic shield layer and the semiconductor substrate are electrically separated from each other.

To more reliably suppress deterioration in characteristics due to signals (distortions) other than input and output waves while suppressing manufacturing cost. A semiconductor device according to the present disclosure includes a circuit substrate including an insulating film layer located above a predetermined semiconductor substrate and a semiconductor layer located above the insulating film layer, a plurality of passive elements provided on the circuit substrate and electrically connected with one another, and an electromagnetic shield layer locally provided in the insulating film layer corresponding to a portion where at least one of the plurality of passive elements is provided, and the electromagnetic shield layer and the semiconductor substrate are electrically separated from each other.