Some embodiments include ferroelectric assemblies. Some embodiments include a capacitor which has ferroelectric insulative material between a first electrode and a second electrode. The capacitor also has a metal oxide between the second electrode and the ferroelectric insulative material. The metal oxide has a thickness of less than or equal to about 30 Å. Some embodiments include a method of forming an assembly. A first capacitor electrode is formed over a semiconductor-containing base. Ferroelectric insulative material is formed over the first electrode. A metal-containing material is formed over the ferroelectric insulative material. The metal-containing material is oxidized to form a metal oxide from the metal-containing material. A second electrode is formed over the metal oxide.

A method for fabricating a capacitor includes forming a first electrode, forming a dielectric layer stack on the first electrode, the dielectric layer stack including an initial hafnium oxide layer and a seed layer having a doping layer embedded therein, forming a thermal source layer on the dielectric layer stack to crystallize the initial hafnium oxide into tetragonal hafnium oxide, and forming a second electrode on the thermal source layer.

A resistor circuit, an artificial intelligence chip and a method for manufacturing the same are provided. The resistor circuit includes a stack structure. The stack structure includes resistive material layers and insulating layers stacked alternately. The resistor circuit includes at least two unit resistors electrically connected in series or parallel. The at least two unit resistors are respectively defined in the resistive material layers of different layers.

The present disclosure relates to a semiconductor device and a fabrication method thereof. The semiconductor device includes a substrate, a first nitride semiconductor layer disposed on the substrate, a second nitride semiconductor layer disposed on the first nitride semiconductor layer and having a bandgap greater than that of the first nitride semiconductor layer. The semiconductor device further includes a first gate conductor disposed on a first region of the second nitride semiconductor layer, a passivation layer covering the first gate conductor, and a second gate conductor disposed on the passivation layer and on a second region of the second nitride semiconductor layer, wherein the first region is laterally spaced apart from the second region.

The disclosure relates to a semiconductor die, including a vertical power transistor device, a pull-down transistor device, and a capacitor. The pull-down transistor device is connected between a gate electrode of the vertical power transistor device and a ground terminal and connects the gate electrode to the ground terminal in a conducting state. The capacitor is connected between one of the load terminals of the vertical power transistor device and the control terminal of the pull-down transistor device and capacitively couples the one load terminal to the control terminal.

A semiconductor device is provided that includes a substrate 10 with first and second opposing main surfaces, a circuit layer disposed on the first main surface, and a first resin body on a surface of the circuit layer opposite from the substrate. The circuit layer includes first and second electrode layers on a side of the semiconductor substrate, a dielectric layer disposed between the electrode layers, a first outer electrode electrically connected to the first electrode layer and extended to the surface of the circuit layer, and a second outer electrode electrically connected to the second electrode layer and extended to the surface of the circuit layer. The first resin body is between the first and second outer electrodes in a plan view, and in sectional view, a tip end of the first resin body is positioned higher than tip ends of the first and second outer electrodes.

The disclosure relates to integrated circuits and methods of manufacture. A method involves forming a first set of one or more circuit layers on a semiconductor substrate, placing at least one prefabricated layer portion onto the first set of circuit layers to form a component, and forming a second set of one or more circuit layers over the first set of circuit layers and the at least prefabricated layer portion. The prefabricated layer portion may be a magnetic layer portion placed to form a magnetic component such as a magnetic core of an inductor or transformer. The method may also comprise forming the prefabricated layer portion.

Deep trench capacitors (DTCs) in an inter-layer medium (ILM) on an interconnect layer of an integrated circuit (IC) die is disclosed. A method of fabricating an IC die comprising DTCs in the ILM is also disclosed. The DTCs are disposed on an IC, in an ILM, to minimize the lengths of the power and ground traces coupling the DTCs to circuits in a semiconductor layer. The DTCs and the semiconductor layer are on opposite sides of the metal layer(s) used to interconnect the circuits, so the locations of the DTCs in the ILM can be independent of circuit layout and interconnect routing. IC dies with DTCs disposed in the ILM can significantly reduce voltage droop and spikes in IC dies in an IC stack. In one example, DTCs are also located in trenches in the substrate of the IC die.

A method for fabricating an electrical or electronic device package includes providing a first plateable encapsulation layer; activating first selective areas on a main surface of the first plateable encapsulation layer; forming a first metallization layer by electrolytic or electroless plating on the first activated areas; and fabricating a passive electrical component on the basis of the first metallization layer.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a first die in a first dielectric layer; a magnetic core inductor, having a first surface and an opposing second surface, in the first dielectric layer, including a first conductive pillar, having a first end at the first surface of the magnetic core inductor and an opposing second end at the second surface, at least partially surrounded by a magnetic material that extends at least partially along a thickness of the first conductive pillar from the second end and tapers towards the first end; and a second conductive pillar coupled to the first conductive pillar; and a second die in a second dielectric layer on the first dielectric layer coupled to the second surface of the magnetic core inductor.