A switching device including a GaN substrate; an unintentionally doped GaN layer on a first surface of the GaN substrate; a regrown unintentionally doped GaN layer on the unintentionally doped GaN layer; a regrowth interface between the unintentionally doped GaN layer and the regrown unintentionally doped GaN layer; a p-GaN layer on the regrown unintentionally doped GaN layer; a first electrode on the p-GaN layer; and a second electrode on a second surface of the GaN substrate.

A new liner structure for improving memory cell design is disclosed that incorporates a boron nitride dielectric layer. An example memory device includes an array of memory cells with each of at least some of the memory cells having a stack of layers, the stack comprising at least one phase change layer. A dielectric layer is provisioned over one or more sidewalls of at least the phase change layer. The dielectric layer comprises both nitrogen and boron. The dielectric layer may be part of a liner structure that includes multiple layers, such as an alternating layer stack of boron nitride and silicon nitride. The dielectric layer can be deposited at low temperature (e.g., less than about 300° C.) while maintaining a low hydrogen content and a relatively high thermal conductivity.

A method for fabricating stacked resistive memory with individual switch control is provided. The method includes forming a first random access memory (ReRAM) device. The method further includes forming a second ReRAM device in a stacked nanosheet configuration on the first ReRAM device. The method also includes forming separate gate contacts for the first ReRAM device and the second ReRAM device.

A memory device includes first to nth decks respectively coupled to first to nth row lines which are stacked over a substrate in a vertical direction perpendicular to a surface of the substrate, n being a positive integer, a first connection structure extending from the substrate in the vertical direction to be coupled to the first row line, even-numbered connection structures extending from the substrate in the vertical direction and respectively coupled to ends of even-numbered row lines among the second to nth row lines, and odd-numbered connection structures extending from the substrate in the vertical direction and respectively coupled to ends of odd-numbered row lines among the second to nth row lines. The even-numbered connection structures are spaced apart from the odd-numbered connection structures with the first row line and the first connection structure that are interposed between the even-numbered connection structures and the odd-numbered connection structures.

A method for manufacturing a nonvolatile semiconductor storage device includes: forming a first conductive layer by self-alignment on a first wiring layer, and performing an annealing processing; stacking a first stacked film on the first conductive layer; processing the first stacked film, the first conductive layer, and the first wiring layer into a stripe structure extending in a first direction; forming and planarizing a first interlayer insulating film; forming a second wiring layer; forming a second conductive layer by self-alignment on the second wiring layer, and performing an annealing processing; processing the second wiring layer and the second conductive layer into a stripe structure extending in a second direction intersecting the first direction; and processing the first stacked film and the first interlayer insulating film below and between the second wiring layer, and forming a first memory cell having the first stacked film in a columnar shape.

Disclosed is a reconfigurable transistor device having a substrate, a plurality of first transistor fingers disposed in a first region over the substrate, and a phase change switch (PCS) having a patch of a phase change material (PCM) disposed over the substrate in a second region to selectively couple a first set of the plurality of first transistor fingers to a bus, wherein the patch of the PCM is electrically insulating in an amorphous state and electrically conductive in a crystalline state. The PCS further includes a thermal element disposed adjacent to the patch of PCM, wherein the first thermal element is configured to maintain the patch of the PCM to within a first temperature range until the patch of the PCM converts to the amorphous state and maintain the patch of the PCM within a second temperature range until the first patch of PCM converts to the crystalline state.

IC devices with stacked backend memory with resistive switching devices are disclosed. An example IC device includes a support structure, a frontend layer with a plurality of frontend devices, and a backend layer with a plurality of resistive switching devices, the resistive switching devices being, e.g., part of memory cells of stacked backend memory. For example, the backend layer may implement stacked arrays of 1T-1RSD memory cells, with resistive switching devices coupled to some S/D regions of access transistors of the memory cells. Such memory cells may be used to implement stacked eMRAM or eRRAM, with access transistors being TFTs. Stacked TFT-based eMRAM or eRRAM as described herein may help increase density of MRAM or RRAM cells, hide the peripheral circuits that control the memory operation below the memory arrays, and address the scaling challenge of some conventional memory technologies.

Semiconductor structures and methods for manufacturing the same are provided. The semiconductor structure includes an interconnect structure and an electrode layer formed over the interconnect structure. The semiconductor structure also includes a gate dielectric layer formed over the electrode layer and an oxide semiconductor layer formed over the gate dielectric layer. The semiconductor structure also includes an indium-containing feature covering a surface of the oxide semiconductor layer and a source/drain contact formed over the indium-containing feature.

A semiconductor storage device includes a memory cell including a core portion that extends in a first direction above a semiconductor substrate; a variable resistance layer that extends in the first direction and is in contact with the core portion; a semiconductor layer that extends in the first direction and is in contact with the variable resistance layer; a first insulator layer that extends in the first direction and is in contact with the semiconductor layer; and a first voltage applying electrode that extends in a second direction orthogonal to the first direction and is in contact with the first insulator layer. The core portion is a vacuum region, or a region containing inert gas.

Subject matter disclosed herein relates to an integrated circuit device having a socket interconnect region for connecting a plurality of conductive lines at a first vertical level to interconnect structures formed at a second vertical level different from the first vertical level. The conductive lines include a plurality of contacted lines that are vertically connected to the interconnect structures at the socket interconnect region, a plurality of terminating lines terminating at the socket interconnect region, and a plurality of pass-through lines that pass through the socket interconnect region without being vertically connected and without being terminated at the socket interconnect region.