A memory cell design is disclosed. The memory cell structure includes phase change and selector layers stacked between top and bottom electrodes. An ohmic contact may be included between the phase change and selector layers. A multi-layer liner structure is provided on sidewalls of the phase change layer. In some such cases, the liner structure is above and not on sidewalls of the selector layer. The liner structure includes a first dielectric layer, and a second dielectric layer on the first dielectric layer. The liner structure includes a third dielectric layer on the second dielectric layer and that is sacrificial in nature, and may not be present in the final structure. The second dielectric layer comprises a high-k dielectric material or a metal silicate material. The second dielectric layer protects the phase change layer from lateral erosion and physical vertical etch and provides etch selectivity during the fabrication process.

A method of forming circuitry components includes forming a stack of horizontally extending and vertically overlapping features. The stack has a primary portion and an end portion. At least some of the features extend farther in the horizontal direction in the end portion moving deeper into the stack in the end portion. Operative structures are formed vertically through the features in the primary portion and dummy structures are formed vertically through the features in the end portion. Horizontally elongated openings are formed through the features to form horizontally elongated and vertically overlapping lines from material of the features. The lines individually extend from the primary portion into the end portion, and individually laterally about sides of vertically extending portions of both the operative structures and the dummy structures. Sacrificial material that is elevationally between the lines is at least partially removed in the primary and end portions laterally between the horizontally elongated openings. Other aspects and implementations are disclosed.

A resistance circuit is configured such that a P-type resistance section and an N-type resistance section are electrically connected in series, the P-type resistance section is configured with P-type diffusion layer resistance elements that are disposed to form a right angle with respect to each other and that are electrically connected in series, and the N-type resistance section is configured with N-type diffusion layer resistance elements that are disposed to form the right angle with respect to each other and that are electrically connected in series. Furthermore, the P-type diffusion layer resistance element is disposed along a <100> orientation direction of a semiconductor substrate, and the N-type diffusion layer resistance element is disposed along a <110> orientation direction of the semiconductor substrate. It is thereby possible to provide the resistance circuit, an oscillation circuit, and an in-vehicle sensor apparatus that reduce stress-induced characteristic fluctuations.

Embodiments of 3D memory devices with a semiconductor plug protected by a dielectric layer and methods for forming the same are disclosed. In an example, a 3D memory device includes a substrate, a memory stack including a plurality of interleaved conductor layers and dielectric layers on the substrate, and a memory string extending vertically through the memory stack. The memory string includes a semiconductor plug in a lower portion of the memory string, a protective dielectric layer on the semiconductor plug, and a memory film above the protective dielectric layer and along a sidewall of the memory string.

The present disclosure provides a scalable architecture for an advanced processing apparatus for performing quantum processing. The architecture is based on an all-silicon CMOS fabrication technology. Transistor-based control circuits, together with floating gates, are used to operate a two-dimensional array of qubits. The qubits are defined by the spin states of a single electron confined in a quantum dot.

Some embodiments include a memory array having a first set of lines extending along a first direction, and a second set of lines over the first set of lines and extending along a second direction. Lines of the second set cross lines of the first set at cross-point locations. Memory structures are within the cross-point locations. Each memory structure includes a top electrode material, a bottom electrode material and a programmable material. Rails of insulative material extend parallel to the lines of the second set and alternate with the lines of the second set along the first direction. The programmable material has first regions within the memory structures and second regions over the rails of insulative material. A planarized surface extends across the lines of the second set and across the second regions of the programmable material. Some embodiments include methods of forming memory arrays.

In some embodiments, the present disclosure relates to a method of forming a memory circuit. The method may be performed by forming an interconnect wire within an inter-level dielectric (ILD) layer over a substrate. A conjunct electrode structure is formed over the interconnect wire, a data storage film is formed over the conjunct electrode structure, and a disjunct electrode structure is formed over the data storage film. The data storage film, the disjunct electrode structure, and the conjunct electrode structure are patterned to form a first data storage layer between the interconnect wire and a first disjunct electrode and to form a second data storage layer between the interconnect wire and a second disjunct electrode.

Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a memory stack including interleaved conductive layers and dielectric layers, a channel structure extending vertically through the memory stack, and a semiconductor layer above the memory stack. The channel structure includes a channel plug in a lower portion of the channel structure, a memory film along a sidewall of the channel structure, and a semiconductor channel over the memory film and in contact with the channel plug. The semiconductor layer includes a semiconductor plug above and in contact with the semiconductor channel.

Embodiments of three-dimensional (3D) memory devices having multiple memory stacks and methods for forming the 3D memory devices are disclosed. In an example, a 3D memory device includes a first device chip, a second device chip, and a bonding interface. The first device chip includes a peripheral device and a first interconnect layer. The second device chip includes a substrate, two memory stacks disposed on opposite sides of the substrate, two memory strings each extending vertically through one of the two memory stacks, and a second interconnect layer. The bonding interface is formed vertically between the first interconnect layer of the first device chip and the second interconnect layer of the second device chip.

A stacked multilayer structure according to an embodiment of the present invention comprises: a stacked layer part including a plurality of conducting layers and a plurality of insulating layers, said plurality of insulating layers being stacked alternately with each layer of said plurality of conducting layers, one of said plurality of insulating layers being a topmost layer among said plurality of conducting layers and said plurality of insulating layers; and a plurality of contacts, each contact of said plurality of contacts being formed from said topmost layer and each contact of said plurality of contacts being in contact with a respective conducting layer of said plurality of conducting layers, a side surface of each of said plurality of contacts being insulated from said plurality of conducting layers via an insulating film.