Memory cell architectures and methods of forming the same are provided. An example memory cell can include a switch element and a memory element formed in series with the switch element. A smallest lateral dimension of the switch element is different than a smallest lateral dimension of the memory element.

A memory device includes a first electrode line layer including a plurality of first electrode lines extending on a substrate in a first direction and being spaced apart from each other, a second electrode line layer including a plurality of second electrode lines extending on the first electrode line layer in a second direction that is different from the first direction and being spaced apart from each other, and a memory cell layer including a plurality of first memory cells located at a plurality of intersections between the plurality of first electrode lines and the plurality of second electrode lines, each first memory cell including a selection device layer, an intermediate electrode and a variable resistance layer that are sequentially stacked. A side surface of the variable resistance layer is perpendicular to a top surface of the substrate or inclined to be gradually wider toward an upper portion of the variable resistance layer. The first memory cell has a side surface slope so as to have a width gradually decreasing toward its upper portion.

A thermally optimized phase change memory cell includes a phase change material element disposed between first and second electrodes. The second electrode includes a thermally insulating region having a first thermal resistivity over the first electrode and a metallic contact region interposed between the phase change material element and the thermally insulating region, where the metallic contact layer has a second thermal resistivity lower than the first thermal resistivity.

A circuit includes: a first node to receive a first current; a first resistive element receiving a first branch current of the first current; first transistors each including a first terminal connected to the second end of the first resistive element; a second resistive element connected to the first node and receiving a second branch current of the first current; a second node to receive a second current; a second transistor including a first terminal, the first terminal of the second transistor connected to the second node and receiving a first branch current of the second current; a third resistive element connected to the second node and receiving a second branch current of the second current; wherein a temperature coefficient of the first current is adjusted by a resistance of the second resistive element and a resistance of the third resistive element.

The disclosure relates to integrated circuits including one or more rows of transistors and methods of forming rows of transistors. In an embodiment, an integrated circuit includes a row of bipolar transistors including a first semiconductor layer having a plurality of first conduction regions, a second semiconductor layer having a second conduction region, a common base between the first semiconductor layer and the second semiconductor layer, and a plurality of insulator walls extending in a first direction. The first conduction regions are separated from one another by the insulator walls. The integrated circuit further includes an insulating trench extending in a second direction and in contact with each of the bipolar transistors of the row of bipolar transistors. A conductive layer is coupled to the base, and the conductive layer extends through the insulator walls and extends at least partially into the insulating trench.

A method of forming a self-aligned phase change memory element is provided. A bottom electrode is formed on a landing pad of a phase change memory element. A layer of dielectric material over the bottom electrode and a via etched through the dielectric material to expose the bottom electrode. The via is lined with a GST phase change layer that is etched back from the top surface of the dielectric layer. The via is then filled with a nitride fill, at least of portion of which is etched back from the top surface of the dielectric layer. A top electrode metal is then deposited at the top of the via, wherein the top electrode material is coupled to the phase change material and nitride fill material.

Memory cell architectures and methods of forming the same are provided. An example memory cell can include a switch element and a memory element formed in series with the switch element. A smallest lateral dimension of the switch element is different than a smallest lateral dimension of the memory element.

The disclosed technology relates generally to integrated circuit devices, and in particular to cross-point memory arrays and methods for fabricating the same. In one aspect, a memory device of the memory array comprises a substrate and a memory cell stack formed between and electrically connected to first and second conductive lines. The memory cell stack comprises a first memory element over the substrate and a second memory element formed over the first element, wherein one of the first and second memory elements comprises a storage element and the other of the first and second memory elements comprises a selector element. The memory cell stack additionally comprises a first pair of sidewalls opposing each other and a second pair of sidewalls opposing each other and intersecting the first pair of sidewalls. The memory device additionally comprises first protective dielectric insulating materials formed on a lower portion of the first pair of sidewalls and an isolation dielectric formed on the first protective dielectric insulating material and further formed on an upper portion of the first pair of sidewalls.

A semiconductor metal-oxide-semiconductor field effect transistor (MOSFET) with increased on-state current obtained through a parasitic bipolar junction transistor (BJT) of the MOSFET. Methods of operating the MOSFET as a memory cell or a memory array select transistor are provided.

Provided are a semiconductor device and a method of fabricating the same.

The semiconductor device includes a semiconductor substrate, a first and a second diffusion region formed under a surface of the semiconductor substrate, a gate and a sidewall spacer stacked on the semiconductor substrate, wherein the first diffusion region is at least one active region not being intersected by the gate and the sidewall spacer, wherein the second diffusion region includes a part of an active region intersecting the gate and the sidewall space, wherein there is no gate insulating layer between the gate and the semiconductor substrate.