A method for producing a resistive memory cell from a stack of layers having a metal-oxide layer interleaved between first and second electrodes includes forming, within one from among the first and second electrodes, an interlayer material-based electrode interlayer having a selectivity to etching greater than or equal to 2:1 relative to materials of the electrodes. During an etching of the stack, overetching is performed configured to laterally consume, in a horizontal direction, the interlayer material such that the electrode interlayer has a lateral recess greater than or equal to 10 nm.

The present disclosure relates to a chalcogenide material including germanium (Ge) with a first atomic percent, selenium (Se) with a second atomic percent that is at least twice the first atomic percent of the germanium, and indium (In) with a third atomic percent less the first atomic percent of the germanium.

A memory cell includes a first conductive line, a lower electrode, a carbon nano-tube (CNT) layer, a middle electrode, a resistive layer, a top electrode and a second conductive line. The first conductive line is disposed over a substrate. The lower electrode is disposed over the first conductive line. The carbon nano-tube (CNT) layer is disposed over the lower electrode. The middle electrode is disposed over the carbon nano-tube layer, thereby the lower electrode, the carbon nano-tube (CNT) layer and the middle electrode constituting a nanotube memory part. The resistive layer is disposed over the middle electrode. The top electrode is disposed over the resistive layer, thereby the middle electrode, the resistive layer and the top electrode constituting a resistive memory part. The second conductive line is disposed over the top electrode.

An RRAM structure includes a substrate. The substrate is divided into a memory cell region and a logic device region. A metal plug is disposed within the memory cell region. An RRAM is disposed on and contacts the metal plug. The RRAM includes a top electrode, a variable resistive layer, and a bottom electrode. The variable resistive layer is disposed between the top electrode and the bottom electrode. The variable resistive layer includes a first bottom surface. The bottom electrode includes a first top surface. The first bottom surface and the first top surface are coplanar. The first bottom surface only overlaps and contacts part of the first top surface.

A memory device enabling a reduced minimal conductance state may be provided. The device comprises a first electrode, a second electrode and phase-change material between the first electrode and the second electrode, wherein the phase-change material enables a plurality of conductivity states depending on the ratio between a crystalline and an amorphous phase of the phase-change material. The memory device comprises additionally a projection layer portion in a region between the first electrode and the second electrode. Thereby, an area directly covered by the phase-change material in the amorphous phase in a reset state of the memory device is larger than an area of the projection layer portion oriented to the phase-change material, such that a discontinuity in the conductance states of the memory device is created and a reduced minimal conductance state of the memory device in a reset state is enabled.

Some embodiments include an arrangement having a memory tier with memory cells on opposing sides of a coupling region. First sense/access lines are under the memory cells, and are electrically connected with the memory cells. A conductive interconnect is within the coupling region. A second sense/access line extends across the memory cells, and across the conductive interconnect. The second sense/access line has a first region having a second conductive material over a first conductive material, and has a second region having only the second conductive material. The first region is over the memory cells, and is electrically connected with the memory cells. The second region is over the conductive interconnect and is electrically coupled with the conductive interconnect. An additional tier is under the memory tier, and includes CMOS circuitry coupled with the conductive interconnect. Some embodiments include methods of forming multitier arrangements.

A selector with a superlattice-like structure and a preparation method thereof are provided, which belong to the technical field of micro-nano electronics. The selector includes a substrate, and a first metal electrode layer, a superlattice-like layer, and a second metal electrode layer sequentially stacked on the substrate. The superlattice-like layer includes n+1 first sublayers and n second sublayers alternately stacked periodically. A material of the first sublayer is amorphous carbon, and a material of the second sublayer is a chalcogenide with gating property.

A lead-free metallic halide memristor is disclosed. The lead-free metallic halide memristor comprises a first electrode layer, an active layer and a second electrode layer, of which the active layer is made of a metallic halide material. Experimental data have proved that the lead-free metallic halide memristor possesses synaptic plasticity because of showing characteristics of short-term potentiation, short-term depression, long-term potentiation, long-term depression during the experiments. Therefore, the lead-free metallic halide memristor has significant potential for being used as an artificial synaptic element so as to be further applied in the manufacture of a reservoir computing chip. Moreover, experimental data have also proved that the lead-free metallic halide memristor also shows the characteristics of multi-level resistive switching, whereupon the lead-free metallic halide memristor can be further used as analog non-volatile memory so as to be further applied in the manufacture of a neuromorphic computing chip.

A semiconductor device includes a substrate including an active portion defined by a device isolation pattern; a word line in the substrate, the word line crossing the active portion and extending in a first direction; a bit line crossing the active portion and the word line and extending in a second direction intersecting the first direction; a first pad on an end portion of the active portion; a first contact on the first pad and adjacent to the bit line in the first direction; and an insulating separation pattern on the word line and adjacent to the first contact in the second direction, wherein the first contact includes a barrier pattern on the first pad, and a conductive pattern vertically extending from the barrier pattern, and a side surface of the conductive pattern of the first contact is in direct contact with the insulating separation pattern.

A semiconductor device may include: a first conductive line including an opening passing through the first conductive line; a second conductive line disposed over the first conductive line and spaced apart from the first conductive line; a first electrode layer buried in the opening; a selector layer disposed in the opening and surrounding side surfaces of the first electrode layer; and a variable resistance layer disposed over the selector layer and the first electrode layer.