There is provided a non-volatile memory device comprising: a substrate; a lower electrode disposed on the substrate; a resistance layer disposed on the lower electrode; and an upper electrode disposed on the resistance layer, wherein the resistance layer include a stack of a graphene oxide film and an iron oxide film, wherein a resistance value of the resistance layer varies based on a voltage applied to the upper electrode.

A switch includes a first electrode layer, a second electrode layer disposed over the first electrode layer, and a selecting element layer interposed between the first electrode layer and the second electrode layer. The selecting element layer includes a gas region in which a current flows or does not flow according to a voltage applied to the switch. When the current flows, the switch is in an on-state, and, when the current does not flow, the switch is in an off-state.

A RRAM device having a diode device structure coupled to a variable resistance layer is disclosed. The diode device structure can either be embedded into or fabricated over the substrate. A memory device having an array of said RRAM devices can be fabricated with multiple common bit lines and common word lines.

This patent document provides an electronic device including a semiconductor memory that can simplify a fabrication process and improve characteristics of a variable resistance element, and a method for fabricating the same. In one aspect, an electronic device including a semiconductor memory is provided, wherein the semiconductor memory includes: a substrate; a variable resistance element formed over the substrate and exhibiting different resistance states to store data; an interlayer insulating layer formed over the substrate to surround at least a portion of the variable resistance element; an upper electrode contact formed over the variable resistance element to penetrate a portion of the interlayer insulating layer and be in contact with the variable resistance element; and a metal wiring formed over the interlayer insulating layer, and configured to include a stacked structure of a tungsten layer and a barrier layer, wherein the barrier layer is in contact with the upper electrode contact and includes tungsten, boron and iridium.

The disclosed technology generally relates to semiconductor devices and more particularly to memory or storage devices based on resistive switching, and to methods of making and using such devices. In one aspect, a resistive switching memory device includes a first electrode and a second electrode having interposed therebetween a first inner region and a second inner region, where the first and second inner regions contacting each other. The first inner region includes one or more metal oxide layers and the second inner region consists of a plurality of layers, where each of the layers of the second inner region is an insulating, a semi-insulating or a semiconducting layer. The second inner region comprises one or more layers having a stoichiometric or off-stoichiometric composition of a material selected from the group consisting of SiGe.sub.x, SiN.sub.x, AlO.sub.x, MgO.sub.x, AlN.sub.x, SiN.sub.x, HfO.sub.x, HfSiO.sub.x, ZrO.sub.x, ZrSiO.sub.x, GdAlO.sub.x, DyScO.sub.x, TaO.sub.x and combinations thereof. The second inner region comprises one or more silicon-containing layers, such that one of the one or more silicon-containing layers contacts the first inner region.

A nonvolatile memory device group includes: (A) a first insulating layer; (B) a second insulating layer that has a first concavity and a second concavity communicating with the first concavity and having a width larger than that of the first concavity and that is disposed on the first insulating layer; (C) a plurality of electrodes that are disposed in the first insulating layer and the top surface of which is exposed from the bottom surface of the first concavity; (D) an information storage layer that is formed on the side walls and the bottom surfaces of the first concavity and the second concavity; and (E) a conductive material layer that is filled in a space surrounded with the information storage layer in the second concavity.

A semiconductor structure comprises a conductive bridge random access memory device and an access device connected in series with the conductive bridge random access memory device. The conductive bridge random access memory device and the access device are arranged in a vertical stack. The vertical stack has a sidewall profile that increases in width from a bottom surface of the vertical stack to a top surface of the vertical stack.

The present disclosure relates to a memory device. The memory device includes an access device arranged on or within a substrate and coupled to a word-line and a source line. A plurality of lower interconnects are disposed within a lower dielectric structure over the substrate. A first electrode is coupled to the plurality of lower interconnects. The plurality of lower interconnects couple the access device to the first electrode. A second electrode is over the first electrode. One or more upper interconnects are disposed within an upper dielectric structure laterally surrounding the second electrode. The one or more upper interconnects couple the second electrode to a bit-line. A data storage structure is disposed between the first electrode and the second electrode. The data storage structure includes one or more metals having non-zero concentrations that change as a distance from the substrate varies.

A semiconductor memory includes first to third lines, the second line crossing the first and third lines between the first line and the third line, a first memory element overlapping an intersection region of the first and second lines between the first line and the second line, the first memory element including a first memory layer, a first electrode under the first memory layer, and a second electrode over the first memory layer, and a second memory element overlapping an intersection region of the second and third lines between the second line and the third line, the second memory element including a second memory layer, a third electrode under the second memory layer, and a fourth electrode over the second memory layer. An electrical resistance relation of the third and fourth electrodes is controlled according to an electrical resistance relation of electrical resistances of the first and second electrodes.

There is provided a three-terminal atomic switching device and a method of manufacturing the same, which belongs to the field of microelectronics manufacturing and memory technology. The three-terminal atomic switching device includes: a stack structure including a source terminal and a drain terminal; a vertical trench formed by etching the stack structure; an M.sub.8XY.sub.6 channel layer formed on an inner wall and a bottom of the vertical trench; and a control terminal formed on a surface of the M.sub.8XY.sub.6 channel layer, wherein the control terminal fills the vertical trench. The source terminal resistance and the drain terminal resistance are controlled by the control terminal. The invention is based on the three-terminal atomic switching device, and realizes high switching ratio characteristic, simple structure, easy integration, high density and low cost due to high non-linearity of the source-drain resistance with respect to the control terminal voltage, and thus can be used in a gated device in a cross-array structure to inhibit a crosstalk phenomenon caused by the leakage current. The three-terminal atomic switching device proposed by the invention is suitable for a planar stacked cross-array structure and a vertical cross-array structure, so as to realize high-density three-dimensional storage.