Abstract: A memory cell device includes a memory cell access layer, a dielectric material over the memory cell access layer, a memory material structure within the dielectric material, and a top electrode in electrical contact with the memory material structure. The memory material structure has upper and lower memory material portions and a memory material element therebetween. The lower memory material layer is in electrical contact with a bottom electrode. The lower memory material layer has an average lateral dimension. The memory material element defines an electrical property state change region therein and has a minimum lateral dimension which is substantially less than the average lateral dimension. In some examples the memory material element is a tapered structure with the electrical property state change region at the junction of the memory material element and the lower memory material layer.

Abstract: Logic circuits are disclosed that include one or more three-terminal chalcogenide devices. The three-terminal chalcogenide devices are electrically interconnected and configured to perform one or more logic operations, including AND, OR, NOT, NAND, NOR, XOR, and XNOR. Embodiments include series and parallel configurations of three-terminal chalcogenide devices. The chalcogenide devices include a chalcogenide switching material as the working medium along with three electrical terminals in electrical communication therewith. In one embodiment, the circuits include one or more input terminals, one or more output terminals, and a clock terminal. The input terminals receive one or more input signals and deliver them to the circuit for processing according to a logic operation. Upon conclusion of processing, the output of the circuit is provided to the output terminal. The clock terminal delivers a clock signal to facilitate operation of the three-terminal devices included in the instant circuits.

Abstract: An intermediate electrode between an ovonic threshold switch and a memory element may be formed in the same pore with the memory element. This may have many advantages including, in some embodiments, reducing leakage.

Abstract: Non-volatile memories formed on a substrate and fabrication methods are disclosed. A bottom electrode comprising a metal layer is disposed on the substrate. A buffer layer comprising a LaNiO3 film is disposed over the metal layer. A resistor layer comprising a SrZrO3 film is disposed on the buffer layer. A top electrode is disposed on the resistor layer.

Abstract: A microelectromechanical system (MEMS) device with a mechanism layer and a base. The top surface of the base is bonded to the mechanism layer and defines a gap in the top surface of the base. A portion of the mechanism layer is deflected into the gap until it contacts the base, and is bonded to the base.

Abstract: A chalcogenide memory cell includes a lower electrode, a chalcogenide layer, and an upper electrode. The lower electrode includes a tapered cavity. The chalcogenide layer is formed in the tapered cavity of the lower electrode. One side of the chalcogenide layer is adjacent to the lower electrode. The upper electrode is formed in a second cavity formed by the chalcogenide layer so that the upper electrode substantially fills the second cavity. The upper electrode is adjacent to the other side of the chalcogenide layer. Information is stored and retrieved by passing current between the upper electrode and the lower electrode. The tapered cavity of the lower electrode is formed through anisotropic etching or through sidewall-application. Undesired currents are prevented using an additional dielectric layer or by using an additional conductive layer that forms a p-n junction with the lower electrode.

Abstract: An MIM device includes a lower electrode of a metal nitride film, a hysteresis film of an oxide film containing Nb formed on the lower electrode, and an upper electrode of a metal nitride film formed on the hysteresis film.

Abstract: Electromechanical non-volatile memory devices are provided including a semiconductor substrate having an upper surface including insulation characteristics. A first electrode pattern is provided on the semiconductor substrate. The first electrode pattern exposes portions of a surface of the semiconductor substrate therethrough. A conformal bit line is provided on the first electrode pattern and the exposed surface of semiconductor substrate. The bit line is spaced apart from a sidewall of the first electrode pattern and includes a conductive material having an elasticity generated by a voltage difference. An insulating layer pattern is provided on an upper surface of the bit line located on the semiconductor substrate. A second electrode pattern is spaced apart from the bit line and provided on the insulating layer pattern. The second electrode pattern faces the first electrode pattern.

Abstract: A resistance type memory device is provided. The resistance type memory device is disposed on a substrate and includes a tungsten electrode, an upper electrode, and a tungsten oxide layer. The upper electrode is disposed on the tungsten electrode. The tungsten oxide layer is sandwiched between the tungsten electrode and the upper electrode.

Abstract: A multi-terminal electrically actuated switch comprises a source electrode, a drain electrode, and an active region physically connected to both electrodes. The active region comprises at least one primary active region comprising at least one material that can be doped or undoped to change its electrical conductivity, and a secondary active region comprising at least one material for providing a source/sink of ionic species that act as dopants for the primary active region(s). A gate electrode is physically connected to the source/sink region. Methods of operating the switch are also provided.

Abstract: A memory device, such as a PCRAM, including a chalcogenide glass backbone material with germanium telluride glass and methods of forming such a memory device.

Abstract: A dielectric layer is formed on a region of a microelectronic substrate. A sacrificial layer is formed on the dielectric layer, and portions of the sacrificial layer and the dielectric layer are removed to form an opening that exposes a portion of the region. A conductive layer is formed on the sacrificial layer and in the opening. Portions of the sacrificial layer and the conductive layer on the dielectric layer are removed to leave a conductive plug in the dielectric layer and in contact with the region. Removal of the sacrificial layer and portions of the conductive layer on the dielectric layer may include polishing to expose the sacrificial layer and to leave a conductive plug in the sacrificial layer and the dielectric layer, etching the sacrificial layer to expose the dielectric layer and leave a portion of the conductive plug protruding from the dielectric layer, and polishing to remove the protruding portion of the conductive plug.

Abstract: A microelectronic programmable structure suitable for storing information, a device including the structure and methods of forming and programming the structure are disclosed. The programmable structure generally includes an ion conductor and a plurality of electrodes. Electrical properties of the structure may be altered by applying energy to the structure, and thus information may be stored using the structure.

Abstract: A phase-change memory cell is formed by a phase-change memory element and by a selection element, which is formed in a semiconductor material body and is connected to the phase-change memory element. The phase-change memory element is made up of a calcogenic material layer and a heater. The selection element is in direct contact with the heater and extends through a dielectric region arranged on top of and contiguous to the semiconductor material body. A dielectric material layer is arranged on the dielectric region and houses a portion of the calcogenic material layer.

Abstract: The method according to the invention is directed to manufacturing an electric device (100) according to the invention, having a body (102) with a resistor comprising a phase change material being changeable between a first phase and a second phase, the resistor having a first electrical resistance when the phase change material is in the first phase, and a second electrical resistance different from the first electrical resistance when the phase change material is in the second phase. The resistor is a nanowire (NW) electrically connecting a first conductor (172, 120) and a second conductor (108, 121). The method comprises the step of providing a body (102) having the first conductor (172, 120), providing the first conductor (172, 120) with the nanowire (NW) thereby electrically connecting the nanowire (NW) and the first conductor (172, 120), and providing the nanowire (NW) with the second conductor (108, 121) thereby electrically connecting the nanowire (NW) and the second conductor (108, 121).