Abstract: A memory array with graded resistance lines includes a first set of lines intersecting a second set of lines. A line from one of the sets of lines includes a graded resistance along a length of the line.

Abstract: A memory element is provided that includes a first electrode, a second electrode, and an active region disposed between the first electrode and the second electrode, wherein at least a portion of the active region comprises an elastically deformable material, and wherein deformation of the elastically deformable material causes said memory element to change from a lower conductive state to a higher conductive state. A multilayer structure also is provided that includes a base and a multilayer circuit disposed above the base, where the multilayer circuit includes at least of the memory elements including the elastically deformable material.

Abstract: A memristor includes a first electrode of a nanoscale width; a second electrode of a nanoscale width; and an active region disposed between the first and second electrodes. The active region has a both a non-conducting portion and a source of dopants portion induced by electric field. The non-conducting portion comprises an electronically semiconducting or nominally insulating material and a weak ionic conductor switching material capable of carrying a species of dopants and transporting the dopants under an electric field. The non-conducting portion is in contact with the first electrode and the source of dopants portion is in contact with the second electrode. The second electrode comprises a metal reservoir for the dopants. A crossbar array comprising a plurality of the nanoscale switching devices is also provided. A process for making at least one nanoscale switching device is further provided.

Abstract: A switchable junction (600) having an intrinsic diode (634) formed with a voltage dependent resistor (640) is disclosed. The switchable junction comprises a first electrode (618), a second electrode (622), and a memristive matrix (620) configured to form an electrical interface (626) with the first electrode (618). The electrical interface has a programmable conductance. The voltage dependent resistor (640) is in electrical contact with the memristive matrix (620). The voltage dependent resistor is configured to form a rectifying diode interface (628) with the second electrode (622).

Abstract: A multilayer structure is provided that includes a base and a multilayer circuit disposed above the base. The multilayer circuit includes memory elements, each including a switching layer, and conductive lines leading from the base to the memory element. The total resistance of the switching layer of a memory element is varied based on the total resistance of conductive lines leading from the base to the memory element.

Abstract: A memristive junction (400) can comprise a first electrode (102) and second electrode (104), with a memristive region (106) situated between them. The memristive region is configured to switch between two activation states via a switching voltage (118) applied between the electrodes. The activation state can be ascertained by application of a reading voltage between the first electrode and second electrode. The junction further comprises a rectifier region situated at an interface (420) between the first electrode and the memristive region, and comprising a layer (402) of temperature-responsive transition material that is substantially conductive at the switching voltage and substantially resistive at the reading voltage.

Abstract: A composition and method is described for intracellular delivery of fullerene containing peptides. The composition and method involve fullerene-substituted phenylalanine as part of a peptide based delivery system. The presence of a fullerene-substituted amino acid in a peptide is found to alter the intracellular transport properties of the peptide.

Abstract: Methods and means related to memory resistors are provided. A memristor includes at least two different active materials disposed between a pair of electrodes. The active materials are selected to exhibit respective and opposite changes in electrical resistance in response to changes in oxygen ion content. The active materials are subject to oxygen ion reconfiguration under the influence of an applied electric field. An electrical resistance of the memristor is thus adjustable by way of applied programming voltages and is non-volatile between programming events.

Abstract: A nanoscale switching device exhibits multiple desired properties including a low switching current level, being electroforming-free, and cycling endurance. The switching device has an active region disposed between two electrodes. The active region contains a switching material capable of transporting dopants under an electric field. The switching material is in an amorphous state and formed by deposition at or below room temperature.

Abstract: A switchable junction (600) having intrinsic diodes with different switching thresholds is disclosed. The switchable junction comprises a first electrode (610) formed of a first conductive material and a second electrode (630) formed of a second conductive material. The junction (600) further includes a memristive matrix (615) configured to form a first and a second electrical interface with the first and second electrodes to form a first rectifying diode interface (626) with a first switching threshold and a second rectifying diode interface (628) with a second switching threshold.

Abstract: A memristive device having a bimetallic electrode includes a memristive matrix, a first electrode and a second electrode. The first electrode is in electrical contact with the memristive matrix and the second electrode is in electrical contact with the memristive matrix and an underlying layer. At least one of the first and second electrodes is a bimetallic electrode which includes a conducting layer and a metallic layer.

Abstract: An addressable nano-scale mechanical actuator is formed at the intersection of two nanowires. The actuator has an active region disposed between the two nanowires, which form the electrodes of the actuator. The active region contains an electrolytically decomposable material. When an activation voltage is applied to the electrodes, the material releases a gas that forms a bubble at one electrode, causing a bulging of a top surface of the actuator. The bulging may be used, via mechanical coupling, to provide mechanical actuation on a nanometer scale. The nanowires may be arranged in a two-dimensional array to provide an array of individually addressable actuators.

Abstract: An installation platform for deploying an earth-based sensor network utilizing a projected pattern from a height. The installation platform includes an aerostatic aircraft, at least one sensor-location projector, and a projector stabilizer. The sensor-location projector is coupled with the aerostatic aircraft, and is configurable to project the projected pattern including at least one sensor-location marker associated with a location for a sensor in the sensor network. The projector stabilizer is configurable for maintaining the sensor-location projector in a sufficiently static orientation relative to the location for the sensor to allow deployment of the sensor within a specified distance of the location on a surface of the earth from the sensor-location marker. A sensor-network-deployment system along with a method for deploying the sensor-network are also provided.

Abstract: A memristor with a switching layer that includes a composite of multiple phases is disclosed. The memristor comprises: a first electrode; a second electrode spaced from the first electrode; and a switching layer positioned between the first electrode and the second electrode, the switching layer comprising the multi-phase composite system that comprises a first majority phase comprising a relatively insulating matrix of a switching material and a second minority phase comprising a relatively conducting material for forming at least one conducting channel in the switching layer during a fabrication process of the memristor. A method of making the memristor and a crossbar employing the memristor are also disclosed.

Abstract: A nanoscale switching device comprises at least two electrodes, each of a nanoscale width; and an active region disposed between and in electrical contact with the electrodes, the active region containing a switching material capable of carrying a species of dopants and transporting the dopants under an electrical field, wherein at least one of the electrodes comprises an amorphous conductive material.

Abstract: A decoding structure employs a main terminal (130), a first memristive switch (112) connected between the main terminal (130) and a first addressable terminal (132), and a second memristive switch (114) connected between the main terminal (130) and a second addressable terminal (134). The second memristive switch (114) is oriented so that a voltage polarity on the main terminal (130) that tends to turn the first memristive switch (112) on tends to turn the second memristive switch (114) off.

Abstract: Various embodiments of the present invention are directed to electronic devices, which combine reconfigurable diode rectifying states with nonvolatile memristive switching. In one aspect, an electronic device (210,230,240) comprises an active region (212) sandwiched between a first electrode (104) and a second electrode (106). The active region includes two or more semiconductor layers and at least one dopant that is capable of being selectively positioned within the active region to control the flow of charge carriers through the device.

Abstract: A memristive switch device can comprise a switch formed between a first electrode and a second electrode, where the switch includes a memristive layer and a select layer directly adjacent the memristive layer. The select layer blocks current to the memristive layer over a symmetric bipolar range of subthreshold voltages applied between the first and second electrodes.

Abstract: Various embodiments of the present invention are direct to nanoscale, reconfigurable memristor devices. In one aspect, a memristor device (500,600) comprises an active region (508,610) sandwiched between a first electrode (301) and a second electrode (302).

Abstract: A nanoscale switching device provides enhanced thermal stability and endurance to switching cycles. The switching device has an active region disposed between electrodes and containing a switching material capable of carrying a species of dopants and transporting the dopants under an electrical field. At least one of the electrodes is formed of conductive material having a melting point greater than 1800° C.