Abstract: A method of electrically linking contacts of a semiconductor device to their corresponding digit lines. The method includes disposing a quantity of mask material into a trench through which the contact is exposed. The mask also abuts a connect region of a conductive element of a corresponding digit line and, therefore, protrudes somewhat over a surface of the semiconductor device. A layer of insulative material is disposed over the semiconductor device with the mask material being exposed therethrough. The mask material is then removed, leaving open cavities that include the trench and a strap region continuous with the trench and with a connect region of the corresponding digit line. Conductive material is disposed within the cavity and electrically isolated from conductive material disposed in adjacent cavities, which define conductive plugs or studs and conductive straps from the conductive material.

Abstract: Fixed-voltage programming pulses are employed to program a phase change memory cell. A burst of incrementally widening fixed-voltage programming pulses may be employed to program a phase change memory to a target threshold voltage.

Abstract: To identify an RFID tag in a field of RFID tags, an interrogator sends a series of commands to implement an arbitration scheme. The commands include differentiation, selection, and modulation information. The tag uses the differentiation information to differentiate commands sent by the interrogator from commands sent by other interrogators that may be within communication range of the tag. The selection information is used by the tag to determine if the tag is a member of a group selected by the interrogator for response to the interrogator. If the tag is a member of the selected group, the tag may send a reply that is modulated using a modulation type selected by the modulation information. In accordance with one of the modulation types, one of three different pulse waveforms is selected by the interrogator via the modulation information to multiply with the baseband waveform of the reply from the tag.

Abstract: A non-volatile memory element includes a bottom electrode 12, a bit line 14 provided on the bottom electrode 12, and a recording layer 15 containing phase change material connected between the bottom electrode 12 and the bit line 14. In accordance with this invention, the bit line 14 is in contact with a growth initiation surface 15a of the recording layer 15. This structure can be obtained by forming the bit line 14 before the recording layer 15, resulting in a three-dimensional structure. This decreases the area of contact between the recording layer 15 and the bit line 14, decreasing heat dissipation to the bit line 14 without increasing the thickness of the recording layer 15. With this three-dimensional structure, moreover, there is no top electrode between the bit line 14 and the recording layer 15, keeping down the complexity of the fabrication process.

Abstract: A memory employs a low-level current source to access a phase change memory cell. The current source charges an access capacitor in order to store sufficient charge for an ensuing access. When a memory cell is accessed, charge stored on the capacitor is discharged through the phase change memory, supplying a current to the phase change memory cell that is sufficient for the intended access operation and greater than that provided directly by the current source.

Abstract: Chalcogenide devices are delineated and sidewalls of the devices are sealed, in an anaerobic and/or anhydrous environment environment. Throughout the delineation and sealing steps, and any intervening steps, the sidewalls are not exposed to oxygen or water. In an illustrative embodiment, a cluster tool includes an etching tool and a sealing/deposition tool configured to etch and seal the chalcogenide devices and to maintain the devices in an anaerobic and/or anhydrous environment throughout the process.

Abstract: A chalcogenide material and memory device exhibiting fast operation over an extended range of reset state resistances. Electrical devices containing the chalcogenide materials permit rapid transformations from the reset state to the set state for reset and set states having a high resistance ratio. The devices provide for high resistance contrast of memory states while preserving fast operational speeds. The chalcogenide materials include Ge, Sb and Te where the Ge and/or Te content is lean relative to Ge2Sb2Te5. In one embodiment, the concentration of Ge is between 11% and 22%, the concentration of Sb is between 22% and 65%, and the concentration of Te is between 28% and 55%. In a preferred embodiment, the concentration of Ge is between 15% and 18%, the concentration of Sb is between 32% and 35%, and the concentration of Te is between 48% and 51%.

Abstract: An electronic device includes a first electrode and a second electrode. The device also includes a resistive material between the first and second electrodes. An active material is between the first electrode and the resistive material. The active material is in electrical communication with the first electrode and the active material is in electrical communication with the second electrode through the resistive layer.

Abstract: A memory device includes a first electrode and a second electrode. A phase-change material is disposed between the first and second electrodes. The phase-change material is in electrical communication with the first and second electrodes at a first contact region and a second contact region respectively. The first and second contact regions are similar in contact area. The device enables scaling of reset current to smaller dimensions without encountering a limitation imposed by an offset current.

Abstract: A chalcongenide material is proposed for programming the cross-connect transistor coupling interconnect lines of an electrically programmable matrix array. Leakage may be reduced by optionally placing a thin insulating breakdown layer in series with the select device or a phase change material. The matrix array may be used in a programmable logic device.

Abstract: A chalcogenide material is proposed for programming the cross-connect transistor coupling interconnect lines of an electrically programmable matrix array. Leakage may be reduced by optionally placing a thin insulating breakdown layer in series with the select device or a phase change material. The matrix array may be used in a programmable logic device.

Abstract: A method for forming electrode materials uniformly within openings having small dimensions, including sublithographic dimensions, or high aspect ratios. The method includes the steps of providing an insulator layer having an opening formed therein, forming a non-conformal conductive or semiresistive material over and within the opening, and mobilizing the conductive material to densify it within the opening. The method reduces the concentration of voids or defects in the conductive or semiresistive material relative to the as-deposited state. The mobilizing step may be accomplished by extrusion or thermal reflow and causes voids or defects to coalesce, collapse, percolate, or otherwise be removed from the as-deposited conductive or semiresistive material.

Abstract: A programmable resistance, chalcogenide, switching or phase-change material device includes a substrate with a plurality of stacked layers including a conducting bottom composite electrode layer, an insulative layer having an opening formed therein, an active material layer deposited over both the insulative layer and the bottom composite electrode, and a top electrode layer deposited over the active material layer. The device uses a chemical or electrochemical liquid phase deposition process to selectively and conformally fill the insulative layer opening with the conductive bottom composite electrode layer. Conformally filling the conductive material within the opening reduces structural irregularities within the opening thereby increasing material density and resistivity within the device and thereby improving device performance and reducing programming current.

Abstract: A non-volatile memory latch may be formed with a phase change memory layer. Such a latch may be faster and more easily integrated into main stream semiconductor processes than conventional latches that use non-volatile memory elements such as flash memory.

Abstract: A method for forming electrically stimulable materials, including programmable resistance and electrical switching materials, in high aspect ratio features. The method includes forming a seed layer in the recessed portion of a feature and using the seed layer to direct the vapor phase deposition of an electrically stimulable material. The seed layer may provide nucleation sites that lead to preferential deposition of the electrically stimulable material on the seed layer relative to the sidewalls of the feature. The seed layer may promote the formation of a finely crystalline morphology of the electrically stimulable material to facilitate deposition in the recessed portions of a feature and inhibit blocking of the top of the feature by large crystals.

Abstract: A memory may be implemented with a stable chalcogenide glass which is defined as a generally amorphous chalcogenide material that does not change to a generally crystalline phase when exposed to 200° C. for 30 minutes or less. Different states may be programmed by changing the threshold voltage of the material. The threshold voltage may be changed with pulses of different amplitude and/or different pulse fall times. Reading may be done using a reference level between the threshold voltages of the two different states. A separate access device is generally not needed.

Abstract: Thin film logic circuits employ thin-film switching devices to execute complementary logic functions. Such logic devices operate, as complementary metal oxide semiconductor (CMOS) logic devices do, in a manner that does not provide a direct conduction path between a system supply and a system return. Complementary logic circuits may employ three-terminal threshold switches as switching elements.

Abstract: A method of programming a multi-layer chalcogenide electronic device. The device includes an active region in electrical communication with two terminals, where the active region includes two or more layers. The method includes providing an electrical signal between the two terminals, where the electrical signal alters an electrical characteristic of a layer remote from one of the terminals. In one embodiment, the layer remote from the terminal is a chalcogenide material and the electrical characteristic is resistance. In another embodiment, an electrical characteristic of the layer in contact with the terminal is also altered. The alteration of an electrical characteristic may be caused by a transformation of a chalcogenide material from one structural state to another structural state.

Abstract: A programmable resistance memory combines multiple cells into a block that includes one or more shared electrodes. The shared electrode configuration provides additional thermal isolation for the active region of each memory cell, thereby reducing the current required to program each memory cell.

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.