Abstract: Phase change memory devices and methods for operating described herein are based on the discovery that, following an initial high current operation applied to a phase change memory cell to establish the high resistance reset state, the current-voltage (I-V) behavior of the memory cell under different bias voltages can be used to detect if the memory cell is a defect cell having poor data retention characteristics.

Abstract: Memory devices and methods for operating such devices are described which can effectively program the metal-oxide memory elements in an array, while also avoiding applying unnecessarily high voltage pulses. Programming operations described herein include applying a lower voltage pulse across a metal-oxide memory element to establish a desired resistance state, and only applying a higher voltage pulse when the lower voltage pulse is insufficient to program the memory element. In doing so, issues associated with applying unnecessarily high voltages across the memory element can be avoided.

Abstract: A memory cell described herein includes a memory element comprising programmable resistance memory material overlying a conductive contact. An insulator element includes a pipe shaped portion extending from the conductive contact into the memory element, the pipe shaped portion having proximal and distal ends and an inside surface defining an interior, the proximal end adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end to the distal end, the bottom electrode having a top surface contacting the memory element adjacent the distal end at a first contact surface. A top electrode is separated from the distal end of the pipe shaped portion by the memory element and contacts the memory element at a second contact surface, the second contact surface having a surface area greater than that of the first contact surface.

Abstract: A memory device including programmable resistance memory cells, including electrically pre-stressed target memory cells. The pre-stressed target memory cells have one of a lower voltage transition threshold, a shorter duration set interval and a longer reset state retention characteristic. Biasing circuitry is included on the device configured to control the pre-stressing operations, and to apply read, set and reset operations that can be modified for the pre-stressed memory cells.

Abstract: A 3D memory device includes an array of semiconductor body pillars and bit line pillars, dielectric charge trapping structures, and a plurality of levels of word line structures arranged orthogonally to the array of semiconductor body pillars and bit line pillars. The semiconductor body pillars have corresponding bit line pillars on opposing first and second sides, providing source and drain terminals. The semiconductor body pillars have first and second channel surfaces on opposing third and fourth sides. Dielectric charge trapping structures overlie the first and second channel surfaces, providing data storage sites on two sides of each semiconductor body pillar in each level of the 3D array. The device can be operated as a 3D AND-decoded flash memory.

Abstract: A memory cell described herein includes a memory element comprising programmable resistance memory material overlying a conductive contact. An insulator element includes a pipe shaped portion extending from the conductive contact into the memory element, the pipe shaped portion having proximal and distal ends and an inside surface defining an interior, the proximal end adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end to the distal end, the bottom electrode having a top surface contacting the memory element adjacent the distal end at a first contact surface. A top electrode is separated from the distal end of the pipe shaped portion by the memory element and contacts the memory element at a second contact surface, the second contact surface having a surface area greater than that of the first contact surface.

Abstract: A memory array comprising vertical memory cells does not require any isolation layers between cells. Thus, a very compact, high density memory array can be achieved. Each memory cell in the memory array is configured to store 4 bits of data per cell. Multi-level charge techniques can be used to increase the number of bit per cell and achieve further increased density for the memory array.

Abstract: Memory devices and methods for operating such devices are described herein. A method is described herein for operating a memory cell comprising phase change material and programmable to a plurality of resistance states including a high resistance state and a lower resistance state. The method comprises applying a first bias arrangement to the memory cell to establish the lower resistance state, the first bias arrangement comprising a first voltage pulse. The method further comprises determining whether the memory cell is in the lower resistance state, and if the memory cell is not in the lower resistance state then applying a second bias arrangement to the memory cell. The second bias arrangement comprises a second voltage pulse having a pulse height greater than that of the first voltage pulse.

Abstract: An integrated circuit phase change memory can be pre-coded by inducing a first resistance state in some cells and the memory, and a second resistance state and some other cells in the memory to represent a data set. The integrated circuit phase change memory is mounted on a substrate after coding the data set. After mounting the integrated circuit phase change memory, the data set is read by sensing the first and second resistance states, and changing cells in the first resistance state to a third resistance state and changing cells in the second resistance state to a fourth resistance state. The first and second resistance states maintain a sensing margin after solder bonding or other thermal cycling process. The third and fourth resistance states are characterized by the ability to cause a transition using higher speed and lower power, suitable for a mission function of a circuit.

Abstract: A phase change device includes a first contact electrode structure a phase change material and a first insulating material between the phase change material and the first contact electrode structure and a second contact electrode in contact with the phase change material. A contact structure formed in the first insulating material between the first contact electrode structure and the phase change material is also included. The contact structure is formed by an insulating material breakdown process. A method of forming a phase change device is also described.

Abstract: A method of programming a phase change device includes selecting a desired threshold voltage (Vth) and applying a programming pulse to a phase change material in the phase change device. The applying of the programming pulse includes applying a quantity of energy to the phase change material to drive at least a portion of this material above a melting energy level. A portion of the energy applied to the phase change material is allowed to dissipate below the melting energy level. The shape of the energy dissipation from the phase change material is controlled until the energy applied to the phase change material is less than a quenched energy level, to cause the phase change device to have the desired Vth. A remaining portion of the energy applied to the phase change material is allowed to dissipate to an environmental level.

Abstract: A 3D memory device is described which includes bottom and top memory cubes having respective arrays of vertical NAND string structures. A common source plane comprising a layer of conductive material is between the top and bottom memory cubes. The source plane is supplied a bias voltage such as ground, and is selectively coupled to an end of the vertical NAND string structures of the bottom and top memory cubes. Memory cells in a particular memory cube are read using current through the particular vertical NAND string between the source plane and a corresponding bit line coupled to another end of the particular vertical NAND string.

Abstract: Memory devices described herein are programmed and erased by physical segregation of an electrically insulating layer out of a memory material to establish a high resistance state, and by re-absorption of at least a portion of the electrically insulating layer into the memory material to establish a low resistance state. The physical mechanism of programming and erasing includes movement of structure vacancies to form voids, and/or segregation of doping material and bulk material, to create the electrically insulating layer consisting of voids and/or dielectric doping material along an inter-electrode current path between electrodes.

Abstract: Memory devices and methods for operating such devices are described herein. A method as described herein includes applying a fixed sequence of voltage pulses across the memory cell of increasing pulse height to change the resistance state from the lower resistance state to the higher resistance state. The fixed sequence of voltage pulses cause increasing current through the phase change memory element until change to the higher resistance state occurs, and after the change the voltage pulses in the fixed sequence causing a voltage across the phase change memory element less than the threshold voltage.

Abstract: The invention provides a semiconductor cell comprising a gate, a dielectric layer, a channel layer, a source region, a drain region and an oxide region. The dielectric layer is adjacent to the gate. The channel layer is adjacent to the dielectric layer and is formed above a source region, a drain region, and an oxide region.

Abstract: A phase change memory device and a method for programming the same. The method includes determining a characterized lowest SET current and corresponding SET resistance for the phase change memory device. The method includes determining a characterized RESET current slope for the phase change memory device. The method also includes calculating a first current amplitude for a RESET pulse based on the characterized lowest SET current and the characterized RESET current slope. The method includes applying the RESET pulse to a target memory cell in the phase change memory device and measuring the resistance of the target memory cell. If the measured resistance is substantially less than a target resistance, the method further includes applying one or more additional RESET pulses. In one embodiment of the invention, the one or more additional RESET pulses have current amplitudes greater than a previously applied RESET pulse.

Abstract: A method of programming a phase change device includes selecting a desired threshold voltage (Vth) and applying a programming pulse to a phase change material in the phase change device. The applying of the programming pulse includes applying a quantity of energy to the phase change material to drive at least a portion of this material above a melting energy level. A portion of the energy applied to the phase change material is allowed to dissipate below the melting energy level. The shape of the energy dissipation from the phase change material is controlled until the energy applied to the phase change material is less than a quenched energy level, to cause the phase change device to have the desired Vth. A remaining portion of the energy applied to the phase change material is allowed to dissipate to an environmental level.

Abstract: Memory devices and methods for operating such devices are described herein. A method is described herein for operating a memory cell comprising phase change material and programmable to a plurality of resistance states including a high resistance state and a lower resistance state. The method comprises applying a first bias arrangement to the memory cell to establish the lower resistance state, the first bias arrangement comprising a first voltage pulse. The method further comprises determining whether the memory cell is in the lower resistance state, and if the memory cell is not in the lower resistance state then applying a second bias arrangement to the memory cell. The second bias arrangement comprises a second voltage pulse having a pulse height greater than that of the first voltage pulse.

Abstract: A phase change memory device and a method for programming the same. The method includes determining a characterized lowest SET current and corresponding SET resistance for the phase change memory device. The method includes determining a characterized RESET current slope for the phase change memory device. The method also includes calculating a first current amplitude for a RESET pulse based on the characterized lowest SET current and the characterized RESET current slope. The method includes applying the RESET pulse to a target memory cell in the phase change memory device and measuring the resistance of the target memory cell. If the measured resistance is substantially less than a target resistance, the method further includes applying one or more additional RESET pulses. In one embodiment of the invention, the one or more additional RESET pulses have current amplitudes greater than a previously applied RESET pulse.

Abstract: A method of accessing memory cells is disclosed. A first signal is sent to at least one layer select transistor. The at least one layer select transistor is activated based on the first signal. Signals are communicated to or from one or more memory cells based on the activated at least layer select transistor.