Abstract: A system and technique is disclosed for writing data in a cross-point memory. The state of one or more memory cells of the cross-point memory are sensed and then are continued to be selected and left on. It is then determined which of the one or more memory cells are to change state based on incoming user data that is to be written into the one or more memory cells. The one or more memory cells determined to change state and are still selected to be on are then written by applying a write-current pulse to the memory cells. In one exemplary embodiment, the one or more memory cells comprise one or more phase-change-type memory cell devices.

Abstract: Nonvolatile memory (e.g. phase change memory) devices, systems, and methods of programming the nonvolatile memory including sensing of a snapback current using a set demarcation voltage for set bit mapped cells and a reset demarcation voltage for reset bit mapped cells before selective writes.

Abstract: Threshold switching devices demonstrating transient current protection through both insulation and repair current mechanisms, including associated systems and methods, are provided and discussed.

Abstract: Phase change material can be set with a multistage set process. Set control logic can heat a phase change semiconductor material (PM) to a first temperature for a first period of time. The first temperature is configured to promote nucleation of a crystalline state of the PM. The control logic can increase the temperature to a second temperature for a second period of time. The second temperature is configured to promote crystal growth within the PM. The nucleation and growth of the crystal set the PM to the crystalline state. The multistage ramping up of the temperature can improve the efficiency of the set process relative to traditional approaches.

Abstract: In one embodiment, an apparatus comprises read circuitry to apply a read voltage to a three dimensional crosspoint (3DXP) memory cell; and write setback circuitry to apply a first setback pulse having a first magnitude to the 3DXP memory cell in response to the application of the read voltage, wherein applying the first setback pulse comprises bypassing a current mirror that is to limit or control a magnitude of a second setback pulse applied to the 3DXP memory cell when the current mirror is coupled to the 3DXP memory cell.

Abstract: Apparatuses for increasing the voltage budget window of a memory array are described. One or more pre-bias voltages may be applied across a selected cell by providing voltages to memory access lines coupled to the selected cell. The threshold voltage of the selected cell may decrease responsive to the pre-bias voltage. Conversely, threshold voltage of deselected cells coupled to only one of the memory access lines coupled to the selected cell may increase responsive to the pre-bias voltage. The decrease of the threshold voltage of the selected cell and the increase of the threshold voltage of the deselected cells may increase the voltage window of the memory array.

Abstract: In one embodiment, an apparatus comprises a memory array comprising a plurality of phase change memory (PCM) cells; and a controller to determine to read data stored by the plurality of PCM cells independent of a read command from a host device; and in response to the determination to read data stored by the plurality of PCM cells independent of a read command from a host device, perform a dummy read operation on the plurality of PCM cells and perform an additional read operation on the plurality of PCM cells.

Abstract: Uncorrectable memory errors may be reduced by determining a logical array address for a set of memory arrays and transforming the logical array address to at least two unique array addresses based, at least in part, on logical locations of at least two memory arrays within the set of memory arrays. The at least two memory arrays are then accessed using the at least two unique array addresses, respectively.

Abstract: Examples may include techniques to mitigate bias drift for memory cells of a memory device. A first memory cell coupled with a first word-line and a bit-line is selected for a write operation. A second memory cell coupled with a second word-line and the bit-line is de-selected for the write operation. First and second bias voltages are applied to the first word-line and the bit-line during the write operation to program the first memory cell. A third bias voltage is applied to the second word-line during the write operation to reduce or mitigate voltage bias to the second memory cell due to the second bias voltage applied to the bit-line to program the first memory cell.

Abstract: In one embodiment, an apparatus comprises a memory array comprising a plurality of phase change memory (PCM) cells; and a controller to determine to read data stored by the plurality of PCM cells independent of a read command from a host device; and in response to the determination to read data stored by the plurality of PCM cells independent of a read command from a host device, perform a dummy read operation on the plurality of PCM cells and perform an additional read operation on the plurality of PCM cells.

Abstract: The present disclosure relates to phase change memory control. An apparatus includes a memory controller. The memory controller includes a word line (WL) control module and a bit line (BL) control module. The memory controller is to determine a WL address based, at least in part, on a received memory address. The memory controller is further to determine a BL address. The apparatus further includes a parameter selection module to select a value of a control parameter based, at least in part, on at least one of the WL address and/or the BL address.

Abstract: A system and technique is disclosed for writing data in a cross-point memory. The state of one or more memory cells of the cross-point memory are sensed and then are continued to be selected and left on. It is then determined which of the one or more memory cells are to change state based on incoming user data that is to be written into the one or more memory cells. The one or more memory cells determined to change state and are still selected to be on are then written by applying a write-current pulse to the memory cells. In one exemplary embodiment, the one or more memory cells comprise one or more phase-change-type memory cell devices.

Abstract: Examples may include techniques to mitigate bias drift for memory cells of a memory device. A first memory cell coupled with a first word-line and a bit-line is selected for a write operation. A second memory cell coupled with a second word-line and the bit-line is de-selected for the write operation. First and second bias voltages are applied to the first word-line and the bit-line during the write operation to program the first memory cell. A third bias voltage is applied to the second word-line during the write operation to reduce or mitigate voltage bias to the second memory cell due to the second bias voltage applied to the bit-line to program the first memory cell.

Abstract: A single memory cell array is formed to maintain current delivery and mitigate current spike through the deposition of resistive materials in two or more regions of the array, including at least one region of memory cells nearer to contacts on the conductive lines and at least one region of memory cells farther from the contacts, where the contacts connect the conductive lines to the current source. Higher and lower resistive materials are introduced during the formation of the memory cells and the conductive lines based on the boundaries and dimensions of the two or more regions using a photo mask. Multiple memory cell arrays formed to maintain current delivery and mitigate current spike can be arranged into a three-dimensional memory cell array. The regions of memory cells in each memory cell array can vary depending on resistance at the contacts on the conductive lines that provide access to the memory cells, where the resistance can vary from one memory cell array to another.

Abstract: In one embodiment, an apparatus comprises read circuitry to apply a read voltage to a three dimensional crosspoint (3DXP) memory cell; and write setback circuitry to apply a first setback pulse having a first magnitude to the 3DXP memory cell in response to the application of the read voltage, wherein applying the first setback pulse comprises bypassing a current mirror that is to limit or control a magnitude of a second setback pulse applied to the 3DXP memory cell when the current mirror is coupled to the 3DXP memory cell.

Abstract: In an embodiment, a memory controller may determine that one or more neighboring memory cells associated with a target memory cell in a memory device are to be refreshed. The controller may generate a command associated with refreshing the one or more neighboring memory cells. The controller may transfer the command from the memory controller to the memory device containing the target memory cell. The command may direct the memory device to refresh the neighboring memory cells and/or return one or more addresses associated with the neighboring memory cells.

Abstract: The present disclosure relates to phase change memory control. An apparatus includes a memory controller. The memory controller includes a word line (WL) control module and a bit line (BL) control module. The memory controller is to determine a WL address based, at least in part, on a received memory address. The memory controller is further to determine a BL address. The apparatus further includes a parameter selection module to select a value of a control parameter based, at least in part, on at least one of the WL address and/or the BL address.

Abstract: Threshold switching devices demonstrating transient current protection through both insulation and repair current mechanisms, including associated systems and methods, are provided and discussed.

Abstract: Apparatus, systems, and methods for error correction in memory are described. In one embodiment, a controller comprises logic to receive a read request from a host device for data stored in a memory, retrieve the data and an associated error correction codeword, send the data to a host device, apply an error correction routine to decode the error correction codeword retrieved with the data, and in response to an error in the error correction codeword, send a location of data associated with the error to the host device. Other embodiments are also disclosed and claimed.

Abstract: Uncorrectable memory errors may be reduced by determining a logical array address for a set of memory arrays and transforming the logical array address to at least two unique array addresses based, at least in part, on logical locations of at least two memory arrays within the set of memory arrays. The at least two memory arrays are then accessed using the at least two unique array addresses, respectively.