Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line has left and right portions. Spike current suppression is implemented by charge screening structures. The charge screening structures are formed by laterally integrating insulating layers into selected interior regions of the left and/or right portions of the access line. The insulating layers vertically separate the access line into top and bottom conductive portions above and below the insulating layers. For memory cells located overlying or underlying the insulating layers, the resistance to each memory cell is increased because the cell is accessed using only the higher resistance path of the top or bottom conductive portion.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line is formed of a conductive material (e.g., tungsten). The access line includes one or more resistive layers (e.g., tungsten silicon nitride) each having a resistivity greater than the resistivity of the conductive material used to form the access line. The resistive layers are formed overlying or underlying at least a portion of the memory cells. A driver is electrically connected to the access line using a via. The driver generates a voltage on the access line to access the memory cells.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line has left and right portions. A conductive layer is positioned in the access line between the left and right portions. The conductive layer is formed in a socket that has been etched or otherwise formed in the access line to provide an opening. This opening is filled by the conductive layer. The conductive layer electrically connects the left and right portions of the access line to a via. A driver is electrically connected to the via for generating a voltage on the access line for accessing one or more memory cells.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a crosspoint memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line is formed of a conductive material (e.g., tungsten). The access line includes one or more resistive layers (e.g., tungsten silicon nitride) each having a resistivity greater than the resistivity of the conductive material used to form the access line. The resistive layers are formed overlying or underlying at least a portion of the memory cells. A driver is electrically connected to the access line using a via. The driver generates a voltage on the access line to access the memory cells.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line is split into left and right portions. Each portion is electrically connected to a single via, which a driver uses to generate a voltage on the access line. To reduce electrical discharge associated with current spikes, a first resistor is located between the left portion and the via, and a second resistor is located between the right portion and the via.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line is split into left and right portions. Each portion is electrically connected to a single via, which a driver uses to generate a voltage on the access line. To reduce electrical discharge associated with current spikes, a first resistor is located between the left portion and the via, and a second resistor is located between the right portion and the via.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line has left and right portions. A conductive layer is positioned in the access line between the left and right portions. The conductive layer is formed in a socket that has been etched or otherwise formed in the access line to provide an opening. This opening is filled by the conductive layer. The conductive layer electrically connects the left and right portions of the access line to a via. A driver is electrically connected to the via for generating a voltage on the access line for accessing one or more memory cells.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line has left and right portions. Spike current suppression is implemented by charge screening structures. The charge screening structures are formed by laterally integrating insulating layers into selected interior regions of the left and/or right portions of the access line. The insulating layers vertically separate the access line into top and bottom conductive portions above and below the insulating layers. For memory cells located overlying or underlying the insulating layers, the resistance to each memory cell is increased because the cell is accessed using only the higher resistance path of the top or bottom conductive portion.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line is split into left and right portions. Each portion is electrically connected to a single via, which a driver uses to generate a voltage on the access line. To reduce electrical discharge associated with current spikes, a first resistor is located between the left portion and the via, and a second resistor is located between the right portion and the via.

Abstract: Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line has left and right portions. Spike current suppression is implemented by charge screening structures. The charge screening structures are formed by laterally integrating insulating layers into selected interior regions of the left and/or right portions of the access line. The insulating layers vertically separate the access line into top and bottom conductive portions above and below the insulating layers. For memory cells located overlying or underlying the insulating layers, the resistance to each memory cell is increased because the cell is accessed using only the higher resistance path of the top or bottom conductive portion.