Abstract: Embodiments herein describe techniques for a semiconductor device including a substrate, a first inter-level dielectric (ILD) layer above the substrate, and a second ILD layer above the first ILD layer. The semiconductor device further includes a capacitor having a bottom plate above the substrate, a capacitor dielectric layer adjacent to and above the bottom plate, and a top plate adjacent to and above the capacitor dielectric layer. The bottom plate, the capacitor dielectric layer, and the top plate are within the first ILD layer or the second ILD layer. Furthermore, an air gap is formed next to the top plate and below a top surface of the second ILD layer. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques for a semiconductor device including a substrate oriented in a horizontal direction, and a memory cell including a transistor and a capacitor above the substrate. The transistor includes a gate electrode oriented in a vertical direction substantially orthogonal to the horizontal direction, and a channel layer oriented in the vertical direction, around the gate electrode and separated by a gate dielectric layer from the gate electrode. The capacitor is within an inter-level dielectric layer above the substrate. The capacitor includes a first plate coupled with a second portion of the channel layer of the transistor, and a second plate separated from the first plate by a capacitor dielectric layer. The first plate of the capacitor is also a source electrode of the transistor. Other embodiments may be described and/or claimed.

Abstract: Described herein are two transistor (2T) memory cells that use TFTs as access and gain transistors. When one or both transistors of a 2T memory cell are implemented as TFTs, these transistors may be provided in different layers above a substrate, enabling a stacked architecture. An example 2T memory cell includes an access TFT provided in a first layer over a substrate, and a gain TFT provided in a second layer over the substrate, the first layer being between the substrate and the second layer (i.e., the gain TFT is stacked in a layer above the access TFT). Stacked TFT based 2T memory cells allow increasing density of memory cells in a memory array having a given footprint area, or, conversely, reducing the footprint area of the memory array with a given memory cell density.

Abstract: Described herein are arrays of embedded dynamic random-access memory (eDRAM) cells that use TFTs as selector transistors. When at least some selector transistors are implemented as TFTs, different eDRAM cells may be provided in different layers above a substrate, enabling a stacked architecture. An example stacked TFT based eDRAM includes one or more memory cells provided in a first layer over a substrate and one or more memory cells provided in a second layer, above the first layer, where at least the memory cells in the second layer, but preferably the memory cells in both the first and second layers, use TFTs as selector transistors. Stacked TFT based eDRAM allows increasing density of memory cells in a memory array having a given footprint area, or, conversely, reducing the footprint area of the memory array with a given memory cell density.

Abstract: Described are apparatuses for improving resistive memory energy efficiency. An apparatus performs data-driven write to make use of asymmetric write switch energy between write0 and write1 operations. The apparatus comprises: a resistive memory cell coupled to a bit line and a select line; a first pass-gate coupled to the bit line; a second pass-gate coupled to the select line; and a multiplexer operable by input data, the multiplexer to provide a control signal to the first and second pass-gates or to write drivers according to logic level of the input data. An apparatus comprises circuit for performing read before write operation which avoids unnecessary writes with an initial low power read operation. An apparatus comprises circuit to perform self-controlled write operation which stops the write operation as soon as bit-cell flips. An apparatus comprises circuit for performing self-controlled read operation which stops read operation as soon as data is detected.

Abstract: Some embodiments include apparatuses having a resistive memory device and methods to apply a combination of voltage stepping current stepping and pulse width stepping during an operation of changing a resistance of a memory cell of the resistive memory device. The apparatuses also include a write termination circuit to limit drive current provided to a memory cell of the resistive memory device during a particular time of an operation performed on the memory cell. The apparatuses further include a programmable variable resistor and resistor control circuit that operate during sensing operation of the memory device.

Abstract: Some embodiments include apparatuses having a resistive memory device and methods to apply a combination of voltage stepping current stepping and pulse width stepping during an operation of changing a resistance of a memory cell of the resistive memory device. The apparatuses also include a write termination circuit to limit drive current provided to a memory cell of the resistive memory device during a particular time of an operation performed on the memory cell. The apparatuses further include a programmable variable resistor and resistor control circuit that operate during sensing operation of the memory device.

Abstract: Described are apparatuses for improving resistive memory energy efficiency. An apparatus performs data-driven write to make use of asymmetric write switch energy between write0 and write1 operations. The apparatus comprises: a resistive memory cell coupled to a bit line and a select line; a first pass-gate coupled to the bit line; a second pass-gate coupled to the select line; and a multiplexer operable by input data, the multiplexer to provide a control signal to the first and second pass-gates or to write drivers according to logic level of the input data. An apparatus comprises circuit for performing read before write operation which avoids unnecessary writes with an initial low power read operation. An apparatus comprises circuit to perform self-controlled write operation which stops the write operation as soon as bit-cell flips. An apparatus comprises circuit for performing self-controlled read operation which stops read operation as soon as data is detected.

Abstract: An apparatus is described. The apparatus includes a semiconductor chip that includes logic circuitry, embedded dynamic random access memory (DRAM) cells and embedded ferroelectric random access memory (FeRAM) cells.

Abstract: Described are apparatuses for improving resistive memory energy efficiency. An apparatus performs data-driven write to make use of asymmetric write switch energy between write0 and write1 operations. The apparatus comprises: a resistive memory cell coupled to a bit line and a select line; a first pass-gate coupled to the bit line; a second pass-gate coupled to the select line; and a multiplexer operable by input data, the multiplexer to provide a control signal to the first and second pass-gates or to write drivers according to logic level of the input data. An apparatus comprises circuit for performing read before write operation which avoids unnecessary writes with an initial low power read operation. An apparatus comprises circuit to perform self-controlled write operation which stops the write operation as soon as bit-cell flips. An apparatus comprises circuit for performing self-controlled read operation which stops read operation as soon as data is detected.

Abstract: Apparatuses for improving resistive memory energy efficiency are provided. An apparatus performs data-driven write to make use of asymmetric write switch energy between write0 and write1 operations. The apparatus comprises: a resistive memory cell coupled to a bit line and a select line; a first pass-gate coupled to the bit line; a second pass-gate coupled to the select line; and a multiplexer operable by input data, the multiplexer to provide a control signal to the first and second pass-gates or to write drivers according to logic level of the input data. An apparatus comprises circuit for performing read before write operation which avoids unnecessary writes with an initial low power read operation. An apparatus comprises circuit to perform self-controlled write operation which stops the write operation as soon as bit-cell flips. An apparatus comprises circuit for performing self-controlled read operation which stops read operation as soon as data is detected.

Abstract: Described is an apparatus and system for improving write margin in memory cells. In one embodiment, the apparatus comprises: a first circuit to provide a pulse signal with a width; and a second circuit to receive the pulse signal and to generate a power supply for the memory cell, wherein the second circuit to reduce a level of the power supply below a data retention voltage level of the memory cell for a time period corresponding to the width of the pulse signal. In one embodiment, the apparatus comprises a column of memory cells having a high supply node and a low supply node; and a charge sharing circuit positioned in the column of memory cells, the charge sharing circuit coupled to the high and low supply nodes, the charge sharing circuit operable to reduce direct-current (DC) power consumption.

Abstract: An apparatus is described that includes a bit line. The apparatus also includes first and second storage cells coupled to the bit line. The first storage cell has a first access transistor. The first access transistor is coupled to a first line resistance. The second storage cell has a second access transistor. The second access transistor is coupled to a second line resistance. The second line resistance is greater than the first line resistance. The apparatus also includes first and second drivers that are coupled to the bit line. The second driver is a stronger driver than the first driver. The apparatus also includes circuitry to select the first driver to write information into the first storage cell and select the second driver to write information into the second storage cell.

Abstract: Described is an apparatus for improving read and write margins. The apparatus comprises: a sourceline; a first bitline; a column of resistive memory cells, each resistive memory cell of the column coupled at one end to the sourceline and coupled to the first bitline at another end; and a second bitline in parallel to the first bitline, the second bitline to decouple read and write operations on the bitline for the resistive memory cell. Described is also an apparatus which comprises: a sourceline; a bitline; a column of resistive memory cells, each resistive memory cell in the column coupled at one end to the sourceline and coupled to the bitline at another end; and sourceline write drivers coupled to the bitline and the sourceline, wherein the sourceline write drivers are distributed along the column of resistive memory cells.

Abstract: Described is an apparatus including memory cell with retention using resistive memory. The apparatus comprises: memory element including a first inverting device cross-coupled to a second inverting device; a restore circuit having at least one resistive memory element, the restore circuit coupled to an output of the first inverting device; a third inverting device coupled to the output of the first inverting device; a fourth inverting device coupled to an output of the third inverting device; and a save circuit having at least one resistive memory element, the save circuit coupled to an output of the third inverting device.

Abstract: Described is an apparatus and system for improving write margin in memory cells. In one embodiment, the apparatus comprises: a first circuit to provide a pulse signal with a width; and a second circuit to receive the pulse signal and to generate a power supply for the memory cell, wherein the second circuit to reduce a level of the power supply below a data retention voltage level of the memory cell for a time period corresponding to the width of the pulse signal. In one embodiment, the apparatus comprises a column of memory cells having a high supply node and a low supply node; and a charge sharing circuit positioned in the column of memory cells, the charge sharing circuit coupled to the high and low supply nodes, the charge sharing circuit operable to reduce direct-current (DC) power consumption.

Abstract: Described is an apparatus and system for improving write margin in memory cells. In one embodiment, the apparatus comprises: a first circuit to provide a pulse signal with a width; and a second circuit to receive the pulse signal and to generate a power supply for the memory cell, wherein the second circuit to reduce a level of the power supply below a data retention voltage level of the memory cell for a time period corresponding to the width of the pulse signal. In one embodiment, the apparatus comprises a column of memory cells having a high supply node and a low supply node; and a charge sharing circuit positioned in the column of memory cells, the charge sharing circuit coupled to the high and low supply nodes, the charge sharing circuit operable to reduce direct-current (DC) power consumption.

Abstract: An apparatus is described that includes a bit line. The apparatus also includes first and second storage cells coupled to the bit line. The first storage cell has a first access transistor. The first access transistor is coupled to a first line resistance. The second storage cell has a second access transistor. The second access transistor is coupled to a second line resistance. The second line resistance is greater than the first line resistance. The apparatus also includes first and second drivers that are coupled to the bit line. The second driver is a stronger driver than the first driver. The apparatus also includes circuitry to select the first driver to write information into the first storage cell and select the second driver to write information into the second storage cell.

Abstract: Described is an apparatus for improving read and write margins. The apparatus comprises: a sourceline; a first bitline; a column of resistive memory cells, each resistive memory cell of the column coupled at one end to the sourceline and coupled to the first bitline at another end; and a second bitline in parallel to the first bitline, the second bitline to decouple read and write operations on the bitline for the resistive memory cell. Described is also an apparatus which comprises: a sourceline; a bitline; a column of resistive memory cells, each resistive memory cell in the column coupled at one end to the sourceline and coupled to the bitline at another end; and sourceline write drivers coupled to the bitline and the sourceline, wherein the sourceline write drivers are distributed along the column of resistive memory cells.

Abstract: Described is an apparatus for improving read and write margins. The apparatus comprises: a sourceline; a first bitline; a column of resistive memory cells, each resistive memory cell of the column coupled at one end to the sourceline and coupled to the first bitline at another end; and a second bitline in parallel to the first bitline, the second bitline to decouple read and write operations on the bitline for the resistive memory cell. Described is also an apparatus which comprises: a sourceline; a bitline; a column of resistive memory cells, each resistive memory cell in the column coupled at one end to the sourceline and coupled to the bitline at another end; and sourceline write drivers coupled to the bitline and the sourceline, wherein the sourceline write drivers are distributed along the column of resistive memory cells.