Abstract: Improving memory retention properties of a polymer memory cell are disclosed. The methods include providing a semiconducting polymer layer containing at least one organic semiconductor and at least one of a carrier ion oxidation preventer and an electrode oxidation preventer. The oxidation preventers may contain at least one of 1) an oxygen scavenger, 2) a polymer with oxidizable side-chain groups which can be preferentially oxidized over the carrier ions/electrodes, and 3) an oxidizable molecule that can be preferentially oxidized over the carrier ions/electrodes.

Abstract: A memory cell made of at least two electrodes with a controllably conductive media between the at least two electrodes is disclosed. The controllably conductive media includes a passive layer made of super ionic material and an active layer. When an external stimuli, such as an applied electric field, is imposed upon the first and second electrode, ions move and dope and/or de-dope the polymer. The applied external stimuli used to dope the polymer is larger than an applied external stimuli to operate the memory cell. The polymer functions as a variable breakdown characteristic diode with electrical characteristics which are a consequence of the doping degree. The memory element may have a current limited read signal. Methods of making the memory devices/cells, methods of using the memory devices/cells, and devices such as computers, hand-held electronic devices and memory devices containing the memory cell(s) are also disclosed.

Abstract: Systems and methods are disclosed that facilitate extending data retention time in a data retention device, such as a nanoscale resistive memory cell array, via assessing a resistance level in a tracking element associated with the memory array and refreshing the memory array upon a determination that the resistance of the tracking element has reached or exceeded a predetermined reference threshold resistance value. The tracking element can be a memory cell within the array itself and can have an initial resistance value that is substantially higher than an initial resistance value for a programmed memory cell in the array, such that resistance increase in the tracking cell will cause the tracking cell to reach the threshold value and trigger refresh of the array before data corruption/loss occurs in the core memory cells.

Abstract: The present invention is a method of undertaking a procedure on a memory-diode, wherein a memory-diode is provided which is programmable so as to have each of a plurality of different threshold voltages. A reading of the state of the memory-diode indicates the so determined threshold voltage of the memory-diode.

Abstract: Systems and methods are disclosed that facilitate extending data retention time in a data retention device, such as a nanoscale resistive memory cell array, via assessing a resistance level in a tracking element associated with the memory array and refreshing the memory array upon a determination that the resistance of the tracking element has reached or exceeded a predetermined reference threshold resistance value. The tracking element can be a memory cell within the array itself and can have an initial resistance value that is substantially higher than an initial resistance value for a programmed memory cell in the array, such that resistance increase in the tracking cell will cause the tracking cell to reach the threshold value and trigger refresh of the array before data corruption/loss occurs in the core memory cells.

Abstract: Improving memory retention properties of a polymer memory cell are disclosed. The methods include providing a semiconducting polymer layer containing at least one organic semiconductor and at least one of a carrier ion oxidation preventer and an electrode oxidation preventer. The oxidation preventers may contain at least one of 1) an oxygen scavenger, 2) a polymer with oxidizable side-chain groups which can be preferentially oxidized over the carrier ions/electrodes, and 3) an oxidizable molecule that can be preferentially oxidized over the carrier ions/electrodes.

Abstract: The present memory device has first and second electrodes, a passive layer between the first and second electrodes and on and in contact with the first electrode, and an active layer between the first and second electrodes and on and in contact with the passive layer and second electrode, for receiving a charged specie from the passive layer. The active layer is a mixture of (i) a first polymer, and (ii) a second polymer for enhancing ion transport, improving the interface and promoting a rapid and substantially uniform distribution of the charged specie in the active layer, i.e., preventing a localized injection of the charged species. These features result in a memory element with improved stability, a more controllable ON-state resistance, improved switching speed and a lower programming voltage.

Abstract: Systems and methodologies are provided for adjusting threshold associated with a polymer memory cell's operation by applying thereupon a regulated electric field and/or voltage pulse width, during a post fabrication stage. Such customization of programming thresholds can typically be obtained at any cycle of programming the memory cell, to increase flexibility in circuit design. Accordingly, the present invention supplies both a current-voltage domain, and/or a frequency-time domain, to facilitate adjusting the program thresholds of the polymer memory cell.

Abstract: The present invention is a method of programming a memory device, wherein different levels or magnitudes of current may be applied to and imposed on the memory device so that any one of a plurality of memory states may be realized. A read step indicates the so determined state of the memory device.

Abstract: Systems and methodologies are provided for activating a polymer memory cell(s) after production by subjecting the polymer memory cell to an electrical field, for an initialization thereof. Such initialization can facilitate the distribution and mobility of metal ions (or charged metallic molecules) within an active layer of the polymer memory cell. The memory cell can include various layers of alternating passive and active media, which are sandwiched between conducting electrode layers.

Abstract: The present memory structure includes first and second electrodes, a passive layer, and an active layer containing nitrogen, the passive and active layers being between the first and second electrodes. Metal ions in the active layer bind to the nitrogen thereof, enhancing retention of the metal ions in the active layer for improved, stable data retention.

Abstract: System(s) and method(s) of improving and controlling memory cell data retention are disclosed. A particular pulse width and magnitude is generated and applied to a memory cell made of at least two electrodes with a controllably conductive media between the at least two electrodes. The current across the memory cell is detected and a lower input pulse is sent to the memory cell. Application of the lower pulse controls the data retention of the memory cell without disturbing the final programming state of the memory cell.

Abstract: The present memory device includes first and second electrodes, a passive layer between the first and second electrodes and an active layer between the first and second electrodes, the active layer being of a material containing randomly oriented pores which are interconnected to form passages through the active layer.

Abstract: The present invention is a method of programming a memory device, wherein different levels or magnitudes of current may be applied to and imposed on the memory device so that any one of a plurality of memory states may be realized. A read step indicates the so determined state of the memory device.

Abstract: Systems and methodologies are provided for simplifying a polymer memory cell's operation by employing a post polymer growth treatment to form ionic or super ionic metal compounds therein. Such post polymer growth treatment facilitates distribution and mobility of metal ions (or charged metallic molecules) within an active layer of the polymer memory cell, and mitigates (or eliminates) a need for initialization procedures. Moreover, the post treatment of the present invention can also facilitate controlling a distribution of various thresholds (e.g., write and erase threshold), and set them to predetermined values Accordingly, variability in threshold values of polymer memory cells that can result from initialization processes can be mitigated (or eliminated), and thicker polymer layers can be employed without an initialization penalty.

Abstract: A memory cell made of at least two electrodes with a controllably conductive media between the at least two electrodes is disclosed. The controllably conductive media includes a passive layer made of super ionic material and an active layer. When an external stimuli, such as an applied electric field, is imposed upon the first and second electrode, ions move and dope and/or de-dope the polymer. The applied external stimuli used to dope the polymer is larger than an applied external stimuli to operate the memory cell. The polymer functions as a variable breakdown characteristic diode with electrical characteristics which are a consequence of the doping degree. The memory element may have a current limited read signal. Methods of making the memory devices/cells, methods of using the memory devices/cells, and devices such as computers, hand-held electronic devices and memory devices containing the memory cell(s) are also disclosed.

Abstract: A memory element includes a first electrode, a passive layer on and in contact with the first electrode, a polyfluorene active layer on and in contact with the active layer, and a second electrode on and in contact with the polyfluorene active layer. The chemical structure of the polyfluorene active layer may be altered to take different forms, each providing a different memory element operating characteristic.

Abstract: The present memory device has first and second electrodes, a passive layer between the first and second electrodes and on and in contact with the first electrode, and an active layer between the first and second electrodes and on and in contact with the passive layer and second electrode, for receiving a charged specie from the passive layer. The active layer is a mixture of (i) a first polymer, and (ii) a second polymer for enhancing ion transport, improving the interface and promoting a rapid and substantially uniform distribution of the charged specie in the active layer, i.e., preventing a localized injection of the charged species. These features result in a memory element with improved stability, a more controllable ON-state resistance, improved switching speed and a lower programming voltage.

Abstract: A test system having a feedback loop that facilitates adjusting an output test waveform to a DUT/CUT (Device Under Test/Circuit Under Test) on-the-fly according to changing DUT/CUT parameters. The system includes a tester having an arbitrary waveform generator (AWG) and a data acquisition system (DAS) that monitors the status of the DUT/CUT. The AWG and DAS connect to the DUT/CUT through a feedback loop where the AWG outputs the test waveform to the DUT/CUT, the DAS monitors the DUT/CUT parameters, and the DAS analyzes and communicates changes to the AWG to effect changes in the output waveform, when desired. The AWG builds the output waveform in small slices (or segments) that are assembled together through a process of selection and calibration. The feedback architecture facilitates a number of changes in the output waveform, including a change in the original order of the preassembled slices, and changes in the magnitude/shape of the output waveform.

Abstract: Systems and methodologies are provided for adjusting threshold associated with a polymer memory cell's operation by applying thereupon a regulated electric field and/or voltage pulse width, during a post fabrication stage. Such customization of programming thresholds can typically be obtained at any cycle of programming the memory cell, to increase flexibility in circuit design. Accordingly, the present invention supplies both a current-voltage domain, and/or a frequency-time domain, to facilitate adjusting the program thresholds of the polymer memory cell.