US20120262981A1 - Data retention structure for non-volatile memory - Google Patents
Data retention structure for non-volatile memory Download PDFInfo
- Publication number
- US20120262981A1 US20120262981A1 US13/532,381 US201213532381A US2012262981A1 US 20120262981 A1 US20120262981 A1 US 20120262981A1 US 201213532381 A US201213532381 A US 201213532381A US 2012262981 A1 US2012262981 A1 US 2012262981A1
- Authority
- US
- United States
- Prior art keywords
- ion
- volatile memory
- layer
- conductive
- set forth
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
Links
Images
Classifications
-
- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C13/00—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00
- G11C13/0002—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00 using resistive RAM [RRAM] elements
- G11C13/0007—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00 using resistive RAM [RRAM] elements comprising metal oxide memory material, e.g. perovskites
-
- H—ELECTRICITY
- H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10B—ELECTRONIC MEMORY DEVICES
- H10B63/00—Resistance change memory devices, e.g. resistive RAM [ReRAM] devices
- H10B63/20—Resistance change memory devices, e.g. resistive RAM [ReRAM] devices comprising selection components having two electrodes, e.g. diodes
- H10B63/22—Resistance change memory devices, e.g. resistive RAM [ReRAM] devices comprising selection components having two electrodes, e.g. diodes of the metal-insulator-metal type
-
- H—ELECTRICITY
- H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10B—ELECTRONIC MEMORY DEVICES
- H10B63/00—Resistance change memory devices, e.g. resistive RAM [ReRAM] devices
- H10B63/80—Arrangements comprising multiple bistable or multi-stable switching components of the same type on a plane parallel to the substrate, e.g. cross-point arrays
-
- H—ELECTRICITY
- H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N70/00—Solid-state devices without a potential-jump barrier or surface barrier, and specially adapted for rectifying, amplifying, oscillating or switching
- H10N70/20—Multistable switching devices, e.g. memristors
- H10N70/24—Multistable switching devices, e.g. memristors based on migration or redistribution of ionic species, e.g. anions, vacancies
-
- H—ELECTRICITY
- H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N70/00—Solid-state devices without a potential-jump barrier or surface barrier, and specially adapted for rectifying, amplifying, oscillating or switching
- H10N70/801—Constructional details of multistable switching devices
- H10N70/821—Device geometry
- H10N70/826—Device geometry adapted for essentially vertical current flow, e.g. sandwich or pillar type devices
-
- H—ELECTRICITY
- H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N70/00—Solid-state devices without a potential-jump barrier or surface barrier, and specially adapted for rectifying, amplifying, oscillating or switching
- H10N70/801—Constructional details of multistable switching devices
- H10N70/881—Switching materials
- H10N70/883—Oxides or nitrides
- H10N70/8833—Binary metal oxides, e.g. TaOx
-
- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C2213/00—Indexing scheme relating to G11C13/00 for features not covered by this group
- G11C2213/70—Resistive array aspects
- G11C2213/71—Three dimensional array
-
- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C2213/00—Indexing scheme relating to G11C13/00 for features not covered by this group
- G11C2213/70—Resistive array aspects
- G11C2213/77—Array wherein the memory element being directly connected to the bit lines and word lines without any access device being used
Definitions
- the present invention relates generally to non-volatile memory. More specifically, the present invention relates to thin-film structures in non-volatile memory.
- Data storage in high-density memory devices can be accomplished using a variety of techniques. Often, the technique used depends on whether or not the stored data is volatile or non-volatile. In volatile memory devices, such as SRAM and DRAM, for example, stored data is not retained when power is removed from the memory device. On the other hand, for non-volatile memory devices, such as MRAM and Flash devices, stored data is retained when power is removed from the memory device.
- volatile memory devices such as SRAM and DRAM
- non-volatile memory devices such as MRAM and Flash devices
- Resistive state memory devices are a promising new type of non-volatile memory in which data is stored in a memory element as a plurality of conductivity profiles (e.g., distinct resistive states).
- a first conductivity profile can represent a logic “1” and a second conductivity profile can represent a logic “0”.
- the first and second conductivity profiles can be set by applying a write voltage of a predetermined magnitude, polarity, and duration across the memory element during a write operation. For example, voltage pulses can be used to write a logic “1” and a logic “0”, respectively.
- reading the value of the stored data in the memory element is typically accomplished by applying a read voltage across the memory element and sensing a read current that flows through the memory element. For example, if a logic “0” represents a high resistance and a logic “1” represents a low resistance, then for a constant read voltage, a magnitude of the read current can be indicative of the resistive state of the memory element. Therefore, based on Ohm's law, the read current will be low if the data stored is a logic “0” (e.g., high resistance) or the read current will be high if the data stored is a logic “1” (e.g., low resistance). Consequently, the value of the stored data can be determined by sensing the magnitude of the read current.
- An array of two terminal memory elements can include a plurality of row conductors and a plurality of column conductors and each memory element can have a terminal connected with one of row conductors and the other terminal connected with one of the column conductors.
- the typical arrangement is a two terminal cross-point memory array where each memory element is positioned approximately at an intersection of one of the row conductors with one of the column conductors. The terminals of the memory element connect with the row and column conductors above and below it.
- a single memory element can be written by applying the write voltage across the row and column conductors the memory element is connected with.
- the memory element can be read by applying the read voltage across the row and column conductors the memory element is connected with. The read current can be sensed (e.g., measured) flowing through the row conductor or the column conductor.
- data retention that is, the ability of stored data to be retained in the absence of power.
- stored data is retained indefinitely in the absence of power.
- factors affecting data retention include but are not limited to memory element structure, material used in the memory element, and voltages applied across the memory elements during data operations, such as read and write operations.
- a read or write voltage is applied across the two terminals of a selected memory element, approximately half of the voltage potential is supplied by the row conductor and half by the column conductor. Accordingly, other memory elements having a terminal connected with the row conductor or column conductor also have a voltage potential applied across their respective terminals.
- half-select voltages may be lower for read operations, in some applications, a majority of data operations to a non-volatile memory may comprise read operations. Repeated read operations may result in numerous applications of read voltages and half-select voltages to memory elements in a memory device. The application of half-select voltages during read operation may affect data retention in half-selected memory elements. However, those skilled in the art will appreciate that some design choices will affect the extent an array is exposed to half-select voltages. For example, a page mode read might not cause the array to experience any half-select voltages during read operations.
- FIG. 2A depicts a memory element switching from a first conductivity profile to a second conductivity profile
- FIG. 2B depicts a memory element having the second conductivity profile
- FIG. 3C depicts retention of the first conductivity profile
- FIG. 4A depicts a memory element having a second conductivity profile that is unaffected by application of a first read voltage
- FIG. 4B depicts a memory element having a first conductivity profile that is unaffected by application of the first read voltage
- FIG. 4D depicts a memory element having a first conductivity profile that is unaffected by application of the second read voltage
- FIG. 6A depicts a non-ohmic device and a memory element that are electrically in series with and sandwiched between a pair of electrodes;
- FIG. 6B depicts an alternate configuration of a non-ohmic device and a memory element that are electrically in series with and sandwiched between a pair of electrodes;
- FIG. 7B depicts a schematic view of a non-volatile two-terminal cross-point array that includes a plurality of memory plugs
- FIG. 7C depicts selected, half-selected, and un-selected memory plugs in a non-volatile two-terminal cross-point array
- FIG. 8A is a cross-sectional view depicting a non-volatile two-terminal cross-point array positioned over a substrate that includes active circuitry;
- FIG. 10 is a plot depicting current loss over time for memory elements with and without ion impeding layers
- FIG. 11 depicts a memory system including a non-volatile two-terminal cross-point array
- FIG. 12 depicts an exemplary electrical system that includes at least one non-volatile two-terminal cross-point array with a data retention structure for data storage.
- the present invention is embodied in a non-volatile memory device, a non-volatile memory element, and a non-volatile memory array.
- the conductive oxide layer 101 includes mobile ions 111 that are movable between the electrolytic tunnel barrier layer 105 and the conductive oxide layer 101 in response to an electric field having a predetermined magnitude and direction, as will be described in greater detail below.
- the conductive oxide layer 101 can be a conductive perovskite. Examples of conductive perovskites include but are not limited to PCMO, LNO, LCMO, LSCO, LSMO, PMO, strontium titanate (STO), and a reduced STO.
- the thickness t 3 of the conductive oxide layer 101 will be application specific. For example, an approximate range of thicknesses can be from about 100 ⁇ to about 300 ⁇ . As one example, the thickness t 3 can be approximately 250 ⁇ .
- the conductive oxide layer 101 can be formed using microelectronics fabrication techniques that are well understood in the semiconductor art for forming thin films.
- Example fabrication techniques include but are not limited to atomic layer deposition (ALD), chemical vapor deposition (CVD), sputtering, molecular beam epitaxy (MBE), spin-on deposition, pulsed laser deposition, electron-beam (e-beam) deposition, and thermal evaporation.
- the ion impeding layer 103 is configured to substantially stop ion movement between the electrolytic tunnel barrier layer 105 and the conductive oxide layer 101 when a voltage that is less than a predetermined magnitude is applied across the memory element 120 , as will be described in greater detail below.
- the material selected for the ion impeding layer 103 will be application dependent. However, suitable materials for the ion impeding layer 103 include but are not limited to LaAlO 3 , TiO x , TaO x , AlO x , SiC, SiO x , IrO x , MgO, Pt, strontium ruthenate (SRO), and a reduced SRO.
- the electrolytic tunnel barrier layer 105 is made from an insulating material (e.g., a dielectric material) that allows ion movement.
- an insulating material e.g., a dielectric material
- electronic refers to electron or hole movement
- electrical or electrolyte refers to ion movement.
- an electrolytic tunnel barrier is a material with bulk properties of an electronic insulator that allows ionic movement but is thin enough to allow for electron tunneling.
- Suitable materials for the electrolytic tunnel barrier layer 105 include but are not limited to yttria-stabilized zirconia (YSZ), ZrO 2 , HfO 2 , and Er 2 O 3 .
- the electrolytic tunnel barrier layer 105 is operative to provide electron tunneling such that the memory element 120 has a non-linear I-V curve and the current flowing through the memory element 120 is a non-linear function of the voltage applied across the memory element 120 .
- Tunneling mechanism for the electrolytic tunnel barrier layer 105 include but are not limited to single step tunneling processes (e.g., direct tunneling, Fowler-Nordheim tunneling, and thermionic field emission tunneling) and multi-step tunneling processes (e.g., trap-assisted tunneling).
- the material and thickness t 1 for the electrolytic tunnel barrier layer 105 will be application dependent.
- the thickness t 1 of the electrolytic tunnel barrier layer 105 is approximately 100 ⁇ or less. More preferably, the thickness t 1 is approximately 50 ⁇ or less. For example, the thickness t 1 can be approximately 25 ⁇ .
- the electrolytic tunnel barrier layer 105 is too thick, tunneling may not occur or the voltage across the memory element 120 necessary for tunneling may be too high. For example, currents generated by the applied voltage may exceed current density limitations of the memory element and/or conductive array lines, the resulting electric field generated by the applied voltage may exceed breakdown limits of the thin film materials in the memory element, or the magnitude of the applied voltage may require driver circuitry that exceeds an area budget for a memory design.
- the thickness t 2 for the ion impeding layer 103 is approximately no greater than the thickness t 1 for the electrolytic tunnel barrier layer 105 (e.g., t 2 ⁇ t 1 ). If the ion impeding layer 103 is too thick, device currents may be too low and/or the mobile ions 111 may not be able to travel through the ion impeding layer 103 .
- the thickness t 2 for the ion impeding layer 103 can be approximately 20 ⁇ .
- the ion impeding layer 103 is made from silicon carbide (SiC), then the thickness t 2 can be approximately 10 ⁇ .
- the ion impeding layer 103 and the electrolytic tunnel barrier layer 105 may be formed using the fabrication techniques described above for the conductive oxide layer 101 .
- the memory element 120 stores data as a plurality of conductivity profiles (e.g., resistive states).
- One of the conductivity profiles may be indicative of a first resistive state (e.g., a logic 1 or an erased state) and another one of the conductivity profiles may be indicative of a second resistive state (e.g., a logic 0 or a programmed state).
- the mobile ions 111 are positioned in the conductive oxide layer 101 and the memory element 120 can store data as the first conductivity profile (e.g., erased state or logic 1).
- a magnitude and polarity of the first write voltage V W1 is operative to generate a first electric field E 1 having a magnitude sufficient to cause a quantity of the mobile ions 111 to move from the conductive oxide layer 101 , through the ion impeding layer 103 , and into the electrolytic tunnel barrier layer 105 .
- the first electric field E 1 has a plurality of magnitudes depending on the dielectric constant and conductivity of the specific materials being used for the memory element 120 .
- the mobile ions 111 depicted in FIG. 2A have a negative charge and move in a direction that is opposite that of the first electric field E 1 .
- the mobile ions 111 can be negatively charged oxygen ions (O ⁇ ).
- the charge of the mobile ions 111 is not limited to negatively charge species of ions and in some applications the mobile ions 111 may be positively charged ions.
- a quantity 211 of the mobile ions 111 have moved from the conductive oxide layer 101 , through the ion impeding layer 103 , and into the electrolytic tunnel barrier layer 105 after the first electric field E 1 was applied.
- Reference to a quantity may include some or all of the mobile ions 111 .
- the switch 203 is opened and the first write voltage V W1 is no longer applied across the memory element 120 .
- the ion impeding layer 103 is also operative to substantially stop movement of the quantity 211 .
- the term “quantity” refers only to those ions that are impeded by the ion impeding layer 103 and not any ions that may not be impeded.
- the relocation of the mobile ions 111 in the conductive oxide layer 101 to the electrolytic tunnel barrier layer 105 results in a change in electrical conductivity of the memory element 120 such that its conductivity profile is switched from the first conductivity profile present in FIG. 1 to a second conductivity profile present in FIGS. 2B and 2C .
- the application of the first write voltage V W1 has effectuated a writing of new data to the memory element 120 and the second conductivity profile is indicative of the new data.
- the second conductivity profile is indicative of a logic 0 or a programmed state of the memory element 120 .
- the memory element 120 is depicted with the quantity 211 still positioned in the electrolytic tunnel barrier layer 105 such that the memory element stores data as the second conductivity profile.
- the voltage source 201 , the switch 203 , and their connection with nodes ( 202 , 204 ) are not depicted. However, like the configuration 200 depicted in FIG. 2B , the stored data (e.g., the second conductivity profile) is retained in the absence of power.
- the memory element 120 may be one of a plurality of memory elements 120 in a non-volatile memory device, such as a removable memory device (e.g., a SD card or USB Thumb Drive).
- the configuration 200 may represent the non-volatile memory device when it is inserted into a host system and the configuration 220 may represent the non-volatile memory device when it is removed from the host system.
- the ion impeding layer 103 is operative to improve retention of stored data in each of the plurality of memory elements 120 in the memory device. Consequently, data retention, that is, the ability of the memory element 120 to retain stored data over a period of time in the absence of power, is enhanced by the ion impeding layer 103 .
- a second write configuration 300 includes a voltage source 301 configured to apply a second write V W2 voltage across the memory element 120 at nodes ( 202 , 204 ).
- the memory element 120 Prior to the application of the second write voltage V W2 , the memory element 120 stores data as the second conductivity profile.
- a switch 303 is closed and the second write voltage V W2 generates a second electric filed E 2 having a magnitude sufficient to move the quantity 211 from the electrolytic tunnel barrier layer 105 , through the ion impeding layer 103 , and back into the conductive oxide layer 101 . Based on the direction of the second electric filed E 2 and the direction of movement of the quantity 211 , the mobile ions have a negative charge.
- the switch 303 is open; however, the application of the second write voltage V W2 has reversibly switched the conductivity profile of the memory element 120 from the second conductivity profile (e.g., logic 0 or programmed state) to the first conductivity profile (e.g., logic 1 or erased state) and the quantity 211 that was previously disposed in the electrolytic tunnel barrier layer 105 has moved through the ion impeding layer 103 and into the conductive oxide layer 101 .
- the mobile ions now reside in the conductive oxide layer 101 and are denoted as quantity 311 .
- the re-introduction of the quantity 311 back into the conductive oxide layer 101 changes the conductivity profile of the memory element 120 .
- the ion impeding layer 103 is operative to substantially stop 305 the quantity 311 from moving back through the ion impeding layer 103 and into the electrolytic tunnel barrier layer 105 when a voltage having a magnitude that is less than the first or second write voltages (V W1 , V W2 ) is applied across the memory element 120 .
- the ion impeding layer 103 is further operative to substantially stop ion movement across the ion impeding layer 103 when the voltage applied across the memory element 120 is a read voltage or a half-select voltage.
- FIGS. 4A through 4D where a read voltage is applied across the memory element 120 at nodes ( 202 , 204 ).
- FIGS. 4A and 4B depict a voltage source 401 for generating a read voltage V R1 having a first polarity and
- FIGS. 4C and 4D depict a voltage source 431 for generating a read voltage V R2 having a second polarity that is opposite the first polarity.
- a magnitude of the read voltage is less than the magnitude of the write voltage (V W1 , V W2 ) in order to prevent previously stored data from being overwritten.
- a switch 403 connected with the voltage source 401 applies the first read voltage V R1 across the memory element 120 .
- an electric field E R1 and a read current I R1 are generated.
- a magnitude of the read current I R1 is indicative of the value (i.e., resistive state) of data stored in the memory element 120 .
- data is stored as the second conductivity profile and in FIG. 4B data is stored as the first conductivity profile.
- conventions such as logic 0 and logic 1, or programmed and erased, may be associated with the conductivity profiles.
- the ion impeding layer 103 is operative to substantially stop (see dashed arrows 405 ) ion movement between the electrolytic tunnel barrier layer 105 and the conductive oxide layer 101 as depicted in FIG. 4A and to prevent ion movement from the conductive oxide layer 101 and into the electrolytic tunnel barrier layer 105 as depicted in FIG. 4B . Consequently, the first and second conductivity profiles are not corrupted or disturbed by the application of the first read voltage V R1 .
- the direction of the electric field can enhance data retention.
- the electric fields (E R1 , E R2 ) are operative to displace the mobile ions away from the ion impeding layer 103 thereby aiding the ion impeding layer 103 in substantially stopping ion movement.
- the electric fields (E R1 , E R2 ) in FIGS. 4B and 4C are operative to displace the mobile ions ( 311 , 211 ) towards the ion impeding layer 103 .
- the ion impeding layer 103 is operative to substantially stop ion movement of the quantity of mobile ions that may be caused by internal electric fields and concentration gradients caused by ion build-up in the electrolytic tunnel barrier layer 105 and/or the conductive oxide layer 101 .
- the ion impeding layer 103 is also operative to substantially stop ion movement due to electrostatic charge repulsion 409 between ions 211 or 311 as depicted by arrows 409 .
- ions that are in close proximity to one another and having identical charges will repel one another with varying amounts of force. Absent the ion impeding layer 103 , the repelling force can cause some of the mobile ions 211 or 311 to move (e.g., drift) between the conductive oxide layer 101 and the electrolytic tunnel barrier layer 105 . Over time, that movement of ions will increase or decrease the conductivity of the conductive oxide layer 101 and corrupt the value of stored data in the memory element 120 . The mutual repulsion occurs even when no voltages are applied across the memory element 120 .
- a configuration 500 includes a pair of electrodes 501 and 503 that sandwich the memory element 120 .
- the memory element 120 is electrically in series with the pair of electrodes ( 501 , 503 ).
- the electrode 501 is in contact with the electrolytic tunnel barrier layer 105 and the electrode 503 is in contact with the conductive oxide layer 101 .
- the aforementioned read, write, and half-select voltages can be applied across the memory element 120 by connecting the voltage sources with the nodes ( 202 , 204 ).
- the pair of electrodes ( 501 , 503 ) may be made from an electrically conductive material including but not limited to a metal, a metal alloy, platinum (Pt), tungsten (W), aluminum (Al), and a conductive oxide material.
- additional thin film layers may be positioned between the electrodes ( 501 , 503 ) and the layers of the memory element 120 .
- Those layers include but are not limited to glue layers, diffusion barriers, adhesion layers, anti-reflection layers, and the like.
- an adhesion layer may be positioned between a surface 101 b of the conductive oxide layer 101 and the electrode 503 to promote adhesion between the materials of the electrode 503 and the conductive oxide layer 101 .
- a glue layer may be positioned between a surface 105 t of the electrolytic tunnel barrier layer 105 and the electrode 501 .
- the memory element 120 is electrically in series with the pair of electrodes ( 501 , 503 ) that sandwich it, the combination forms a memory element 520 where voltages for data operations (e.g., read and write voltages) may be applied to nodes ( 202 , 204 ).
- each memory element 120 can store a single bit of data as one of two distinct conductivity profiles having a first resistive state R 0 at a read voltage V R indicative of a logic “0” and a second resistive state R 1 at V R indicative of a logic “1”, where R 0 ⁇ R 1 .
- a change in conductivity, measured at the read voltage V R between R 0 and R 1 differs by a large enough factor so that a sense unit that is electrically coupled with the memory element 120 can distinguish the R 0 state from the R 1 state.
- the factor can be at least a factor of approximately 5.
- the predetermined factor is approximately 10 or more (e.g., R 0 ⁇ 1M ⁇ and R 1 ⁇ 100 k ⁇ ).
- large predetermined factors may also allow intermediate resistive states (e.g., R 00 , R 01 , R 10 , and R 11 ).
- the non-ohmic devices 611 and 621 create a non-linear I-V characteristic curve that falls within a desired operational current-voltage range for data operations (e.g., read and write operations) to the memory element 120 .
- the non-ohmic devices 611 and 621 substantially reduce or eliminate current flow when the memory element 120 is not selected for a read or write operation.
- the non-ohmic devices 611 and 621 allow data to be written to the memory element 120 when a write voltage V W of appropriate magnitude and polarity is applied across the nodes ( 202 , 204 ) of a selected memory element 120 .
- the non-ohmic devices 611 and 621 allow data to be read from the memory element 120 when a read voltage V R of appropriate magnitude and polarity is applied across the nodes ( 202 , 204 ) of a selected memory element 120 .
- An additional function of the non-ohmic devices 611 and 621 is to substantially reduce or eliminate current flow through half-selected and un-selected memory elements 120 .
- Suitable materials for the electrically conductive layers for the electrodes of the non-ohmic devices 611 and 621 include but are not limited to metals (e.g., aluminum Al, platinum Pt, palladium Pd, iridium Ir, gold Au, copper Cu, tantalum Ta, tantalum nitride TaN, titanium (Ti), and tungsten W), metal alloys, refractory metals and their alloys, and semiconductors (e.g., silicon Si).
- metals e.g., aluminum Al, platinum Pt, palladium Pd, iridium Ir, gold Au, copper Cu, tantalum Ta, tantalum nitride TaN, titanium (Ti), and tungsten W
- metal alloys e.g., aluminum Al, platinum Pt, palladium Pd, iridium Ir, gold Au, copper Cu, tantalum Ta, tantalum nitride TaN, titanium (Ti), and tungsten W
- metal alloys e.
- the non-ohmic devices ( 611 , 621 ) can include a pair of diodes connected in a back-to-back configuration (not shown), for example.
- Each of the diodes can be manufactured to only allow current to flow in a certain direction when its breakdown voltage (of a predetermined magnitude and polarity) is reached.
- the non-ohmic device 611 is positioned adjacent to electrode 501 ; whereas, in FIG. 6B , the non-ohmic device 621 is positioned adjacent to electrode 503 .
- the material for the pair of electrodes ( 501 , 503 ) will be compatible with the electrode material for the non-ohmic devices 611 and 621 .
- one of the pair of electrodes ( 501 , 503 ) can serve as one of the electrodes for the non-ohmic devices 611 and 621 .
- a non-volatile memory device 700 includes a plurality of first conductive array lines 711 (one is depicted) and a plurality of second conductive array lines 713 (one is depicted), and a plurality memory plugs 702 (one is depicted).
- Each memory plug 702 includes a first terminal 701 in electrical communication with only one of the first conductive array lines 711 and a second terminal 703 in electrical communication with only one of the second conductive array lines 713 .
- Each memory plug 702 includes a memory element 120 that is electrically in series with the first and second terminals ( 701 , 703 ) and the layers 101 , 103 , and 105 of the memory element 120 are electrically in series with one another.
- the first conductive array lines 711 may be substantially aligned with a X-axis (e.g., running from left to right on the drawing sheet) and the second conductive array lines 713 may be substantially aligned with a Y-axis (e.g., looking into the drawing sheet).
- the aforementioned read and write and voltages are applied to a selected memory plug 702 by applying the voltages across the two conductive array lines that the memory plug 702 is positioned between.
- FIG. 7A by applying the read and write and voltages at the nodes ( 202 , 204 ) stored data can be read from the selected memory plug 702 or new data can be written to the selected memory plug 702 .
- schematic view of the non-volatile memory device 700 includes the plurality of first and second conductive array lines ( 711 , 713 ) and a plurality of the memory plugs 702 connected with the plurality of first and second conductive array lines ( 711 , 713 ) by their respective first and second terminals ( 701 , 703 ).
- the plurality of first conductive array lines 711 are substantially aligned with the X-axis and define a row direction (row 731 ) and the plurality of second conductive array lines 713 are substantially aligned with the Y-axis and define a column direction (col 733 ).
- the non-volatile memory device 700 includes the selected memory plug 702 ′ positioned at the intersection of selected conductive array lines 711 ′ and 713 ′.
- Memory plugs 702 that are only connected with one of the selected conductive array lines ( 711 ′ and 713 ′) are denoted as half-selected memory plugs 702 h .
- the remaining memory plugs 702 in the memory device 700 are un-selected memory plugs 702 because there respective first and second terminals ( 701 , 703 ) are connected with conductive array lines that are not at a read or write voltage potential.
- the memory plug 702 identified with dashed line 7 A- 7 A is depicted in cross-sectional view in FIG. 7A . As was described above, the memory plugs 702 may or may not include a non-ohmic device.
- vias can be used to electrically couple the conductive array lines ( 711 , 713 ) with the active circuitry 803 .
- the active circuitry 803 may include but is not limited to address decoders, sense amps, memory controllers, data buffers, direct memory access (DMA) circuits, voltage sources for generating the read and write voltages, just to name a few.
- Active circuits 810 - 818 can be configured to apply the select voltage potentials (e.g., read and write voltage potentials) to selected conductive array lines ( 711 , 713 ).
- active circuits coupled with the conductive array lines ( 711 , 713 ) can be used to sense the read current I R from selected memory elements 120 during a read operation and the sensed current can be processed to determine the conductivity profiles (e.g., the resistive state) of the selected memory elements 120 .
- the some of the active circuits can be configured to apply an un-select voltage potential (e.g., approximately a ground potential) to the un-selected array lines ( 711 , 713 ).
- a dielectric material 811 e.g., SiO 2
- Active circuits 840 - 852 can be configured to apply the select voltage potentials (e.g., read and write voltage potentials) to selected conductive array lines (e.g., 711 a, b , . . . n, and 713 a, b , . . . n).
- the active circuits can be used to sense the read current I R from selected memory elements 120 during a read operation and can be configured to apply the un-select voltage potential to the un-selected array lines.
- a table depicts data loss in memory elements with and without the ion impeding layer 103 .
- the structure comprises a layer of PCMO (e.g., a conductive oxide layer) and a layer of YSZ (e.g., an electrolytic tunnel barrier layer) sandwiched between a pair of Pt electrodes.
- PCMO e.g., a conductive oxide layer
- YSZ e.g., an electrolytic tunnel barrier layer
- the structure comprises a layer of PCMO (e.g., conductive oxide layer 101 ), a layer of SiO x (e.g., the ion impeding layer 103 ), and a layer of YSZ (e.g., the electrolytic tunnel barrier layer 105 ) sandwiched between a pair of Pt electrodes (e.g., 501 , 503 ).
- PCMO e.g., conductive oxide layer 101
- SiO x e.g., the ion impeding layer 103
- YSZ e.g., the electrolytic tunnel barrier layer 105
- the above erase and program slope values for the memory elements with and without the ion impeding layer 103 are averaged and plotted as percent of initial current loss per decade versus time.
- Plots for erase and program states of memory elements without the ion impeding layer 103 are denoted as 1001 and 1003 respectively.
- Plots for erase and program states of memory elements 120 with the ion impeding layer 103 are denoted as 1002 and 1004 respectively.
- an exemplary memory system 1100 includes the aforementioned non-volatile two-terminal cross-point memory array 700 (array 700 hereinafter) and the plurality of first conductive and second conductive traces denoted as 711 and 713 , respectively.
- the memory system 1100 also includes an address unit 1103 and a sense unit 1105 .
- the address unit 1103 receives an address ADDR, decodes the address, and based on the address, selects at least one of the plurality of first conductive traces (denoted as 711 ′) and one of the plurality of second conductive traces (denoted as 713 ′).
- the sense unit 1105 processes the one or more currents and at least one additional signal to generate a data signal DOUT that is indicative of the stored data in the memory plug.
- the sense unit 1105 may sense current flowing through a plurality of memory plugs and processes those currents along with additional signals to generate a data signal DOUT for each of the plurality of memory plugs.
- a bus 1127 communicates the data signal DOUT to a data bus 1129 .
- the address unit 1103 receives write data DIN to be written to a memory plug specified by the address ADDR.
- a bus 1125 communicates the write data DIN from the data bus 1129 to the address unit 1103 .
- the address unit 1103 determines a magnitude and polarity of the select voltage potentials to be applied to the selected first and second conductive traces 711 ′ and 713 ′ based on the value of the write data DIN. For example, one magnitude and polarity can be used to write a logic “0” and a second magnitude and polarity can be used to write a logic “1”.
- the memory system 1100 can include dedicated circuitry that is separate from the address unit 1103 to generate the select potentials and to determine the magnitude and polarity of the select potentials.
- the memory system 1100 and its components can be electrically coupled with and controlled by an external system or device (e.g., a microprocessor or a memory controller).
- the memory system 1100 can include at least one control unit 1107 operative to coordinate and control operation of the address and sense units 1103 and 1105 and any other circuitry necessary for data operations (e.g., read and write operations) to the array 700 .
- One or more signal lines 1109 and 1111 can electrically couple the control unit 1107 with the address and sense units 1103 and 1105 .
- the control unit 1107 can be electrically coupled with an external system (e.g., a microprocessor or a memory controller) through one or more signal lines 1113 .
- one or more of the arrays 700 can be positioned over a substrate that includes active circuitry and the active circuitry can be electrically coupled with the array(s) 700 using an interconnect structure that couples signals from the active circuitry with the conductive array lines 711 and 713 .
- the busses, signal lines, control signals, the address, sense, and control units 1103 , 1105 , and 1107 can comprise the active circuitry and its related interconnect, and can be fabricated on a substrate (e.g., a silicon wafer) using a microelectronics fabrication technology, such as CMOS, for example.
- an electrical system 1200 includes a CPU 1201 that is electrically coupled 1204 with a bus 1202 , an I/O unit 1207 that is electrically coupled 1210 with the bus 1202 , and a storage unit 1205 that is electrically coupled 1208 with the bus 1202 .
- the I/O unit 1207 is electrically coupled 1212 to external sources (not shown) of input data and output data.
- the CPU 1201 can be any type of processing unit including but not limited to a microprocessor ( ⁇ P), a micro-controller ( ⁇ C), and a digital signal processor (DSP), for example.
- the storage unit 1205 stores at least a portion of the data in the aforementioned non-volatile two-terminal cross-point array as depicted in FIGS. 7A through 8B .
- Each memory array includes a plurality of the two-terminal memory elements 120 .
- the configuration of the storage unit 1205 will be application specific. Example configurations include but are not limited to one or more single layer non-volatile two-terminal cross-point arrays and one or more vertically stacked non-volatile two-terminal cross-point arrays.
- the CPU 1201 may include a memory controller (not shown) for controlling data operations to the storage unit 1205 .
- the electrical system 1200 may include the CPU 1201 and the I/O unit 1207 coupled with the bus 1202 , and a memory unit 1203 that is directly coupled 1206 with the CPU 1201 .
- the memory unit 1203 is configured to serve some or all of the memory needs of the CPU 1201 .
- the CPU 1201 and optionally the I/O unit 1207 , executes data operations (e.g., reading and writing data) to the non-volatile memory unit 1203 .
- the memory unit 1203 stores at least a portion of the data in the aforementioned non-volatile two-terminal cross-point array as depicted in FIGS. 7A through 8B .
- Each memory array includes a plurality of the two-terminal memory elements 120 .
- the configuration of the memory unit 1203 will be application specific. Example configurations include but are not limited to one or more single layer non-volatile two-terminal cross-point arrays and one or more vertically stacked non-volatile two-terminal cross-point arrays.
- data stored in the memory unit 1203 is retained in the absence of electrical power.
- Data and program instructions for use by the CPU 1201 may be stored in the memory unit 1203 .
- the CPU 1201 may include a memory controller (not shown) for controlling data operations to the non-volatile memory unit 1205 .
- the memory controller may be configured for direct memory access (DMA).
Abstract
A data retention structure in a memory element that stores data as a plurality of conductivity profiles is disclosed. The memory element can be used in a variety of electrical systems and includes a conductive oxide layer, an ion impeding layer, and an electrolytic tunnel barrier layer. A write voltage applied across the memory element causes a portion of the mobile ions to move from the conductive oxide layer, through the ion impeding layer, and into the electrolytic tunnel barrier layer thereby changing a conductivity of the memory element, or the write voltage causes a quantity of the mobile ions to move from the electrolytic tunnel barrier layer, through the ion impeding layer, and back into the conductive oxide layer. The ion impeding layer is operative to substantially stop mobile ion movement when a voltage that is less than the write voltage is applied across the memory element.
Description
- This application is a continuation of pending U.S. patent application Ser. No. 12/075,017, filed Mar. 7, 2008, the disclosure of which is herein incorporated by reference.
- The present invention relates generally to non-volatile memory. More specifically, the present invention relates to thin-film structures in non-volatile memory.
- Data storage in high-density memory devices can be accomplished using a variety of techniques. Often, the technique used depends on whether or not the stored data is volatile or non-volatile. In volatile memory devices, such as SRAM and DRAM, for example, stored data is not retained when power is removed from the memory device. On the other hand, for non-volatile memory devices, such as MRAM and Flash devices, stored data is retained when power is removed from the memory device.
- Resistive state memory devices are a promising new type of non-volatile memory in which data is stored in a memory element as a plurality of conductivity profiles (e.g., distinct resistive states). A first conductivity profile can represent a logic “1” and a second conductivity profile can represent a logic “0”. The first and second conductivity profiles can be set by applying a write voltage of a predetermined magnitude, polarity, and duration across the memory element during a write operation. For example, voltage pulses can be used to write a logic “1” and a logic “0”, respectively.
- In either case, after data has been written to the memory element, reading the value of the stored data in the memory element is typically accomplished by applying a read voltage across the memory element and sensing a read current that flows through the memory element. For example, if a logic “0” represents a high resistance and a logic “1” represents a low resistance, then for a constant read voltage, a magnitude of the read current can be indicative of the resistive state of the memory element. Therefore, based on Ohm's law, the read current will be low if the data stored is a logic “0” (e.g., high resistance) or the read current will be high if the data stored is a logic “1” (e.g., low resistance). Consequently, the value of the stored data can be determined by sensing the magnitude of the read current.
- In high density memory devices, it is desirable to pack as many memory cells as possible in the smallest area possible in order to increase memory density and data storage capacity. One factor that can have a significant impact on memory density is the number of terminals that are required to access a memory element for reading or writing. As the number of terminals required to access the memory element increases, device area increases with a concomitant decrease in areal density. Most memory technologies, such as DRAM, SRAM, and some MRAM devices, require at least three terminals to access the core memory element that stores the data. However, in some memory technologies, such as certain resistance based memories, two terminals can be used to both read and write data to/from the memory element.
- An array of two terminal memory elements can include a plurality of row conductors and a plurality of column conductors and each memory element can have a terminal connected with one of row conductors and the other terminal connected with one of the column conductors. The typical arrangement is a two terminal cross-point memory array where each memory element is positioned approximately at an intersection of one of the row conductors with one of the column conductors. The terminals of the memory element connect with the row and column conductors above and below it. A single memory element can be written by applying the write voltage across the row and column conductors the memory element is connected with. Similarly, the memory element can be read by applying the read voltage across the row and column conductors the memory element is connected with. The read current can be sensed (e.g., measured) flowing through the row conductor or the column conductor.
- One challenge for some non-volatile memories is data retention, that is, the ability of stored data to be retained in the absence of power. Ideally, stored data is retained indefinitely in the absence of power. Examples of factors affecting data retention include but are not limited to memory element structure, material used in the memory element, and voltages applied across the memory elements during data operations, such as read and write operations. When a read or write voltage is applied across the two terminals of a selected memory element, approximately half of the voltage potential is supplied by the row conductor and half by the column conductor. Accordingly, other memory elements having a terminal connected with the row conductor or column conductor also have a voltage potential applied across their respective terminals. Those un-selected memory elements are generally referred to as half-selected memory elements because one of their terminals has ½ of a read voltage potential or ½ of a write voltage potential applied to it and the other terminal is typically at a ground potential. The potential difference across the terminals is referred to as a half-select voltage. The half-select voltage can generate electric fields, that over time, can disturb (e.g., corrupt) the stored data in those memory elements. Moreover, because write voltages are typically greater in magnitude than read voltages, the half-select voltages during write operations are greater than the half-select voltages during read operations. Therefore, it is desirable for the write voltages to affect stored data only in the selected memory element(s) and not in half-selected memory elements.
- Although the magnitude of half-select voltages may be lower for read operations, in some applications, a majority of data operations to a non-volatile memory may comprise read operations. Repeated read operations may result in numerous applications of read voltages and half-select voltages to memory elements in a memory device. The application of half-select voltages during read operation may affect data retention in half-selected memory elements. However, those skilled in the art will appreciate that some design choices will affect the extent an array is exposed to half-select voltages. For example, a page mode read might not cause the array to experience any half-select voltages during read operations.
- There are continuing efforts to improve non-volatile memory.
-
FIG. 1 depicts a memory element including mobile ions and storing data as a first conductivity profile; -
FIG. 2A depicts a memory element switching from a first conductivity profile to a second conductivity profile; -
FIG. 2B depicts a memory element having the second conductivity profile; -
FIG. 2C depicts retention of the second conductivity profile; -
FIG. 3A depicts a memory element switching from the second conductivity profile to the first conductivity profile; -
FIG. 3B depicts a memory element having the first conductivity profile; -
FIG. 3C depicts retention of the first conductivity profile; -
FIG. 4A depicts a memory element having a second conductivity profile that is unaffected by application of a first read voltage; -
FIG. 4B depicts a memory element having a first conductivity profile that is unaffected by application of the first read voltage; -
FIG. 4C depicts a memory element having a second conductivity profile that is unaffected by application of a second read voltage; -
FIG. 4D depicts a memory element having a first conductivity profile that is unaffected by application of the second read voltage; -
FIG. 5 depicts a memory element electrically in series with and sandwiched by a pair of electrodes; -
FIG. 6A depicts a non-ohmic device and a memory element that are electrically in series with and sandwiched between a pair of electrodes; -
FIG. 6B depicts an alternate configuration of a non-ohmic device and a memory element that are electrically in series with and sandwiched between a pair of electrodes; -
FIG. 7A depicts a portion of a non-volatile two-terminal cross-point array including a non-volatile memory plug electrically in series with a first conductive array line and a second conductive array line; -
FIG. 7B depicts a schematic view of a non-volatile two-terminal cross-point array that includes a plurality of memory plugs; -
FIG. 7C depicts selected, half-selected, and un-selected memory plugs in a non-volatile two-terminal cross-point array; -
FIG. 8A is a cross-sectional view depicting a non-volatile two-terminal cross-point array positioned over a substrate that includes active circuitry; -
FIG. 8B is a cross-sectional view depicting a stacked non-volatile two-terminal cross-point array positioned over a substrate that includes active circuitry; -
FIG. 9 is a table depicting data for erase and program slopes for memory elements with and without ion impeding layers; -
FIG. 10 is a plot depicting current loss over time for memory elements with and without ion impeding layers; -
FIG. 11 depicts a memory system including a non-volatile two-terminal cross-point array; and -
FIG. 12 depicts an exemplary electrical system that includes at least one non-volatile two-terminal cross-point array with a data retention structure for data storage. - Although the previous drawings depict various examples of the invention, the invention is not limited by the depicted examples. Furthermore, the depictions are not necessarily to scale.
- In the following detailed description and in the several figures of the drawings, like elements are identified with like reference numerals.
- As shown in the drawings for purpose of illustration, the present invention is embodied in a non-volatile memory device, a non-volatile memory element, and a non-volatile memory array.
- Reference is now made to
FIG. 1 and similarly as inFIG. 3D where anon-volatile memory device 100 includes amemory element 120. Thememory element 120 includes aconductive oxide layer 101, an ion impeding layer, and an electrolytictunnel barrier layer 105. Thelayers memory element 120 are electrically in series with one another. Preferably, surfaces 101 b, 101 t, 103 t, and 105 t of thelayers - The
conductive oxide layer 101 includesmobile ions 111 that are movable between the electrolytictunnel barrier layer 105 and theconductive oxide layer 101 in response to an electric field having a predetermined magnitude and direction, as will be described in greater detail below. Theconductive oxide layer 101 can be a conductive perovskite. Examples of conductive perovskites include but are not limited to PCMO, LNO, LCMO, LSCO, LSMO, PMO, strontium titanate (STO), and a reduced STO. The thickness t3 of theconductive oxide layer 101 will be application specific. For example, an approximate range of thicknesses can be from about 100 Å to about 300 Å. As one example, the thickness t3 can be approximately 250 Å. Theconductive oxide layer 101 can be formed using microelectronics fabrication techniques that are well understood in the semiconductor art for forming thin films. Example fabrication techniques include but are not limited to atomic layer deposition (ALD), chemical vapor deposition (CVD), sputtering, molecular beam epitaxy (MBE), spin-on deposition, pulsed laser deposition, electron-beam (e-beam) deposition, and thermal evaporation. - The
ion impeding layer 103 is configured to substantially stop ion movement between the electrolytictunnel barrier layer 105 and theconductive oxide layer 101 when a voltage that is less than a predetermined magnitude is applied across thememory element 120, as will be described in greater detail below. The material selected for theion impeding layer 103 will be application dependent. However, suitable materials for theion impeding layer 103 include but are not limited to LaAlO3, TiOx, TaOx, AlOx, SiC, SiOx, IrOx, MgO, Pt, strontium ruthenate (SRO), and a reduced SRO. - Criteria for selecting the material for
ion impeding layer 103 may include but are not limited to a material operative as a mobility barrier to themobile ions 111, a material having a high activation energy for migration ofmobile ions 111 to vacancy sites in the material, a material having stoichiometrically too few sites for migration of themobile ions 111, and a material having a low conductivity to themobile ions 111 and having an electrical conductivity that is higher that an electrical conductivity of a material for the electrolytictunnel barrier layer 105. - The electrolytic
tunnel barrier layer 105 is made from an insulating material (e.g., a dielectric material) that allows ion movement. Those skilled in the art will appreciate that the term electronic refers to electron or hole movement, while the term electrical or electrolyte refers to ion movement. Accordingly, an electrolytic tunnel barrier is a material with bulk properties of an electronic insulator that allows ionic movement but is thin enough to allow for electron tunneling. Suitable materials for the electrolytictunnel barrier layer 105 include but are not limited to yttria-stabilized zirconia (YSZ), ZrO2, HfO2, and Er2O3. The electrolytictunnel barrier layer 105 is operative to provide electron tunneling such that thememory element 120 has a non-linear I-V curve and the current flowing through thememory element 120 is a non-linear function of the voltage applied across thememory element 120. Tunneling mechanism for the electrolytictunnel barrier layer 105 include but are not limited to single step tunneling processes (e.g., direct tunneling, Fowler-Nordheim tunneling, and thermionic field emission tunneling) and multi-step tunneling processes (e.g., trap-assisted tunneling). - The material and thickness t1 for the electrolytic
tunnel barrier layer 105 will be application dependent. Preferably, the thickness t1 of the electrolytictunnel barrier layer 105 is approximately 100 Å or less. More preferably, the thickness t1 is approximately 50 Å or less. For example, the thickness t1 can be approximately 25 Å. If the electrolytictunnel barrier layer 105 is too thick, tunneling may not occur or the voltage across thememory element 120 necessary for tunneling may be too high. For example, currents generated by the applied voltage may exceed current density limitations of the memory element and/or conductive array lines, the resulting electric field generated by the applied voltage may exceed breakdown limits of the thin film materials in the memory element, or the magnitude of the applied voltage may require driver circuitry that exceeds an area budget for a memory design. The thickness t2 for theion impeding layer 103 is approximately no greater than the thickness t1 for the electrolytic tunnel barrier layer 105 (e.g., t2≦t1). If theion impeding layer 103 is too thick, device currents may be too low and/or themobile ions 111 may not be able to travel through theion impeding layer 103. For example, the thickness t2 for theion impeding layer 103 can be approximately 20 Å. As another example, if theion impeding layer 103 is made from silicon carbide (SiC), then the thickness t2 can be approximately 10 Å. Theion impeding layer 103 and the electrolytictunnel barrier layer 105 may be formed using the fabrication techniques described above for theconductive oxide layer 101. - Referring again to
FIG. 1 , thememory element 120 stores data as a plurality of conductivity profiles (e.g., resistive states). One of the conductivity profiles may be indicative of a first resistive state (e.g., alogic 1 or an erased state) and another one of the conductivity profiles may be indicative of a second resistive state (e.g., a logic 0 or a programmed state). For example, inFIG. 1 themobile ions 111 are positioned in theconductive oxide layer 101 and thememory element 120 can store data as the first conductivity profile (e.g., erased state or logic 1). Turning now toFIG. 2A , afirst write configuration 200 includes avoltage source 201 operative to apply a first write voltage VW1 across thememory element 120. Aswitch 203 is connected with thevoltage source 201 and is operative to apply the first write voltage VW1 across thememory element 120. Conversely, when theswitch 203 is open the first write voltage VW1 is no longer applied across thememory element 120. As depicted inFIG. 2A , theswitch 203 is closed so that the first write voltage VW1 is applied across thememory element 120 atnodes mobile ions 111 to move from theconductive oxide layer 101, through theion impeding layer 103, and into the electrolytictunnel barrier layer 105. Those skilled in the art will appreciate that the first electric field E1 has a plurality of magnitudes depending on the dielectric constant and conductivity of the specific materials being used for thememory element 120. Based on the direction of the first electric field E1 and on the direction of movement of themobile ions 111, themobile ions 111 depicted inFIG. 2A have a negative charge and move in a direction that is opposite that of the first electric field E1. For example, themobile ions 111 can be negatively charged oxygen ions (O−). However, the charge of themobile ions 111 is not limited to negatively charge species of ions and in some applications themobile ions 111 may be positively charged ions. - Moving now to
FIG. 2B , aquantity 211 of themobile ions 111 have moved from theconductive oxide layer 101, through theion impeding layer 103, and into the electrolytictunnel barrier layer 105 after the first electric field E1 was applied. Reference to a quantity may include some or all of themobile ions 111. Theswitch 203 is opened and the first write voltage VW1 is no longer applied across thememory element 120. Theion impeding layer 103 is operative to substantially stop (see dashed arrows 205) thequantity 211 from moving back through theion impeding layer 103 and into theconductive oxide layer 101 unless a write voltage having a sufficient magnitude and polarity (e.g., a second write voltage as will be described below) is applied across thememory element 120. InFIG. 2B , the voltage applied across thememory element 120 is substantially 0V; however, as will be described below, a read voltage having a magnitude that is less than the write voltage can be applied across thememory element 120. Theion impeding layer 103 is further operative to substantially stop movement of thequantity 211 when the read voltage is applied across nodes (202, 204). Moreover, when thememory element 120 is half-selected such that a half-select voltage is applied across the nodes (202, 204) theion impeding layer 103 is also operative to substantially stop movement of thequantity 211. It should be appreciated by those skilled in the art that the term “quantity” refers only to those ions that are impeded by theion impeding layer 103 and not any ions that may not be impeded. - The relocation of the
mobile ions 111 in theconductive oxide layer 101 to the electrolytic tunnel barrier layer 105 (i.e., quantity 211) results in a change in electrical conductivity of thememory element 120 such that its conductivity profile is switched from the first conductivity profile present inFIG. 1 to a second conductivity profile present inFIGS. 2B and 2C . Accordingly, the application of the first write voltage VW1 has effectuated a writing of new data to thememory element 120 and the second conductivity profile is indicative of the new data. In one embodiment, the second conductivity profile is indicative of a logic 0 or a programmed state of thememory element 120. - Referring to
FIG. 2C , in aconfiguration 220, thememory element 120 is depicted with thequantity 211 still positioned in the electrolytictunnel barrier layer 105 such that the memory element stores data as the second conductivity profile. Thevoltage source 201, theswitch 203, and their connection with nodes (202, 204) are not depicted. However, like theconfiguration 200 depicted inFIG. 2B , the stored data (e.g., the second conductivity profile) is retained in the absence of power. Thememory element 120 may be one of a plurality ofmemory elements 120 in a non-volatile memory device, such as a removable memory device (e.g., a SD card or USB Thumb Drive). Therefore, theconfiguration 200 may represent the non-volatile memory device when it is inserted into a host system and theconfiguration 220 may represent the non-volatile memory device when it is removed from the host system. In either case, theion impeding layer 103 is operative to improve retention of stored data in each of the plurality ofmemory elements 120 in the memory device. Consequently, data retention, that is, the ability of thememory element 120 to retain stored data over a period of time in the absence of power, is enhanced by theion impeding layer 103. - Turning now to
FIG. 3A , asecond write configuration 300 includes a voltage source 301 configured to apply a second write VW2 voltage across thememory element 120 at nodes (202, 204). Prior to the application of the second write voltage VW2, thememory element 120 stores data as the second conductivity profile. Aswitch 303 is closed and the second write voltage VW2 generates a second electric filed E2 having a magnitude sufficient to move thequantity 211 from the electrolytictunnel barrier layer 105, through theion impeding layer 103, and back into theconductive oxide layer 101. Based on the direction of the second electric filed E2 and the direction of movement of thequantity 211, the mobile ions have a negative charge. - Moving now to
FIG. 3B , theswitch 303 is open; however, the application of the second write voltage VW2 has reversibly switched the conductivity profile of thememory element 120 from the second conductivity profile (e.g., logic 0 or programmed state) to the first conductivity profile (e.g.,logic 1 or erased state) and thequantity 211 that was previously disposed in the electrolytictunnel barrier layer 105 has moved through theion impeding layer 103 and into theconductive oxide layer 101. The mobile ions now reside in theconductive oxide layer 101 and are denoted asquantity 311. The re-introduction of thequantity 311 back into theconductive oxide layer 101 changes the conductivity profile of thememory element 120. Consequently, the application of the second write voltage VW2 has effectuated a writing of new data to thememory element 120. Theion impeding layer 103 is operative to substantially stop 305 thequantity 311 from moving back through theion impeding layer 103 and into the electrolytictunnel barrier layer 105 when a voltage having a magnitude that is less than the first or second write voltages (VW1, VW2) is applied across thememory element 120. As was described above, theion impeding layer 103 is further operative to substantially stop ion movement across theion impeding layer 103 when the voltage applied across thememory element 120 is a read voltage or a half-select voltage. - Referring now to
FIG. 3C , aconfiguration 320 depicts the memory element without the power source 301. In theconfiguration 320, theion impeding layer 103 is operative to substantially stop ion motion such that the first conductivity profile is retained in the absence of power. As was described above, the configurations depicted inFIGS. 3B and 3C may represent a non-volatile memory device when it is inserted and removed from a host system, respectively. Accordingly, the application of the first write voltage VW1, followed by the application of the second write voltage VW2, has returned thememory element 120 to the first conductivity profile depicted inFIG. 1 . Although not depicted, a re-application of the first write voltage VW1 to the configuration depicted inFIG. 3C will reversibly switch the first conductivity profile to the second conductivity profile depicted inFIGS. 2B and 2C . - Reference is now made to
FIGS. 4A through 4D where a read voltage is applied across thememory element 120 at nodes (202, 204).FIGS. 4A and 4B depict avoltage source 401 for generating a read voltage VR1 having a first polarity andFIGS. 4C and 4D depict avoltage source 431 for generating a read voltage VR2 having a second polarity that is opposite the first polarity. Regardless of read voltage polarity, a magnitude of the read voltage is less than the magnitude of the write voltage (VW1, VW2) in order to prevent previously stored data from being overwritten. For example, if the magnitude of the write voltages (VW1, VW2) is approximately 4V, then the magnitude of the read voltage can be approximately 1.5V. In some applications, the read voltage will be applied with only one polarity. In other applications, the polarity of the read voltage may be alternated (e.g., +VR and −VR). For example, approximately half of the read operations are effectuated using a first polarity and approximately half of the read operations are effectuated using a second polarity. - Referring again to
FIGS. 4A and 4B , inconfigurations switch 403 connected with thevoltage source 401 applies the first read voltage VR1 across thememory element 120. As a result, an electric field ER1 and a read current IR1 are generated. A magnitude of the read current IR1 is indicative of the value (i.e., resistive state) of data stored in thememory element 120. InFIG. 4A data is stored as the second conductivity profile and inFIG. 4B data is stored as the first conductivity profile. Depending on the application, conventions such as logic 0 andlogic 1, or programmed and erased, may be associated with the conductivity profiles. Theion impeding layer 103 is operative to substantially stop (see dashed arrows 405) ion movement between the electrolytictunnel barrier layer 105 and theconductive oxide layer 101 as depicted inFIG. 4A and to prevent ion movement from theconductive oxide layer 101 and into the electrolytictunnel barrier layer 105 as depicted inFIG. 4B . Consequently, the first and second conductivity profiles are not corrupted or disturbed by the application of the first read voltage VR1. - Turning now to
FIGS. 4C and 4D , the polarity of the read voltage VR2 is reversed. Inconfigurations switch 433 is connected with avoltage source 431 that applies the second read voltage VR2 across thememory element 120. The read voltage VR2 generates an electric field ER2 and a read current IR2 that are opposite in direction to the electric field ER1 and the read current IR1 depicted inFIGS. 4A and 4B . Nevertheless, theion impeding layer 103 is operative to substantially stop (see dashed arrows 405) ion movement from the electrolytictunnel barrier layer 105 and back into theconductive oxide layer 101 as depicted inFIG. 4C where thememory element 120 stores data as the second conductivity profile. Similarly,ion impeding layer 103 is operative to substantially stop ion movement from theconductive oxide layer 101 and into the electrolytictunnel barrier layer 105 as depicted inFIG. 4D where thememory element 120 stores data as the first conductivity profile. Consequently, the first and second conductivity profiles are not corrupted or disturbed by the application of the second read voltage VR2. - Depending on the charge or ionization state of the
mobile ions 111, the direction of the electric field can enhance data retention. InFIGS. 4A and 4D , assuming the mobile ions (211, 311) are negatively charged, the electric fields (ER1, ER2) are operative to displace the mobile ions away from theion impeding layer 103 thereby aiding theion impeding layer 103 in substantially stopping ion movement. In contrast, the electric fields (ER1, ER2) inFIGS. 4B and 4C are operative to displace the mobile ions (311, 211) towards theion impeding layer 103. Accordingly, theion impeding layer 103 must be configured to substantially stop the ion movement in the worst case scenario where the charge of the ion species and the direction of the electric field displace the mobile ions towards theion impeding layer 103. Although the above discussion focused on electric fields generated by read voltages, the same principles apply when the applied voltage is a half-select voltage, because in both cases ion motion is substantially stopped. On the other hand, in the case where the applied voltage is a write voltage, ion movement is necessary to effectuate the switching of the conductivity profile of thememory element 120. Additionally, theion impeding layer 103 is operative to substantially stop ion movement of the quantity of mobile ions that may be caused by internal electric fields and concentration gradients caused by ion build-up in the electrolytictunnel barrier layer 105 and/or theconductive oxide layer 101. - Referring again to
FIGS. 4A through 4D , theion impeding layer 103 is also operative to substantially stop ion movement due toelectrostatic charge repulsion 409 betweenions arrows 409. For example, ions that are in close proximity to one another and having identical charges will repel one another with varying amounts of force. Absent theion impeding layer 103, the repelling force can cause some of themobile ions conductive oxide layer 101 and the electrolytictunnel barrier layer 105. Over time, that movement of ions will increase or decrease the conductivity of theconductive oxide layer 101 and corrupt the value of stored data in thememory element 120. The mutual repulsion occurs even when no voltages are applied across thememory element 120. - Although the forgoing discussion has disclosed ions with negative ionization state, the ionization state of the ions is application dependent and the material selected for the
memory element 120 can include materials configured to operate with ions having a positive ionization state. - Reference is now made to
FIG. 5 where aconfiguration 500 includes a pair ofelectrodes memory element 120. Thememory element 120 is electrically in series with the pair of electrodes (501, 503). Theelectrode 501 is in contact with the electrolytictunnel barrier layer 105 and theelectrode 503 is in contact with theconductive oxide layer 101. The aforementioned read, write, and half-select voltages can be applied across thememory element 120 by connecting the voltage sources with the nodes (202, 204). The pair of electrodes (501, 503) may be made from an electrically conductive material including but not limited to a metal, a metal alloy, platinum (Pt), tungsten (W), aluminum (Al), and a conductive oxide material. Although not depicted inFIG. 5 , additional thin film layers may be positioned between the electrodes (501, 503) and the layers of thememory element 120. Those layers include but are not limited to glue layers, diffusion barriers, adhesion layers, anti-reflection layers, and the like. For example, an adhesion layer may be positioned between asurface 101 b of theconductive oxide layer 101 and theelectrode 503 to promote adhesion between the materials of theelectrode 503 and theconductive oxide layer 101. Similarly, a glue layer may be positioned between asurface 105 t of the electrolytictunnel barrier layer 105 and theelectrode 501. In that thememory element 120 is electrically in series with the pair of electrodes (501, 503) that sandwich it, the combination forms amemory element 520 where voltages for data operations (e.g., read and write voltages) may be applied to nodes (202, 204). - Moving now to
FIGS. 6A and 6B ,configurations non-ohmic device non-ohmic devices memory element 120 and the pair of electrodes (501, 503). As was discussed above, eachmemory element 120 stores data as a plurality of conductivity profiles with discrete resistances at certain voltages. Therefore, eachmemory element 120 can be schematically depicted as a resistor that is electrically in series with thenon-ohmic devices specific memory element 120 is indicative of a value of stored data in thatmemory element 120. As an example, eachmemory element 120 can store a single bit of data as one of two distinct conductivity profiles having a first resistive state R0 at a read voltage VR indicative of a logic “0” and a second resistive state R1 at VR indicative of a logic “1”, where R0≠R1. Preferably, a change in conductivity, measured at the read voltage VR, between R0 and R1 differs by a large enough factor so that a sense unit that is electrically coupled with thememory element 120 can distinguish the R0 state from the R1 state. For example, the factor can be at least a factor of approximately 5. Preferably, the predetermined factor is approximately 10 or more (e.g., R0≈1MΩ and R1≈100 kΩ). The larger the predetermined factor is, the easier it is to distinguish between resistive states R0 and R1. Furthermore, large predetermined factors may also allow intermediate resistive states (e.g., R00, R01, R10, and R11). - The resistance of the
memory element 120 may not be a linear function of the voltage applied across thememory element 120 at the nodes (202, 204). Therefore, a resistance RS of thememory elements 120 can approximately be a function of the applied voltage V such that RS≈f (V). The applied voltage V can be a read voltage, a write voltage, or a half-select voltage. Moreover, because thenon-ohmic devices memory element 120, a resulting series resistance creates a voltage drop across thenon-ohmic devices memory element 120 will be less than the voltage applied across the nodes (202, 204). As one example, if the read voltage VR≈3V and the voltage drop across thenon-ohmic devices memory element 120 is approximately 1.0V. - The
non-ohmic devices memory element 120. Thenon-ohmic devices memory element 120 is not selected for a read or write operation. Thenon-ohmic devices memory element 120 when a write voltage VW of appropriate magnitude and polarity is applied across the nodes (202, 204) of a selectedmemory element 120. Similarly, thenon-ohmic devices memory element 120 when a read voltage VR of appropriate magnitude and polarity is applied across the nodes (202, 204) of a selectedmemory element 120. An additional function of thenon-ohmic devices un-selected memory elements 120. - The
non-ohmic devices FIGS. 6A and 6B . Those layers can include a pair of electrodes that sandwich one or more layers of a dielectric material. The dielectric material(s) are operative as a tunnel barrier layer(s) that generate the non-linear I-V characteristic of thenon-ohmic devices non-ohmic devices non-ohmic devices non-ohmic devices - Alternatively, the non-ohmic devices (611, 621) can include a pair of diodes connected in a back-to-back configuration (not shown), for example. Each of the diodes can be manufactured to only allow current to flow in a certain direction when its breakdown voltage (of a predetermined magnitude and polarity) is reached.
- In
FIG. 6A , thenon-ohmic device 611 is positioned adjacent toelectrode 501; whereas, inFIG. 6B , thenon-ohmic device 621 is positioned adjacent toelectrode 503. In some applications, the material for the pair of electrodes (501, 503) will be compatible with the electrode material for thenon-ohmic devices non-ohmic devices - Reference is now made to
FIG. 7A , where anon-volatile memory device 700 includes a plurality of first conductive array lines 711 (one is depicted) and a plurality of second conductive array lines 713 (one is depicted), and a plurality memory plugs 702 (one is depicted). Eachmemory plug 702 includes afirst terminal 701 in electrical communication with only one of the firstconductive array lines 711 and asecond terminal 703 in electrical communication with only one of the second conductive array lines 713. Eachmemory plug 702 includes amemory element 120 that is electrically in series with the first and second terminals (701, 703) and thelayers memory element 120 are electrically in series with one another. The first and second terminals (701, 703) can be the pair of electrodes (501, 503) described in reference toFIGS. 5 , 6A, and 6B. As depicted inFIG. 7A , thememory plug 702 may include the above mentioned non-ohmic devices, such as thedevice 611 or the device 613 (not shown). The non-ohmic device is electrically in series with the first and second terminals (701, 703) and with thememory element 120. The position of the non-ohmic device in thememory plug 702 may be as depicted (e.g., device 611) or the non-ohmic device can be positioned between thesecond terminal 703 and thememory element 120. Although,non-ohmic device 611 is depicted, thememory plug 702 need not include a non-ohmic device and thefirst terminal 701 may be in contact with thememory element 120. - Although a coordinate system is not depicted, the first
conductive array lines 711 may be substantially aligned with a X-axis (e.g., running from left to right on the drawing sheet) and the secondconductive array lines 713 may be substantially aligned with a Y-axis (e.g., looking into the drawing sheet). The aforementioned read and write and voltages are applied to a selectedmemory plug 702 by applying the voltages across the two conductive array lines that thememory plug 702 is positioned between. InFIG. 7A , by applying the read and write and voltages at the nodes (202, 204) stored data can be read from the selectedmemory plug 702 or new data can be written to the selectedmemory plug 702. A read current IR flows through the selectedmemory plug 702, thememory element 120, and the non-ohmic device (611 or 613) if it is included in thememory plug 702. The direction of flow of the read current IR (e.g., substantially along a Z-axis) will depend on the polarity of the read voltage. For example, if a positive read voltage potential is applied to thenode 202 and a negative read voltage potential is applied to thenode 204, then the read current IR will flow from the firstconductive array line 711 to the second conductive array lines 713. In some applications, amemory cell 705, the repeatable unit that makes up the array, may include all or a portion of the conductive array lines (711, 713) as denoted by the dashed line for thememory cell 705. - Turning now to
FIG. 7B , schematic view of thenon-volatile memory device 700 includes the plurality of first and second conductive array lines (711, 713) and a plurality of the memory plugs 702 connected with the plurality of first and second conductive array lines (711, 713) by their respective first and second terminals (701, 703). The plurality of firstconductive array lines 711 are substantially aligned with the X-axis and define a row direction (row 731) and the plurality of secondconductive array lines 713 are substantially aligned with the Y-axis and define a column direction (col 733). Preferably, the first and second conductive array lines (711, 713) are arranged substantially orthogonal to each other.Conductive array lines 711′ and 713′ are selected array lines because a read or write voltage is applied to those lines at nodes (202, 204) to selectmemory plug 702′ for a data operation (e.g., read or write operation). - In
FIG. 7C , thenon-volatile memory device 700 includes the selectedmemory plug 702′ positioned at the intersection of selectedconductive array lines 711′ and 713′. Memory plugs 702 that are only connected with one of the selected conductive array lines (711′ and 713′) are denoted as half-selected memory plugs 702 h. The remaining memory plugs 702 in thememory device 700 are un-selected memory plugs 702 because there respective first and second terminals (701, 703) are connected with conductive array lines that are not at a read or write voltage potential. It should be noted that thememory plug 702 identified with dashedline 7A-7A is depicted in cross-sectional view inFIG. 7A . As was described above, the memory plugs 702 may or may not include a non-ohmic device. - Referring now to
FIG. 8A , thenon-volatile memory device 700 includes asubstrate 801 that includesactive circuitry 803 that is fabricated on thesubstrate 801. As one example, thesubstrate 801 can be a silicon (Si) wafer and the active circuitry can be microelectronic devices formed on thesubstrate 801 using a CMOS fabrication process. The memory plugs 702 and their respective conductive array lines (711, 713) can be fabricated on top of theactive circuitry 803 in thesubstrate 801. Those skilled in the art will appreciate that an inter-level interconnect structure (not shown) can electrically couple the conductive array lines (711, 713) with theactive circuitry 803 which may include several metal layers. For example, vias can be used to electrically couple the conductive array lines (711, 713) with theactive circuitry 803. Theactive circuitry 803 may include but is not limited to address decoders, sense amps, memory controllers, data buffers, direct memory access (DMA) circuits, voltage sources for generating the read and write voltages, just to name a few. Active circuits 810-818 can be configured to apply the select voltage potentials (e.g., read and write voltage potentials) to selected conductive array lines (711, 713). Moreover, active circuits coupled with the conductive array lines (711, 713) can be used to sense the read current IR from selectedmemory elements 120 during a read operation and the sensed current can be processed to determine the conductivity profiles (e.g., the resistive state) of the selectedmemory elements 120. In some applications, it may be desirable to prevent un-selected array lines (711, 713) from floating. The some of the active circuits can be configured to apply an un-select voltage potential (e.g., approximately a ground potential) to the un-selected array lines (711, 713). A dielectric material 811 (e.g., SiO2) may be used where necessary to provide electrical insulation between elements of thenon-volatile memory device 700. - In
FIG. 8B , anon-volatile memory device 820 includes a plurality of non-volatile memory arrays that are vertically stacked above one another (e.g., along the Z-axis) and are positioned above asubstrate 821 that includesactive circuitry 823. Thenon-volatile memory device 820 includes vertically stacked memory layers A and B and may include additional memory layers up to an nth memory layer. The memory layers A, B, . . . through the nth layer can be electrically coupled with theactive circuitry 823 in thesubstrate 821 by an inter-level interconnect structure as was described above. Layer A includes memory plugs 702 a and first and second conductive array lines (711 a, 713 a), Layer B includes memory plugs 702 b and first and second conductive array lines (711 b, 713 b), and if the nth layer is implemented, then the nth layer includes memory plugs 702 n and first and second conductive array lines (711 n, 713 n).Dielectric materials non-volatile memory device 820. Active circuits 840-852 can be configured to apply the select voltage potentials (e.g., read and write voltage potentials) to selected conductive array lines (e.g., 711 a, b, . . . n, and 713 a, b, . . . n). As was described above, the active circuits can be used to sense the read current IR from selectedmemory elements 120 during a read operation and can be configured to apply the un-select voltage potential to the un-selected array lines. - Turning to
FIG. 9 , a table depicts data loss in memory elements with and without theion impeding layer 103. In memory elements without theion impeding layer 103, the structure comprises a layer of PCMO (e.g., a conductive oxide layer) and a layer of YSZ (e.g., an electrolytic tunnel barrier layer) sandwiched between a pair of Pt electrodes. For the 25 Å thick YSZ, the erase and program slopes are −15.6 and 9.3 respectively. For the 30 Å thick YSZ, the erase and program slopes are −17.3 and 4.3 respectively. In contrast, for the memory element including theion impeding layer 103, the structure comprises a layer of PCMO (e.g., conductive oxide layer 101), a layer of SiOx (e.g., the ion impeding layer 103), and a layer of YSZ (e.g., the electrolytic tunnel barrier layer 105) sandwiched between a pair of Pt electrodes (e.g., 501, 503). For the 4 Å, 8 Å, and 20 Å thick SiOx layers, the values for the erase and program slopes are lower than those of the memory elements without theion impeding layer 103 and those lower values are indicative of improved data retention. - In
FIG. 10 , the above erase and program slope values for the memory elements with and without theion impeding layer 103 are averaged and plotted as percent of initial current loss per decade versus time. Plots for erase and program states of memory elements without theion impeding layer 103 are denoted as 1001 and 1003 respectively. Plots for erase and program states ofmemory elements 120 with theion impeding layer 103 are denoted as 1002 and 1004 respectively. - Reference is now made to
FIG. 11 , where anexemplary memory system 1100 includes the aforementioned non-volatile two-terminal cross-point memory array 700 (array 700 hereinafter) and the plurality of first conductive and second conductive traces denoted as 711 and 713, respectively. Thememory system 1100 also includes anaddress unit 1103 and asense unit 1105. Theaddress unit 1103 receives an address ADDR, decodes the address, and based on the address, selects at least one of the plurality of first conductive traces (denoted as 711′) and one of the plurality of second conductive traces (denoted as 713′). Theaddress unit 1103 applies select voltage potentials (e.g., read or write voltages) to the selected first and secondconductive traces 711′ and 713′. Theaddress unit 1103 also applies a non-select voltage potential tounselected traces 711 and 712. Thesense unit 1105 senses one or more currents flowing through one or more of the conductive traces. During a read operation to thearray 700, current sensed by thesense unit 1105 is indicative of stored data in a memory plug (not shown) positioned at an intersection of the selected first and secondconductive traces 711′ and 713′. Abus 1121 coupled with anaddress bus 1123 can be used to communicate the address ADDR to theaddress unit 1103. Thesense unit 1105 processes the one or more currents and at least one additional signal to generate a data signal DOUT that is indicative of the stored data in the memory plug. In some embodiments, thesense unit 1105 may sense current flowing through a plurality of memory plugs and processes those currents along with additional signals to generate a data signal DOUT for each of the plurality of memory plugs. Abus 1127 communicates the data signal DOUT to adata bus 1129. During a write operation to thearray 700, theaddress unit 1103 receives write data DIN to be written to a memory plug specified by the address ADDR. Abus 1125 communicates the write data DIN from thedata bus 1129 to theaddress unit 1103. Theaddress unit 1103 determines a magnitude and polarity of the select voltage potentials to be applied to the selected first and secondconductive traces 711′ and 713′ based on the value of the write data DIN. For example, one magnitude and polarity can be used to write a logic “0” and a second magnitude and polarity can be used to write a logic “1”. In other embodiments, thememory system 1100 can include dedicated circuitry that is separate from theaddress unit 1103 to generate the select potentials and to determine the magnitude and polarity of the select potentials. - One skilled in the art will appreciate that the
memory system 1100 and its components (e.g., 1103 and 1105) can be electrically coupled with and controlled by an external system or device (e.g., a microprocessor or a memory controller). Optionally, thememory system 1100 can include at least onecontrol unit 1107 operative to coordinate and control operation of the address andsense units array 700. One ormore signal lines control unit 1107 with the address andsense units control unit 1107 can be electrically coupled with an external system (e.g., a microprocessor or a memory controller) through one ormore signal lines 1113. - As was described above in reference to
FIGS. 8A and 8B , one or more of thearrays 700 can be positioned over a substrate that includes active circuitry and the active circuitry can be electrically coupled with the array(s) 700 using an interconnect structure that couples signals from the active circuitry with theconductive array lines FIG. 11 , the busses, signal lines, control signals, the address, sense, andcontrol units - Reference is now made to
FIG. 12 , where anelectrical system 1200 includes aCPU 1201 that is electrically coupled 1204 with abus 1202, an I/O unit 1207 that is electrically coupled 1210 with thebus 1202, and astorage unit 1205 that is electrically coupled 1208 with thebus 1202. The I/O unit 1207 is electrically coupled 1212 to external sources (not shown) of input data and output data. TheCPU 1201 can be any type of processing unit including but not limited to a microprocessor (μP), a micro-controller (μC), and a digital signal processor (DSP), for example. Via thebus 1202, theCPU 1201, and optionally the I/O unit 1207, perform data operations (e.g., reading and writing data) on thestorage unit 1205. Thestorage unit 1205 stores at least a portion of the data in the aforementioned non-volatile two-terminal cross-point array as depicted inFIGS. 7A through 8B . Each memory array includes a plurality of the two-terminal memory elements 120. The configuration of thestorage unit 1205 will be application specific. Example configurations include but are not limited to one or more single layer non-volatile two-terminal cross-point arrays and one or more vertically stacked non-volatile two-terminal cross-point arrays. In theelectrical system 1200, data stored in thestorage unit 1205 is retained in the absence of electrical power. TheCPU 1201 may include a memory controller (not shown) for controlling data operations to thestorage unit 1205. - Alternatively, the
electrical system 1200 may include theCPU 1201 and the I/O unit 1207 coupled with thebus 1202, and amemory unit 1203 that is directly coupled 1206 with theCPU 1201. Thememory unit 1203 is configured to serve some or all of the memory needs of theCPU 1201. TheCPU 1201, and optionally the I/O unit 1207, executes data operations (e.g., reading and writing data) to thenon-volatile memory unit 1203. Thememory unit 1203 stores at least a portion of the data in the aforementioned non-volatile two-terminal cross-point array as depicted inFIGS. 7A through 8B . Each memory array includes a plurality of the two-terminal memory elements 120. The configuration of thememory unit 1203 will be application specific. Example configurations include but are not limited to one or more single layer non-volatile two-terminal cross-point arrays and one or more vertically stacked non-volatile two-terminal cross-point arrays. In theelectrical system 1200, data stored in thememory unit 1203 is retained in the absence of electrical power. Data and program instructions for use by theCPU 1201 may be stored in thememory unit 1203. TheCPU 1201 may include a memory controller (not shown) for controlling data operations to thenon-volatile memory unit 1205. The memory controller may be configured for direct memory access (DMA). - Although the invention has been described in its presently contemplated best mode, it is clear that it is susceptible to numerous modifications, modes of operation and embodiments, all within the ability and skill of those familiar with the art and without exercise of further inventive activity. Furthermore, although several embodiments of the present invention have been disclosed and illustrated herein, the invention is not limited to the specific forms or arrangements of parts so described and illustrated. The invention is only limited by the claims. Accordingly, that which is intended to be protected by Letters Patent is set forth in the claims and includes all variations and modifications that fall within the spirit and scope of the claim.
Claims (28)
1. A non-volatile memory device, comprising:
a memory element (ME) having exactly two terminals, the ME including electrically in series with the two terminals
a conductive oxide layer including mobile ions,
an ion impeding layer, and
an electrolytic tunnel barrier layer,
the ME is reversibly switchable between different conductivity profiles by applying different write voltages across the two terminals, and
the ion impeding layer operative to substantially stop mobile ion movement between the electrolytic tunnel barrier layer and the conductive oxide layer when voltages other than the different write voltages are applied across the two terminals.
2. The non-volatile memory device as set forth in claim 1 , wherein the different conductivity profiles of the ME are non-destructively determined by applying a read voltage across the two terminals.
3. The non-volatile memory device as set forth in claim 1 , wherein the ion impeding layer is operative to substantially stop ion movement when a read voltage is applied across the two terminals.
4. The non-volatile memory device as set forth in claim 1 and further comprising:
a non-ohmic device sandwiched between a pair of electrodes, the non-ohmic device is electrically in series with the two terminals and with the pair of electrodes.
5. The non-volatile memory device as set forth in claim 1 , wherein the conductive oxide layer comprises a conductive perovskite.
6. The non-volatile memory device as set forth in claim 5 , wherein the conductive perovskite is a material selected from the group consisting of PCMO, LSCO, LNO, LCMO, PMO, LSMO, strontium titanate (STO), and a reduced STO.
7. The non-volatile memory device as set forth in claim 1 , wherein the electrolytic tunnel barrier layer has a first conductivity and the ion impeding layer has a second conductivity that is higher than the first conductivity.
8. The non-volatile memory device as set forth in claim 1 , wherein current flow through the ME is a non-linear function of a voltage applied across the two terminals.
9. The non-volatile memory device as set forth in claim 8 , wherein the ME includes a non-linear I-V curve.
10. The non-volatile memory device as set forth in claim 1 , wherein the mobile ions comprise mobile oxygen ions.
11. The non-volatile memory device as set forth in claim 1 , wherein the ion impeding layer is made from a material selected from the group consisting of LaAlO3, TiOx, TaOx, AlOx, SiOx, IrOx, MgO, Pt, strontium ruthenate (SRO), and a reduced SRO.
12. The non-volatile memory device as set forth in claim 1 , wherein the electrolytic tunnel barrier layer is made from an electronically insulating material.
13. The non-volatile memory device as set forth in claim 12 , wherein the electronically insulating material is a material selected from the group consisting of yttria-stabilized zirconia (YSZ), ZrO2, HfO2, and Er2O3.
14. The non-volatile memory device as set forth in claim 1 , wherein a conductivity profile of the ME is indicative of at least one bit of stored data that is retained in an absence of electrical power.
15. An electrical system, comprising:
a bus;
a processing unit in electrical communication with the bus;
an input/output (I/O) unit in electrical communication with the bus; and
a memory unit in electrical communication with the processing unit, the memory unit including
a substrate including active circuitry,
a plurality of first conductive array lines,
a plurality of second conductive array lines, and
a plurality of memory cells, each memory cell including a first terminal in electrical communication with only one of the plurality of first conductive array lines and a second terminal in electrical communication with only one of the plurality of second conductive array lines, the plurality of memory cells and the plurality of first and second conductive array lines are positioned over the substrate with the plurality of first and second conductive array lines in electrical communication with at least a portion of the active circuitry, the portion configured for data operations on the memory cells,
each memory cell including a memory element (ME) electrically in series with its respective first and second terminals, each ME having exactly two electrodes, current flow through the ME is a non-linear function of a voltage applied across the two electrodes, the ME including electrically in series with its two electrodes
a conductive oxide layer including mobile ions,
an ion impeding layer, and
an electrolytic tunnel barrier layer.
16. The electrical system of claim 15 , wherein the memory unit includes a plurality of stacked non-volatile two-terminal cross-point memory arrays.
17. A non-volatile memory element, comprising:
a first terminal;
a second terminal;
a conductive oxide layer including mobile ions;
an electrolytic tunnel barrier layer having a first thickness that is approximately 50 Å or less, the electrolytic tunnel barrier layer is permeable to the mobile ions when a write voltage is applied across the first and second terminals; and
an ion impeding layer configured to substantially stop mobile ion movement between the conductive oxide layer and the electrolytic tunnel barrier layer for voltages other than the write voltage that are applied across the first and second terminals, and
wherein the conductive oxide layer, the ion impeding layer, and the electrolytic tunnel barrier layer are electrically in series with the first and second terminals.
18. The non-volatile memory element as set forth in claim 17 , wherein the conductive oxide layer comprises a conductive perovskite.
19. The non-volatile memory element as set forth in claim 18 , wherein the conductive perovskite is a material selected from the group consisting of PCMO, LSCO, LNO, LCMO, PMO, LSMO, strontium titanate (STO), and a reduced STO.
20. The non-volatile memory element as set forth in claim 17 , wherein the ion impeding layer is made from a material selected from the group consisting of LaAlO3, TiOx, TaOx, AlOx, SiOx, IrOx, MgO, Pt, strontium ruthenate (SRO), and a reduced SRO.
21. The non-volatile memory element as set forth in claim 17 , wherein current flow through the ME is a non-linear function of a voltage applied across the first and second terminals.
22. The non-volatile memory element as set forth in claim 17 , wherein the electrolytic tunnel barrier layer is made from an electronically insulating material selected from the group consisting of yttria-stabilized zirconia (YSZ), ZrO2, HfO2, and Er2O3.
23. An electrical system, comprising:
a bus;
a processing unit in electrical communication with the bus;
an input/output (I/O) unit in electrical communication with the bus; and
a storage unit in electrical communication with the bus, the storage unit including
a substrate including active circuitry,
a plurality of first conductive array lines,
a plurality of second conductive array lines, and
a plurality of memory cells, each memory cell including a first terminal in electrical communication with only one of the plurality of first conductive array lines and a second terminal in electrical communication with only one of the plurality of second conductive array lines, the plurality of memory cells and the plurality of first and second conductive array lines are positioned over the substrate with the plurality of first and second conductive array lines in electrical communication with at least a portion of the active circuitry, the portion configured for data operations on the memory cells,
each memory cell including a memory element (ME) electrically in series with its respective first and second terminals, each ME having exactly two electrodes and including electrically in series with its two electrodes
a conductive oxide layer including mobile ions;
an electrolytic tunnel barrier layer that is permeable to the mobile ions when a write voltage is applied across the first and second terminals; and
an ion impeding layer configured to substantially stop mobile ion movement between the conductive oxide layer and the electrolytic tunnel barrier layer for voltages other than the write voltage that are applied across the first and second terminals.
24. A non-volatile memory device, comprising:
a substrate including active circuitry;
a plurality of first conductive array lines;
a plurality of second conductive array lines; and
a plurality of memory cells, each memory cell including a first terminal in electrical communication with only one of the plurality of first conductive array lines and a second terminal in electrical communication with only one of the plurality of second conductive array lines, the plurality of memory cells and the plurality of first and second conductive array lines are positioned over the substrate with the plurality of first and second conductive array lines in electrical communication with at least a portion of the active circuitry, the portion configured for data operations on the memory cells,
each memory cell including a memory element (ME) electrically in series with its respective first and second terminals, each ME having exactly two electrodes and including electrically in series with its two electrodes
a conductive oxide layer including mobile ions;
an electrolytic tunnel barrier layer that is permeable to the mobile ions when a write voltage is applied across the first and second terminals; and
an ion impeding layer configured to substantially stop mobile ion movement between the conductive oxide layer and the electrolytic tunnel barrier layer for voltages other than the write voltage that are applied across the first and second terminals.
25. The non-volatile memory device as set forth in claim 24 , wherein the electrolytic tunnel barrier layer has a first thickness that is approximately 50 Å or less.
26. The non-volatile memory device as set forth in claim 25 , wherein current flow through the ME is a non-linear function of a voltage applied across the two electrodes.
27. The non-volatile memory device as set forth in claim 24 , wherein the ion impeding layer is made from a material selected from the group consisting of LaAlO3, TiOx, TaOx, AlOx, SiOx, IrOx, MgO, Pt, strontium ruthenate (SRO), and a reduced SRO.
28. The non-volatile memory device as set forth in claim 24 , wherein the plurality of first conductive array lines have an orientation that is substantially orthogonal to the plurality of second conductive array lines and each memory cell is positioned substantially between an intersection of one of the plurality of first conductive array lines with one of the plurality of second conductive array lines.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US13/532,381 US20120262981A1 (en) | 2008-03-07 | 2012-06-25 | Data retention structure for non-volatile memory |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US12/075,017 US8208284B2 (en) | 2008-03-07 | 2008-03-07 | Data retention structure for non-volatile memory |
US13/532,381 US20120262981A1 (en) | 2008-03-07 | 2012-06-25 | Data retention structure for non-volatile memory |
Related Parent Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US12/075,017 Continuation US8208284B2 (en) | 2008-03-07 | 2008-03-07 | Data retention structure for non-volatile memory |
Publications (1)
Publication Number | Publication Date |
---|---|
US20120262981A1 true US20120262981A1 (en) | 2012-10-18 |
Family
ID=41053427
Family Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US12/075,017 Expired - Fee Related US8208284B2 (en) | 2008-03-07 | 2008-03-07 | Data retention structure for non-volatile memory |
US13/532,381 Abandoned US20120262981A1 (en) | 2008-03-07 | 2012-06-25 | Data retention structure for non-volatile memory |
Family Applications Before (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US12/075,017 Expired - Fee Related US8208284B2 (en) | 2008-03-07 | 2008-03-07 | Data retention structure for non-volatile memory |
Country Status (1)
Country | Link |
---|---|
US (2) | US8208284B2 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US10078372B2 (en) | 2013-05-28 | 2018-09-18 | Blackberry Limited | Performing an action associated with a motion based input |
Families Citing this family (25)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7082052B2 (en) | 2004-02-06 | 2006-07-25 | Unity Semiconductor Corporation | Multi-resistive state element with reactive metal |
US20060171200A1 (en) | 2004-02-06 | 2006-08-03 | Unity Semiconductor Corporation | Memory using mixed valence conductive oxides |
US8270193B2 (en) | 2010-01-29 | 2012-09-18 | Unity Semiconductor Corporation | Local bit lines and methods of selecting the same to access memory elements in cross-point arrays |
US8003511B2 (en) * | 2008-12-19 | 2011-08-23 | Unity Semiconductor Corporation | Memory cell formation using ion implant isolated conductive metal oxide |
US20130082232A1 (en) | 2011-09-30 | 2013-04-04 | Unity Semiconductor Corporation | Multi Layered Conductive Metal Oxide Structures And Methods For Facilitating Enhanced Performance Characteristics Of Two Terminal Memory Cells |
US8565003B2 (en) | 2011-06-28 | 2013-10-22 | Unity Semiconductor Corporation | Multilayer cross-point memory array having reduced disturb susceptibility |
US8208284B2 (en) * | 2008-03-07 | 2012-06-26 | Unity Semiconductor Corporation | Data retention structure for non-volatile memory |
US8263420B2 (en) * | 2008-11-12 | 2012-09-11 | Sandisk 3D Llc | Optimized electrodes for Re-RAM |
US8189364B2 (en) * | 2008-12-17 | 2012-05-29 | Qs Semiconductor Australia Pty Ltd. | Charge retention structures and techniques for implementing charge controlled resistors in memory cells and arrays of memory |
CN102365750B (en) * | 2009-03-27 | 2014-03-12 | 惠普开发有限公司 | Switchable junction with intrinsic diode |
US8045364B2 (en) * | 2009-12-18 | 2011-10-25 | Unity Semiconductor Corporation | Non-volatile memory device ion barrier |
WO2011090963A2 (en) * | 2010-01-21 | 2011-07-28 | Cornell University | Perovskite to brownmillerite complex oxide crystal structure transformation induced by oxygen deficient getter layer |
US8638584B2 (en) * | 2010-02-02 | 2014-01-28 | Unity Semiconductor Corporation | Memory architectures and techniques to enhance throughput for cross-point arrays |
US8796656B2 (en) * | 2010-06-04 | 2014-08-05 | Micron Technology, Inc. | Oxide based memory |
US8420534B2 (en) * | 2010-10-12 | 2013-04-16 | Micron Technology, Inc. | Atomic layer deposition of crystalline PrCaMnO (PCMO) and related methods |
US20120211716A1 (en) * | 2011-02-23 | 2012-08-23 | Unity Semiconductor Corporation | Oxygen ion implanted conductive metal oxide re-writeable non-volatile memory device |
US8866121B2 (en) * | 2011-07-29 | 2014-10-21 | Sandisk 3D Llc | Current-limiting layer and a current-reducing layer in a memory device |
US9299926B2 (en) * | 2012-02-17 | 2016-03-29 | Intermolecular, Inc. | Nonvolatile memory device using a tunnel oxide layer and oxygen blocking layer as a current limiter element |
US10134916B2 (en) | 2012-08-27 | 2018-11-20 | Micron Technology, Inc. | Transistor devices, memory cells, and arrays of memory cells |
KR101999342B1 (en) * | 2012-09-28 | 2019-07-12 | 삼성전자주식회사 | Resistive switching element and memory device including the same |
US9053801B2 (en) | 2012-11-30 | 2015-06-09 | Micron Technology, Inc. | Memory cells having ferroelectric materials |
US9515262B2 (en) | 2013-05-29 | 2016-12-06 | Shih-Yuan Wang | Resistive random-access memory with implanted and radiated channels |
WO2014194069A2 (en) | 2013-05-29 | 2014-12-04 | Shih-Yuan Wang | Resistive random-access memory formed without forming voltage |
JP5755782B2 (en) * | 2014-05-26 | 2015-07-29 | 株式会社東芝 | Nonvolatile resistance change element |
US10153155B2 (en) | 2015-10-09 | 2018-12-11 | University Of Florida Research Foundation, Incorporated | Doped ferroelectric hafnium oxide film devices |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7035140B2 (en) * | 2004-01-16 | 2006-04-25 | Hewlett-Packard Development Company, L.P. | Organic-polymer memory element |
US20060171200A1 (en) * | 2004-02-06 | 2006-08-03 | Unity Semiconductor Corporation | Memory using mixed valence conductive oxides |
US8045364B2 (en) * | 2009-12-18 | 2011-10-25 | Unity Semiconductor Corporation | Non-volatile memory device ion barrier |
US8208284B2 (en) * | 2008-03-07 | 2012-06-26 | Unity Semiconductor Corporation | Data retention structure for non-volatile memory |
Family Cites Families (44)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS6215235A (en) | 1985-07-15 | 1987-01-23 | Mitsubishi Rayon Co Ltd | Production of electrically conductive high polymer material |
US6034882A (en) | 1998-11-16 | 2000-03-07 | Matrix Semiconductor, Inc. | Vertically stacked field programmable nonvolatile memory and method of fabrication |
US6518156B1 (en) | 1999-03-29 | 2003-02-11 | Hewlett-Packard Company | Configurable nanoscale crossbar electronic circuits made by electrochemical reaction |
US6545891B1 (en) | 2000-08-14 | 2003-04-08 | Matrix Semiconductor, Inc. | Modular memory device |
US6563118B2 (en) * | 2000-12-08 | 2003-05-13 | Motorola, Inc. | Pyroelectric device on a monocrystalline semiconductor substrate and process for fabricating same |
US6873540B2 (en) * | 2001-05-07 | 2005-03-29 | Advanced Micro Devices, Inc. | Molecular memory cell |
US6563185B2 (en) | 2001-05-21 | 2003-05-13 | The Regents Of The University Of Colorado | High speed electron tunneling device and applications |
US7388276B2 (en) | 2001-05-21 | 2008-06-17 | The Regents Of The University Of Colorado | Metal-insulator varactor devices |
US6534784B2 (en) | 2001-05-21 | 2003-03-18 | The Regents Of The University Of Colorado | Metal-oxide electron tunneling device for solar energy conversion |
US7173275B2 (en) | 2001-05-21 | 2007-02-06 | Regents Of The University Of Colorado | Thin-film transistors based on tunneling structures and applications |
US6856536B2 (en) | 2002-08-02 | 2005-02-15 | Unity Semiconductor Corporation | Non-volatile memory with a single transistor and resistive memory element |
US7009235B2 (en) | 2003-11-10 | 2006-03-07 | Unity Semiconductor Corporation | Conductive memory stack with non-uniform width |
US7186569B2 (en) | 2002-08-02 | 2007-03-06 | Unity Semiconductor Corporation | Conductive memory stack with sidewall |
AU2003264480A1 (en) | 2002-09-19 | 2004-04-08 | Sharp Kabushiki Kaisha | Variable resistance functional body and its manufacturing method |
US6944052B2 (en) | 2002-11-26 | 2005-09-13 | Freescale Semiconductor, Inc. | Magnetoresistive random access memory (MRAM) cell having a diode with asymmetrical characteristics |
US7220985B2 (en) | 2002-12-09 | 2007-05-22 | Spansion, Llc | Self aligned memory element and wordline |
DE10319271A1 (en) | 2003-04-29 | 2004-11-25 | Infineon Technologies Ag | Memory circuitry and manufacturing method |
US6972238B2 (en) | 2003-05-21 | 2005-12-06 | Sharp Laboratories Of America, Inc. | Oxygen content system and method for controlling memory resistance properties |
US7408212B1 (en) | 2003-07-18 | 2008-08-05 | Winbond Electronics Corporation | Stackable resistive cross-point memory with schottky diode isolation |
US7029924B2 (en) | 2003-09-05 | 2006-04-18 | Sharp Laboratories Of America, Inc. | Buffered-layer memory cell |
US7060586B2 (en) | 2004-04-30 | 2006-06-13 | Sharp Laboratories Of America, Inc. | PCMO thin film with resistance random access memory (RRAM) characteristics |
US7148144B1 (en) | 2004-09-13 | 2006-12-12 | Spansion Llc | Method of forming copper sulfide layer over substrate |
US7443710B2 (en) * | 2004-09-28 | 2008-10-28 | Spansion, Llc | Control of memory devices possessing variable resistance characteristics |
US7102156B1 (en) | 2004-12-23 | 2006-09-05 | Spansion Llc Advanced Micro Devices, Inc | Memory elements using organic active layer |
US7154769B2 (en) * | 2005-02-07 | 2006-12-26 | Spansion Llc | Memory device including barrier layer for improved switching speed and data retention |
US7897951B2 (en) * | 2007-07-26 | 2011-03-01 | Unity Semiconductor Corporation | Continuous plane of thin-film materials for a two-terminal cross-point memory |
EP1878022A1 (en) | 2005-04-22 | 2008-01-16 | Matsusita Electric Industrial Co., Ltd. | Electric element, memory device and semiconductor integrated circuit |
US7660145B2 (en) * | 2005-07-01 | 2010-02-09 | Semiconductor Energy Laboratory Co., Ltd. | Storage device and semiconductor device |
US7303971B2 (en) | 2005-07-18 | 2007-12-04 | Sharp Laboratories Of America, Inc. | MSM binary switch memory device |
US7446010B2 (en) | 2005-07-18 | 2008-11-04 | Sharp Laboratories Of America, Inc. | Metal/semiconductor/metal (MSM) back-to-back Schottky diode |
US20070105390A1 (en) | 2005-11-09 | 2007-05-10 | Oh Travis B | Oxygen depleted etching process |
US7218984B1 (en) | 2005-12-16 | 2007-05-15 | International Business Machines Corporation | Dynamically determining yield expectation |
JP4594878B2 (en) | 2006-02-23 | 2010-12-08 | シャープ株式会社 | Resistance control method for variable resistance element and nonvolatile semiconductor memory device |
KR100718155B1 (en) | 2006-02-27 | 2007-05-14 | 삼성전자주식회사 | Non-volatile memory device using two oxide layer |
JP4199781B2 (en) | 2006-04-12 | 2008-12-17 | シャープ株式会社 | Nonvolatile semiconductor memory device |
US7569459B2 (en) | 2006-06-30 | 2009-08-04 | International Business Machines Corporation | Nonvolatile programmable resistor memory cell |
US20080173975A1 (en) | 2007-01-22 | 2008-07-24 | International Business Machines Corporation | Programmable resistor, switch or vertical memory cell |
US8487450B2 (en) | 2007-05-01 | 2013-07-16 | Micron Technology, Inc. | Semiconductor constructions comprising vertically-stacked memory units that include diodes utilizing at least two different dielectric materials, and electronic systems |
US8987702B2 (en) | 2007-05-01 | 2015-03-24 | Micron Technology, Inc. | Selectively conducting devices, diode constructions, constructions, and diode forming methods |
US20080280125A1 (en) | 2007-05-08 | 2008-11-13 | Gary Allen Denton | Components with A Conductive Copper Sulfide Skin |
US7459716B2 (en) | 2007-06-11 | 2008-12-02 | Kabushiki Kaisha Toshiba | Resistance change memory device |
US8294219B2 (en) | 2007-07-25 | 2012-10-23 | Intermolecular, Inc. | Nonvolatile memory element including resistive switching metal oxide layers |
US7742323B2 (en) * | 2007-07-26 | 2010-06-22 | Unity Semiconductor Corporation | Continuous plane of thin-film materials for a two-terminal cross-point memory |
US7995371B2 (en) * | 2007-07-26 | 2011-08-09 | Unity Semiconductor Corporation | Threshold device for a memory array |
-
2008
- 2008-03-07 US US12/075,017 patent/US8208284B2/en not_active Expired - Fee Related
-
2012
- 2012-06-25 US US13/532,381 patent/US20120262981A1/en not_active Abandoned
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7035140B2 (en) * | 2004-01-16 | 2006-04-25 | Hewlett-Packard Development Company, L.P. | Organic-polymer memory element |
US20060171200A1 (en) * | 2004-02-06 | 2006-08-03 | Unity Semiconductor Corporation | Memory using mixed valence conductive oxides |
US8208284B2 (en) * | 2008-03-07 | 2012-06-26 | Unity Semiconductor Corporation | Data retention structure for non-volatile memory |
US8045364B2 (en) * | 2009-12-18 | 2011-10-25 | Unity Semiconductor Corporation | Non-volatile memory device ion barrier |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US10078372B2 (en) | 2013-05-28 | 2018-09-18 | Blackberry Limited | Performing an action associated with a motion based input |
US10353484B2 (en) | 2013-05-28 | 2019-07-16 | Blackberry Limited | Performing an action associated with a motion based input |
US10884509B2 (en) | 2013-05-28 | 2021-01-05 | Blackberry Limited | Performing an action associated with a motion based input |
US11467674B2 (en) | 2013-05-28 | 2022-10-11 | Blackberry Limited | Performing an action associated with a motion based input |
Also Published As
Publication number | Publication date |
---|---|
US20090225582A1 (en) | 2009-09-10 |
US8208284B2 (en) | 2012-06-26 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US8208284B2 (en) | Data retention structure for non-volatile memory | |
US10803935B2 (en) | Conductive metal oxide structures in non-volatile re-writable memory devices | |
US11672189B2 (en) | Two-terminal reversibly switchable memory device | |
US8274817B2 (en) | Non volatile memory device ion barrier | |
US8395928B2 (en) | Threshold device for a memory array | |
US8565006B2 (en) | Conductive metal oxide structures in non volatile re writable memory devices | |
US7382644B2 (en) | Two terminal memory array having reference cells |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
STCB | Information on status: application discontinuation |
Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION |