Abstract: Programming a resistive memory structure at a temperature well above the operating temperature can create a defect distribution with higher stability, leading to a potential improvement of the retention time. The programming temperature can be up to 100 C above the operating temperature. The memory chip can include embedded heaters in the chip package, allowing for heating the memory cells before the programming operations.

Abstract: A semiconductor structure includes a memory region. A memory structure is disposed on the memory region. The memory structure includes a first electrode, a resistance variable layer, a protection material and a second electrode. The first electrode has a top surface on the memory region. The resistance variable layer has at least a first portion and a second portion. The first portion is disposed over the top surface of the first electrode and the second portion extends upwardly from the first portion. The protection material surrounds the second portion of the resistance variable layer. The protection material is configurable to protect at least one conductive path in the resistance variable layer. The second electrode is disposed over the resistance variable layer.

Abstract: Provision of fabrication, construction, and/or assembly of a memory device including a two-terminal memory portion is described herein. The two-terminal memory device fabrication can provide enhanced capabilities in connection with precisely tuning on-state current over a greater possible range.

Abstract: A sidewall-type memory cell (e.g., a CBRAM, ReRAM, or PCM cell) may include a bottom electrode, a top electrode layer defining a sidewall, and an electrolyte layer arranged between the bottom and top electrode layers, such that a conductive path is defined between the bottom electrode and a the top electrode sidewall via the electrolyte layer, wherein the bottom electrode layer extends generally horizontally with respect to a horizontal substrate, and the top electrode sidewall extends non-horizontally with respect to the horizontal substrate, such that when a positive bias-voltage is applied to the cell, a conductive path grows in a non-vertical direction (e.g., a generally horizontal direction or other non-vertical direction) between the bottom electrode and the top electrode sidewall.

Abstract: In one embodiment, a chip comprises a capacitor and a resistor. The capacitor comprises a first capacitor terminal, a second capacitor terminal, and a dielectric layer between the first and second capacitor terminals. The second capacitor terminal and the resistor are both fabricated from a resistor metal layer.

Abstract: A resistive memory cell may include a ring-shaped bottom electrode, a top electrode, and an electrolyte layer arranged between the bottom and top electrodes. A ring-shaped bottom electrode may be formed by forming a dielectric layer over a bottom electrode contact, etching a via in the dielectric layer to expose at least a portion of the bottom electrode contact, depositing a conductive via liner over the dielectric layer and into the via, the via liner deposited in the via forming a ring-shaped structure in the via and a contact portion in contact with the exposed bottom electrode contact, the ring-shaped structure defining a radially inward cavity of the ring-shaped structure, and filling the cavity with a dielectric fill material, such that the ring-shaped structure of the via liner forms the ring-shaped bottom electrode, depositing an electrolyte layer over the bottom electrode, and depositing a top electrode over the electrolyte layer.

Abstract: Selector devices that can be suitable for memory device applications can have low leakage currents at low voltages to reduce sneak current paths for non selected devices, and high leakage currents at high voltages to minimize voltage drops during device switching. The selector device can include a first electrode, a tri-layer dielectric layer, and a second electrode. The tri-layer dielectric layer can include a low band gap dielectric layer disposed between two higher band gap dielectric layers. The high band gap dielectric layers can be doped with doping materials to form traps at energy levels higher than the operating voltage of the memory device.

Abstract: Various embodiments include dual three-dimensional (3D) resistor structures and methods of forming such structures. In some embodiments, a dual 3D resistor structure includes: a dielectric layer having a first set of trenches extending in a first direction through the dielectric layer; and a second set of trenches overlayed on the first set of trenches, the second set of trenches extending in a second direction through the dielectric layer, the second set of trenches and the first set of trenches forming at least one dual 3D trench; and a resistor material overlying the dielectric layer and at least partially filling the at least one dual 3D trench along the first direction and the second direction.

Abstract: A semiconductor structure includes a memory region. A memory structure is disposed on the memory region. The memory structure includes a first electrode, a resistance variable layer, protection spacers and a second electrode. The first electrode has a top surface and a first outer sidewall surface on the memory region. The resistance variable layer has a first portion and a second portion. The first portion is disposed over the top surface of the first electrode and the second portion extends upwardly from the first portion. The protection spacers are disposed over a portion of the top surface of the first electrode and surround at least the second portion of the resistance variable layer. The protection spacers are configurable to protect at least one conductive path in the resistance variable layer. The protection spacers have a second outer sidewall surface substantially aligned with the first outer sidewall surface of the first electrode.

Abstract: Resistive random access memory (ReRAM) cells can include a ZnTe switching layer and TiN or Pt electrodes. The combination of the switching layer of ZnTe and the electrodes of TiN or Pt is designed to achieve desirable performance characteristics, such as low current leakage as well as low and consistent switching currents. High temperature anneal of the ZnTe switching layer can further improve the performance of the ReRAM cells. The switching layer may be deposited using various techniques, such as sputtering or atomic layer deposition (ALD).

Abstract: A phase changeable memory cell is disclosed. In an embodiment of the invention, a phase changeable memory cell is formed with an ultra-small contact area to reduce the programming current. This contact area between heater electrode and phase changeable material is limited by the thickness of thin films rather than lithographic critical dimension in one dimension. As a result, the contact area is much less than the square of lithographic critical dimension for almost every technology node, which is helps in reducing current. To further reduce the current and improve the heating efficiency, heater electrode is horizontally put with its length being tunable so as to minimize the heat loss flowing through the heater to the terminal that connects to the front end switch device. In addition, above and below the heater layer, low-thermal-conductivity material (LTCM) is used to minimize heat dissipation. This results in reduced power consumption of the phase changeable memory cell with improved reliability.

Abstract: A semiconductor structure comprises a metal gate structure formed in a substrate, wherein the metal gate structure comprises a first film formed of a first material and formed on a bottom and sidewalls of a gate trench, a second film formed of a second material and formed over the first film and a gate electrode formed over the second film. The semiconductor structure further comprises a resistor structure formed in the substrate, where the resistor structure comprises a third film formed of the first material and formed on a bottom and sidewalls of a resistor trench and a fourth film formed of the second material and formed over the third film.

Abstract: Memory devices and methods for forming the device are disclosed. The device includes a substrate having an array surface and a non-array surface and a memory array having a plurality of memory cells interconnected by first conductors in a first direction and second conductors in a second direction. The memory array is disposed on the array surface of the substrate. The device further includes through silicon via (TSV) contacts disposed in the substrate. The TSV contacts extend from the array surface to the non-array surface, enabling electrical connections to the array from the non-array surface.

Abstract: To form a memory cell with a phase change element, a hole is formed through an insulator to a bottom electrode, and a phase change material is deposited on the insulator surface covering the hole. A confining structure is formed over the phase change material so the phase change material expands into the hole when heated to melting to become electrically connected to the bottom electrode. A top electrode is formed over and electrically connects to the phase change material. The bottom electrode can include a main portion and an extension having a reduced lateral dimension. The confining structure can include capping material having a higher melting temperature than the phase change material, and sufficient tensile strength to ensure the phase change material moves into the hole when the phase change material melts and expands. The hole can be a J shaped hole.

Abstract: A two-terminal memory cell comprises a dual mode of operation in a unipolar mode and bipolar mode for a programming or On-state and for an erase or Off-state of the cell. The two-terminal memory cell is field programmable and can be flexibly designed or integrated into existing architecture. The two-terminal memory comprises a first electrode layer and a second electrode layer with a switching layer disposed between that has an electrical insulator material. A semiconductor layer is disposed between the switching layer and at least one of the first electrode or the second electrode. The switching layer generates a conductive path that is configured to be in a program state and an erase state, based on a bipolar mode and a unipolar mode.

Abstract: Combinatorial workflow is provided for evaluating materials and processes for current selector devices in a cross point memory array. Blanket layers, metal-insulator-metal devices, and compete memory structures are combinatorially fabricated on multiple regions of a substrate, with each region having a different material and process condition for the current selector devices. The current selector devices are then characterized, and the data are compared to obtain the optimum materials and processes.

Abstract: A method of fabricating a fin selector with a gated RRAM and the resulting device are disclosed. Embodiments include forming a bottom electrode layer and a hardmask on a semiconductor substrate; etching the hardmask, bottom electrode layer, and semiconductor substrate to form a fin-like structure; forming first and second dummy gate stacks on first and second side surfaces of the fin-like structure, respectively; forming spacers on vertical surfaces of the first and second dummy gate stacks; forming an ILD surrounding the spacers; removing the first and second dummy gate stacks, forming first and second cavities on first and second sides of the fin-like structure; forming an RRAM layer on the first and second side surfaces of the fin-like structure in the first and second cavities, respectively; and filling each of the first and second cavities with a top electrode.

Abstract: A semiconductor structure includes a substrate and a resistor provided over the substrate. The resistor includes a first material layer, a second material layer, a first contact structure and a second contact structure. The first material layer includes at least one of a metal and a metal compound. The second material layer includes a semiconductor material. The second material layer is provided over the first material layer and includes a first sub-layer and a second sub-layer. The second sub-layer is provided over the first sub-layer. The first sub-layer and the second sub-layer are differently doped. Each of the first contact structure and the second contact structure provides an electrical connection to the second sub-layer of the second material layer.

Abstract: Providing for two-terminal memory cell structures and fabrication that can be achieved with a relatively low temperature process(es) is described herein. By way of example, disclosed two-terminal memory cells can be formed at least in part as a continuous deposition, potentially yielding improved efficiency in manufacturing. Furthermore, various embodiments can be compatible with some existing complementary metal oxide semiconductor fabrication processes, reducing or avoiding retooling overhead that might be associated with modifying existing fabrication processes in favor of other two-terminal memory cell fabrication techniques.

Abstract: A semiconductor structure with a high voltage area and a low voltage area includes a substrate of a first conductivity type accommodating the high voltage area and the low voltage area. A resistor is on the substrate, connecting the high voltage area and the low voltage area, and the resistor resides substantially in the high voltage area. The structure further includes a first doped region of the first conductivity type in the substrate between the high voltage area and the low voltage area, and a second doped region of a second conductivity type between the substrate and the first doped region. Moreover, an insulating layer is formed between the resistor and the first doped region.

Abstract: A multi-bit NVM cell includes a storage unit having resistive elements, such as phase change resistive elements. The NVM cell may be configured as a single port or dual port multi-bit cell. The NVM cell includes primary and secondary cell selectors. The primary selector selects the multi-bit cell while the secondary selector selects a bit within the multi-bit cell. A plurality of storage units can be commonly coupled to a primary selector, facilitating high density applications.

Abstract: Providing for two-terminal memory having an inherent rectifying characteristic(s) is described herein. By way of example, the two-terminal memory can be a resistive switching device having one or more “on” states and an “off” state, to facilitate storage of digital information. A conductive filament can be electrically isolated from an electrode of the two-terminal memory by a thin tunneling layer, which permits a tunneling current for voltages greater in magnitude than a positive rectifying voltage or a negative rectifying voltage. The two-terminal memory cell can therefore have high resistance to small voltages, mitigating leakage currents in an array of the two-terminal memory cells. In addition, the memory cell can be conductive above a rectifying voltage, enabling reading of the memory cell in response to a suitable read bias, and erasing of the memory cell in response to a suitable negative erase bias.

Abstract: Resistive random access memory (ReRAM) cells can include an embedded metal nanoparticle switching layer and electrodes. The metal nanoparticles can be formed using a micelle solution. The generation of the nanoparticles can be controlled in multiple dimensions to achieve desirable performance characteristics, such as low power consumption as well as low and consistent switching currents.

Abstract: An integrated circuit system, and a method of manufacture thereof, including: an integrated circuit die; a non-volatile memory cell in the integrated circuit die and having a bit line for reading a data condition state of the non-volatile memory cell; and a voltage clamp in the integrated circuit die, the voltage clamp having a semiconductor switch connected to the bit line for reducing voltage excursions on the bit line.

Abstract: A solid state memory comprises a top electrode, a bottom electrode and an insulating switching medium that is disposed at a thickness based on a predetermined function. The insulating switching medium generates a conduction path in response to an electric signal applied to the device. The thickness of the insulating switching medium is a function of a filament width of the conduction path and operates to prevent rupture of a semi-stable region. The semi-stable region maintains filament structure over time and does not degrade into retention failure. The solid state memory can comprise one or more conducting layers that can operate to control the conductance at an on-state of the memory and offer oxygen vacancies or metal ions to the switching medium. The function of the thickness of the insulating switching medium can vary depending upon the number of conduction layers disposed at the insulating switching medium.

Abstract: A disturb-resistant nonvolatile memory device includes a substrate, a dielectric material overlying the semiconductor substrate, a first cell comprising a first wiring structure extending in a first direction overlying the dielectric material, a first contact region, a first resistive switching media, and a second wiring structure extending in a second direction orthogonal to the first direction, a second cell comprising the first wiring structure, a second contact region, a second resistive switching media, and a third wiring structure separated from the second wiring structure and parallel to the second wiring structure, and a dielectric material disposed at least in a region between the first switching region and the second switching region to electrically and physically isolate the first switching region and the second switching region.

Abstract: A resistive memory device is disclosed. The resistive memory device comprises one or more metal oxide layers. The resistive memory device displays a property of asymmetric hysteresis loop formation when positive and negative electrical biases are applied across the device.

Abstract: Provided are resistive random access memory (ReRAM) cells and methods of fabricating thereof. A stack including a defect source layer, a defect blocking layer, and a defect acceptor layer disposed between the defect source layer and the defect blocking layer may be subjected to annealing. During the annealing, defects are transferred in a controllable manner from the defect source layer to the defect acceptor layer. At the same time, the defects are not transferred into the defect blocking layer thereby creating a lowest concentration zone within the defect acceptor layer. This zone is responsible for resistive switching. The precise control over the size of the zone and the defect concentration within the zone allows substantially improvement of resistive switching characteristics of the ReRAM cell. In some embodiments, the defect source layer includes aluminum oxynitride, the defect blocking layer includes titanium nitride, and the defect acceptor layer includes aluminum oxide.

Abstract: Embodiments disclosed herein may relate to a memory cell comprising a chalcogenide material mixture having a chalcogenide composition and a metallic glass-forming composition.

Abstract: An embodiment, relates to a phase changeable memory cell. The phase changeable memory cell is formed with an ultra small contact area formed by filament conductive path. This contact area between a heating electrode and phase changeable material layer is determined by the forming of filament path, which is conductive and much smaller in cross-sectional area than the minimum area that can be achieved by lithography. This leads to high heating efficiency and ultra-low programming current. As the disclosed structure has no requirement on endurance for the formed filament and use phase changeable material rather than filament-forming material to provide high on/off resistance ratio, drawbacks of filament-forming material on low endurance and low sensing margin are avoided in the proposed cell structure.

Abstract: The present disclosure provides a resistive random access memory (RRAM) cells and methods of making the same. The RRAM cell includes a transistor and an RRAM structure. The RRAM structure includes a bottom electrode having a via portion and a non-planar portion, a resistive material layer conformally covering the non-planar portion of the bottom electrode; and, a top electrode on the resistive material layer. The via portion of the bottom electrode is embedded in a first RRAM stop layer. The non-planar portion of the bottom electrode has an apex and is centered above the via portion.

Abstract: In one embodiment, a capacitor includes a first row including a first capacitor element and a second capacitor element coupled in parallel, and a second row including a third capacitor element and a fourth capacitor element coupled in parallel. The first row is coupled in series with the second row. In a metallization level over a workpiece, the second capacitor element is disposed between the first capacitor element and the third capacitor element. In the metallization level, the third capacitor element is disposed between the second capacitor element and the fourth capacitor element. The first, the second, the third, and the fourth capacitor elements are disposed in the metallization level.

Abstract: A resistive switching device and methods for making the same are disclosed. In the above said device, a resistive switching layer is interposed between opposing electrodes. The resistive switching layer comprises at least two sub-layers of switchable insulative material characterized by different ionic mobilities.

Abstract: In one aspect, a method of forming a phase change material layer is provided. The method includes supplying a reaction gas including the composition of Formula 1 into a reaction chamber, supplying a first source which includes Ge(II) into the reaction chamber, and supplying a second source into the reaction chamber. Formula 1 is NR1R2R3, where R1, R2 and R3 are each independently at least one selected from the group consisting of H, CH3, C2H5, C3H7, C4H9, Si(CH3)3, NH2, NH(CH3), N(CH3)2, NH(C2H5) and N(C2H5)2.

Abstract: Nonvolatile memory elements that are based on resistive switching memory element layers are provided. A nonvolatile memory element may have a resistive switching metal oxide layer. The resistive switching metal oxide layer may have one or more layers of oxide. A resistive switching metal oxide may be doped with a dopant that increases its melting temperature and enhances its thermal stability. Layers may be formed to enhance the thermal stability of the nonvolatile memory element. An electrode for a nonvolatile memory element may contain a conductive layer and a buffer layer.

Abstract: Some embodiments include methods of forming memory cells. An opening is formed over a first conductive structure to expose an upper surface of the first conductive structure. The opening has a bottom level with a bottom width. The opening has a second level over the bottom level, with the second level having a second width which is greater than the bottom width. The bottom level of the opening is filled with a first portion of a multi-portion programmable material, and the second level is lined with the first portion. The lined second level is filled with a second portion of the multi-portion programmable material. A second conductive structure is formed over the second portion. Some embodiments include memory cells.

Abstract: A method for forming a resistive memory cell within a memory array includes forming a patterned stopping layer on a first metal layer formed on a substrate and forming a bottom electrode into features of the patterned stopping layer. The method further includes forming a resistive memory layer. The resistive memory layer includes a metal oxide layer and a top electrode layer. The method further includes patterning the resistive memory layer so that the top electrode layer acts as a bit line within the memory array and a top electrode of the resistive memory cell.

Abstract: Switching device structures and methods are described herein. A switching device can include a vertical stack comprising a material formed between a first and a second electrode. The switching device can further include a third electrode coupled to the vertical stack and configured to receive a voltage applied thereto to control a formation state of a conductive pathway in the material between the first and the second electrode, wherein the formation state of the conductive pathway is switchable between an on state and an off state.

Abstract: A fin-type programmable memory cell includes a bottom electrode electrically coupled to an access device, a top electrode, and an L-shaped memory material element electrically coupled to the bottom and top electrodes. A memory array includes an array of such memory cells, electrically coupled to an array of access devices.

Abstract: The present disclosure provides a resistive random access memory (RRAM) cells and methods of making the same. The RRAM cell includes a transistor and an RRAM structure. The RRAM structure includes a bottom electrode having a via portion and a top portion, a resistive material layer on the bottom electrode having a width that is same as a width of the top portion of the bottom electrode; a capping layer over the bottom electrode, a first spacer surrounding the capping layer and a top electrode, a second spacer surround the top portion of the bottom electrode and the first spacer, and the top electrode. The RRAM cell further includes a conductive material connecting the top electrode of the RRAM structure to a metal layer.

Abstract: A phase change memory cell, an array of the phase change memory cells, and a method for fabricating the phase change memory cells. The phase change memory cell includes a bottom electrode, a heating element, and a heat shield. During programming of the phase change memory cell, the bottom electrode passes current to the phase change memory cell. The heating element is electrically coupled to the bottom electrode and generates heat during the programming of the phase change memory cell. The heat shield is thermally conductive and surrounds at least a portion of the heating element. The heat shield conducts heat generated during programming of the phase change memory cell to the bottom electrode.

Abstract: A 3D array of nonvolatile memory has each read/write element accessed at a crossing between a word line and a bit line. The read/write element forms a tubular electrode having an outside shell of R/W material enclosing an oxide core. In a rectangular form, one side of the electrode contacts the word line and another side contacts the bit line. The thickness of the shell rather than its surface areas in contact with the word line and bit line determines the conduction cross-section and therefore the resistance. By adjusting the thickness of the shell, independent of its contact area with either the word line or bit line, each read/write element can operate with a much increased resistance and therefore much reduced current. Processes to manufacture a 3D array with such tubular R/W elements 3D array are also described.

Abstract: In some aspects, a memory cell is provided that includes a first conducting layer, a reversible resistance switching element above the first conducting layer, a second conducting layer above the reversible resistance switching element, and a liner disposed about a sidewall of the reversible resistance switching element. The reversible resistance switching element includes a first metal oxide material, and the liner includes the first metal oxide material. Numerous other aspects are provided.

Abstract: In a vertical dynamic memory cell, monocrystalline semiconductor material of improved quality is provided for the channel of an access transistor by lateral epitaxial growth over an insulator material (which complements the capacitor dielectric in completely surrounding the storage node except at a contact connection structure, preferably of metal, from the access transistor to the storage node electrode) and etching away a region of the lateral epitaxial growth including a location where crystal lattice dislocations are most likely to occur; both of which features serve to reduce or avoid leakage of charge from the storage node. An isolation structure can be provided in the etched region such that space is provided for connections to various portions of a memory cell array.

Abstract: A nonvolatile memory device and method for forming a resistive switching memory element, with improved lifetime and switching performance. A nonvolatile memory element includes resistive switching layer formed between a first and second electrode. The resistive switching layer comprises a metal oxide. One or more electrodes include a dopant material to provide the electrode with enhanced oxygen-blocking properties that maintain and control the oxygen ion content within the memory element contributing to increased device lifetime and performance.

Abstract: In one embodiment of the present invention, a resistive switching device includes a first electrode disposed over a substrate and coupled to a first potential node, a switching layer disposed over the first electrode, a conductive amorphous layer disposed over the switching layer, and a second electrode disposed on the conductive amorphous layer and coupled to a second potential node.

Abstract: Methods and devices associated with phase change cell structures are described herein. In one or more embodiments, a method of forming a phase change cell structure includes forming a substrate protrusion that includes a bottom electrode, forming a phase change material on the substrate protrusion, forming a conductive material on the phase change material, and removing a portion of the conductive material and a portion of the phase change material to form an encapsulated stack structure.

Abstract: An array of nonvolatile memory cells includes a plurality of vertically stacked tiers of nonvolatile memory cells. The tiers individually include a first plurality of horizontally oriented first electrode lines and a second plurality of horizontally oriented second electrode lines crossing relative to the first electrode lines. Individual of the memory cells include a crossing one of the first electrode lines and one of the second electrode lines and material there-between. Specifically, programmable material, a select device in series with the programmable material, and current conductive material in series between and with the programmable material and the select device are provided in series with such crossing ones of the first and second electrode lines. The material and devices may be oriented for predominant current flow in defined horizontal and vertical directions. Method and other implementations and aspects are disclosed.

Abstract: Semiconductor memory devices are provided. The device may include may include first and second selection lines connected to each other to constitute a selection line group, a plurality of word lines sequentially stacked on each of the first and second selection lines, vertical electrodes arranged in a row between the first and second selection lines, a plurality of bit line plugs arranged in a row at each of both sides of the selection line group, and bit lines crossing the word lines and connecting the bit line plugs with each other.

Abstract: A non-volatile memory element including a first electrode; a second electrode; and a variable resistance layer. The variable resistance layer including, when a first metal is M and a second metal is N: a third metal oxide layer NOz; a second metal oxide layer NOy; and a first metal oxide layer MOx such that the third, second and first metal oxide layers are stacked in this order; wherein when an oxygen content atomic percentage of an oxide of the first metal M in a stoichiometric state is A, an oxygen content atomic percentage of an oxide of the second metal N in a stoichiometric state is B, an oxygen content atomic percentage of MOx is C, an oxygen content atomic percentage of NOy is D, and an oxygen content atomic percentage of NOz is E, (D/B)<(C/A), (E/B)<(C/A) and y<z are satisfied.