Phase change memory with inter-granular switching

Abstract

A memory device comprising a conglomerate material interposed between a first electrode and a second electrode is provided. The conglomerate material includes nanocrystalline grains embedded in an amorphous matrix. During operations, phase change reactions occur at the inter-grain boundaries in the conglomerate material so as to reduce the operation power.

Description

PARTIES TO A JOINT RESEARCH AGREEMENT

International Business Machines Corporation, a New York Corporation, and Macronix International Corporation, Ltd., a Taiwan corporation, are parties to a Joint Research Agreement.

BACKGROUND

Technological Field

The present technology relates to memory devices based on phase change materials, and methods for manufacturing and operating such devices.

Description of Related Art

In a phase change memory (PCM), each memory cell includes a phase change memory element. The phase change memory element can be caused to change phase between a crystalline state and an amorphous state. The amorphous state is characterized by higher electrical resistivity than the crystalline state. In operation of the phase change memory element, an electrical current pulse passed through the phase change memory cell can set or reset the resistivity phase of the phase change memory element. To reset the memory element into the amorphous phase, an electrical current pulse with a large magnitude for a short time period can be used to heat up an active region of the memory element to a melting temperature, and then cool quickly causing it to solidify in the amorphous phase. To set the memory element into the crystalline phase, an electrical current pulse with a medium magnitude, which causes it to heat up to a crystallization transition temperature, and a longer cooling time period can be used allowing the active region to solidify in a crystalline phase. To read the state of the memory element, a small voltage is applied to the selected cell and the resulting electrical current is sensed.

To achieve low power operation, the magnitude of the current needed for reset can be reduced by reducing the size of the phase change material element in the cell and/or the contact area between electrodes and the phase change material, such that higher current densities are achieved with small absolute current values through the phase change material element. As shown in FIG. 1A, a conventional “mushroom-type” memory cell 100 has a reduced contact area between first electrode 111 and phase change memory element 113. First electrode 111 extends through dielectric 112, phase change memory element 113 comprises a body of phase change material, and second electrode 114 resides on the memory element 113. First electrode 111 is coupled to a terminal of an access device (not shown) such as a diode or transistor, while second electrode 114 is coupled to a bit line and can be part of the bit line (now shown). First electrode 111 has a width less than the width of second electrode 114 and memory element 113, establishing a small contact area between the body of phase change material and first electrode 111 and a relatively larger contact area between the body of phase change material and second electrode 114, so that higher current densities are achieved with small absolute current values through memory element 113. Because of this smaller contact area at the first electrode 111, the current density increases in the region adjacent first electrode 111, resulting in the active region 115 having a “mushroom” shape as shown in FIG. 1A. FIG. 1B is a low angle annular dark field scanning transmission electron microscopy (LAADF-STEM) image of a cross-section of a mushroom-type memory cell comprising Ge₂Sb₂Te₅ in the reset state. As seen in the FIG. 1B, a bulk amorphous mushroom-shaped region 116 is formed over the bottom electrode and surrounded by large crystalline grains.

For smaller width of electrodes, smaller currents are required for a reset operation. However, forming electrodes of sublithographic feature size involves complicated manufacturing processes, thereby increasing manufacturing costs. Moreover, the electrical and mechanical reliability issues increase with reducing the contact area.

It is desirable to provide memory devices having small reset current yet maintaining electrical and mechanical reliability.

SUMMARY

A memory device having a conglomerate material interposed between a first electrode and a second electrode is described herein. The conglomerate material comprises nanocrystalline grains embedded within an amorphous matrix. The memory device can be operated using inter-granular phase switching. The memory device further comprises circuitry to execute the inter-granular phase switching, wherein the circuitry applies a first bias arrangement to induce formation of amorphous material between the nanocrystalline grains within a region over the first electrode, effective to increase electrical resistance of the conglomerate material between the first and second electrodes above a first threshold without eliminating the nanocrystalline grains in the region, and applies a second bias arrangement to induce expansion of the nanocrystalline grains in the region by an amount effective to decrease electrical resistance of the conglomerate material between the first and second electrodes below a second threshold. The first bias arrangement applied to the memory device is configured to melt the conglomerate material between the nanocrystalline grains and then form the amorphous phase to block the electrical current between the nanocrystalline grains over the first electrode. The second bias arrangement applied to the memory device induces crystallization between the nanocrystalline grains so that the electrical current passes through between the nanocrystalline grains.

A conglomerate material described herein comprises a chalcogenide with an amount of germanium effective to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix. In another embodiment, the conglomerate material comprises a chalcognide with one or more additives selected from a group including silicon, oxygen, nitrogen and carbon, in an amount or amounts effective to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix.

The term “nanocrystalline grains” used herein refers to grains having less than 10 nm in minimum dimension.

The term “additive” or “additives” used herein refers to a dopant or an element intentionally added during formation of the conglomerate material.

A method for manufacturing the memory device described herein includes forming a first electrode having an electrode surface; forming a conglomerate material on the electrode surface, the conglomerate material including nanocrystalline grains embedded in an amorphous matrix; and forming a second electrode on the conglomerate material. The conglomerate material is formed using physical vapor deposition techniques. The conglomerate material comprises chalcogenide alloys with an effective amount of germanium to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix. The conglomerate material also comprises combination of chalcogenide alloys with an effective amount of silicon to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix.

A method for operating a memory device having a conglomerate material between first and second electrodes is also provided. The conglomerate material includes nanocrystalline grains embedded in an amorphous matrix. To store a first data value, the method includes applying a first bias arrangement to induce formation of amorphous material between the nanocrystalline grains within a region over a first electrode, by an amount effective to increase electrical resistance of the conglomerate material between the first and second electrodes above a first threshold without eliminating the nanocrystalline grains in the region. To store a second data value, the method includes applying a second bias arrangement to induce expansion of the nanocrystalline grains within the region by an amount effective to decrease electrical resistance of the conglomerate material between the first and second electrodes below a second threshold.

Other features, combinations of features, aspects and advantages of the technology described herein can be seen in the drawings, the detailed description and the claims, which follow.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A illustrates a prior art “mushroom” type phase change memory cell.

FIG. 1B is a low angle annular dark field scanning transmission electron microscopy (LAADF-STEM) image of a cross-section of a mushroom-type memory cell comprising Ge₂Sb₂Te₅ in the reset state.

FIG. 2 schematically illustrates a structure of a memory cell with a conglomerate material having nanocrystalline grains as described herein.

FIG. 3 is a high angle annular dark field scanning transmission electron microscopy (HAADF-STEM) image of a cross-section of a memory cell comprising a conglomerate material having nanocrystalline grains described herein in the reset state.

FIG. 4A is a high resolution transmission electron microscopy (HRTEM) image illustrating an expanded view of a conglomerate material having nanocrystalline grains as described herein in the reset state.

FIG. 4B indicates the marked regions in FIG. 4A as crystalline phase.

FIG. 5A is a high resolution transmission electron microscopy (HRTEM) image illustrating an expanded view of a conglomerate material having nanocrystalline grains as described herein in the set state.

FIG. 5B indicates the marked regions in FIG. 5A as amorphous phase.

FIG. 6 is a low angle annular dark field scanning transmission electron microscopy (LAADF-STEM) image of a cross-section of a memory cell comprising a conglomerate material having nanocrystalline grains as described herein in the reset state.

FIG. 7 is a graph illustrating the melting temperature and reset current as a function of time based on a simulation of a prior art mushroom-type memory cell.

FIG. 8 is graph illustrating the melting temperature and reset current as a function of time based on a simulation of a memory cell comprising a conglomerate material having nanocrystalline grains as described herein.

FIG. 9 is a graph illustrating resistance as a function of reset current of memory cells comprising a conglomerate material having nanocrystalline grains as described herein.

FIG. 10 is a graph illustrating resistance as a function of reset voltage of memory cells comprising a conglomerate material having nanocrystalline grains as described herein.

FIG. 11 is a graph illustrating the resistivity as a function of temperature of memory cells comprising conglomerate materials A and B.

FIG. 12 is a graph illustrating the resistance distribution of memory cells comprising conglomerate materials A and B.

FIG. 13 illustrates heat flow simulation of a memory cell comprising a conglomerate material having nanocrystalline grains as described herein.

FIG. 14 is a graph illustrating improved endurance achieved by memory cells comprising a conglomerate material A as described herein.

FIG. 15 is a graph illustrating improved number of cycles achieved by memory cells comprising a conglomerate material A as described herein.

FIG. 16 illustrates a cross-sectional view of a thermally confined memory cell.

FIG. 17 illustrates a cross-sectional view of an alternative memory cell design.

FIG. 18 illustrates a manufacturing process flow for manufacturing a memory cell of FIG. 2.

FIG. 19 is a simplified block diagram of an integrated circuit including a memory array having memory cells with memory elements comprising a conglomerate material as described herein.

DETAILED DESCRIPTION

A detailed description of embodiments of the technology is provided with reference to the FIGS. 2-19.

FIG. 2 illustrates a memory cell 200 having a conglomerate material including nanocrystalline grains 215 embedded in an amorphous matrix 213. Memory cell 200 includes a first electrode 211 having an electrode surface 220 contacting the conglomerate material, and a second electrode 214 on the conglomerate material. Inter-grain boundaries 217-1, 217-2, . . . and 217-8, collectively indicated 217, are between nanocrystalline grains 215. To simplify the illustration, not all inter-grain boundaries are given their own numeral. The nanocrystalline grains 215 can have a stoichiometry different than the amorphous matrix 213.

First and second electrodes 211 and 214 may comprise, for example, TiN or TaN. Alternatively, the first and second electrodes 211 and 214 may each be W, WN, TiAlN or TaAlN, or comprise, for further examples, one or more elements selected from the group consisting of doped-Si, Si, C, Ge, Cr, Ti, W, Mo, Al, Ta, Cu, Pt, Ir, La, Ni, N, O, and Ru and combinations thereof.

The conglomerate material is the memory element and composed of a phase change material. Nanocrystalline grains 215 and amorphous matrix 213 may both be comprised of a phase change material, and may be comprised of a phase change material in combination with additives, such as Si, N, O, and C in amounts effective to cause formation of the conglomerate structure, or in amounts effective to increase the crystallization transition temperature. Nanocrystalline grains 215 in embodiments described herein can comprise more atoms selected from a group including Ge, Sb, Te, and Ga and lesser atoms of the additives than occur in amorphous matrix 213. The amorphous material in amorphous matrix 213 in embodiments described herein can comprise more additives selected from a group including Si, N, O, and C than occur in the nanocrystalline grains 215. The conglomerate material in embodiments described herein can comprise a chalcogenide with an amount of germanium effective to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix. The chalcogenide can be Ge_xSb_yTe_z, for example Ge₄Sb₂Te₃, and Ge_xSb_yGa_z for example Ge₁Sb₁Te₁. The conglomerate material in embodiments described herein can comprise a chalcogenide with one or more additives selected from a group including silicon (Si), nitrogen (N), oxygen (O) and carbon (C), in an amount or amounts, for example 1-10 at %, effective to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix. The chalcogenide with one or more additives can be Ge_xSb_yTe_zSi_m, Ge_xSb_yTe_zSi_mO_n, Ge_xSb_yTe_zSi_mN_n, Ge_xSb_yTe_z, N_m. In a reset operation, circuitry applies a first bias arrangement to induce formation or expansion of bodies of amorphous material between the nanocrystalline grains 215 within a region 210 over the first electrode surface 220 effective to increase electrical resistance of the conglomerate material between the first and second electrodes 211 and 214 above a first threshold without eliminating the nanocrystalline grains 215 in the region 210. After the first bias arrangement is applied, the amorphous material surrounds the nanocrystalline grains in the region 210. A current crowding effect occurs at inter-grain boundaries 217 over first electrode 211. With a current limiter (not shown), the first bias arrangement is limited to melting the material in inter-grain boundaries 217, and not eliminating nanocrystalline grains 215, resulting in the amorphous phase at inter-grain boundaries 217. The current limiter during the first bias arrangement can be used to limit current flow through the memory element.

In a set operation, a second bias arrangement is applied to memory cell 200 to induce growth or expansion of nanocrystalline grains 215 in the region 210 by an amount effective to decrease electrical resistance of the conglomerate material between the first and second electrodes 211 and 214 below a second threshold. Thus, the crystalline phase is formed at inter-grain boundaries 217, rendering a low resistance state. After the second bias arrangement is applied, the nanocrystalline grains surround the amorphous material in the region 210. During reset and set operations, the phase change reactions generally occur at inter-grain boundaries 217 within the conglomerate material.

FIG. 3 illustrates a high angle annular dark field scanning transmission electron microscopy (HAADF-STEM) image of a cross-section of a memory cell comprising a conglomerate material 216 having nanocrystalline grains embedded in the amorphous matrix in the reset state. The inset image 230 in the upper-left corner shows an electron beam diffraction pattern illustrating the coexistence of the crystalline and amorphous phases in conglomerate material 216. The conglomerate material 216 comprises a chalcogenide or a chalcogenide with one or more additives. The white spots indicate the crystalline phase (nanocrystalline grains), and the gray spots indicate the amorphous phase (amorphous matrix). The nanocrystalline grains have more atoms selected from a group including germanium (Ge), antimony (Sb), tellurium (Te), and gallium (Ga), while the amorphous matrix has more additives selected from a group including silicon (Si), oxygen (O), nitrogen (N), and carbon (C). The conglomerate material has a different atomic concentration profile in the crystalline region (nanocrystalline grains) than is found in the amorphous region (amorphous matrix).

The term “stoichiometry” as used here refers to the quantitative relationship in atomic concentration between two or more substances in the phase change material in a volume measurable, for example, using energy dispersive x-ray spectroscopy (EDX), or equivalent techniques.

FIG. 4A is a high resolution transmission electron microscopy (HRTEM) image illustrating an expanded view of a conglomerate material having nanocrystalline grains as described herein, in the reset state. FIG. 4B indicates the marked regions in FIG. 4A as crystalline phase. The nanocrystalline grains are surrounded by the amorphous material so that the conglomerate material between the first and second electrodes is in the high resistance state. The grain size of the nanocrystalline grains is less than 10 nm in minimum dimension. The arrows indicate the directions of expansion of the nanocrystalline grains, if a set operation is executed, in which the nanocrystalline grains grow to contact each other to create low resistance.

FIG. 5A is a high resolution transmission electron microscopy (HRTEM) image illustrating an expanded view of a conglomerate material having nanocrystalline grains as described herein, in the set state. FIG. 5B indicates the marked regions in FIG. 5A as amorphous phase. The amorphous regions are isolated by the crystalline material so that the conglomerate material between the first and second electrodes is in the low resistance state. The arrow 501 indicates a current path, if a reset operation is executed, in which the crystalline material between the amorphous regions will be amorphized to create high resistance.

FIG. 6 is a low angle annular dark field scanning transmission electron microscopy (LAADF-STEM) image of a cross-section of a memory cell comprising a conglomerate material having nanocrystalline grains in the reset state. As compared to FIG. 1A, FIG. 6 reveals no big amorphous mushroom-shaped region in the conglomerate material 216 above the first electrode 211. This is because the phase change region in the conglomerate material is limited to the space between the nanocrystalline grains. As no big bulk amorphous region needs to be formed in the conglomerate material, the reset current drastically decreases.

FIG. 7 and FIG. 8 are simulation results that illustrate the melting temperature and reset current as a function of time for a prior art mushroom-type memory cell comprising Ge₂Sb₂Te₅ and for a memory cell comprising a conglomerate material, respectively. The hottest point in the mushroom-type memory cell is located in the center of the bulk amorphous region. When applying the reset current of 48 μA the center of the phase change region is heated up to 1100K as shown in FIG. 7. Due to the local current crowding effect in the conglomerate material, as seen in FIG. 8, the reset current needs only 7.5 μA to heat up to 850K and to form the amorphous phase between the nanocrystalline grains.

FIG. 9 is a graph illustrating resistance as a function of reset current of memory cells comprising a conglomerate material having nanocrystalline grains described herein. Curves 901 and 903 illustrate the average values of resistance in the reset and set states, respectively. With use of a ring type bottom electrode having diameter of 35 nm and thickness of 1.5 nm, the reset current needs only 20 μA to induce enough resistance difference, for example 10×, between the reset and set states. FIG. 10 illustrates resistance as a function of reset voltage, using the same memory cell structure used for the experiment producing FIG. 9. With application of about 1 volt bias to the gate and drain of the access transistor, the resulting reset current provides an operation window of 10× resistance difference.

FIG. 11 is a graph of memory cells comprising conglomerate materials A and B, illustrating the resistivity as a function of temperature. At higher temperatures (above about 400° C.), material A exhibits greater resistance than material B, but at lower temperature (below about 400° C.), material A has lower resistance than material B. Due to the lower resistance at room temperature, material A may exhibit a faster read speed. FIG. 12 is a graph illustrating the resistance distribution of memory cells comprising conglomerate materials A and B. With the reset current of 80 μA applied to both materials A and B, material A has narrower distribution in the reset state.

FIG. 13 illustrates heat flow simulation of a memory cell comprising a conglomerate material having nanocrystalline grains. In the Y direction, heat generated between the nanocrystalline grains flows into the electrode, which minimizes the thermal disturbance to the neighboring cells in reset operation. The amorphous material surrounding the nanocrystalline grains takes a part in the thermal isolation to greatly reduce the disturbance in the X direction. FIG. 14 is a graph illustrating improved endurance achieved by memory cells comprising a conglomerate material A using a 256 Mb test chip. The nanocrystalline grains embedded in the amorphous matrix are inhibited from growth by the surrounding amorphous material so that the data retention is improved. As extrapolated in FIG. 14, material A may demonstrate good data retention of 55° C./100 years. FIG. 15 is a graph illustrating improved number of cycles achieved by memory cells comprising a conglomerate material A. Material A also can achieve the number of cycles of greater than 10⁸ and maintain an operation window of 10× resistance difference, as shown in FIG. 15.

FIG. 16 illustrates a cross-sectional view of an alternative memory cell 370 design. Memory cell 370 includes a memory element 372 comprising the conglomerate material in an inter-electrode current path through memory element 372. The conglomerate material comprises nanocrystalline grains 315 embedded in an amorphous matrix 313. The memory element 372 is in a pillar shape and contacts first and second electrodes 374 and 376 at electrode surfaces 378 and 380, respectively. The memory element 372 has a width 384 substantially the same as that of the first and second electrodes 374 and 376 to define a multi-layer pillar surrounded by dielectric (not shown). As used herein, the term “substantially” is intended to accommodate manufacturing tolerances. In operation, as current passes between the first and second electrodes 374 and 376 and through the memory element 372, the inter-grain boundaries heats up to cause phase change reactions. This leads to a majority of the phase transformation occurring at the inter-grain boundaries within the conglomerate material during device operation.

FIG. 17 illustrates a cross-sectional view of an alternative memory cell 400 design. The memory cell 400 includes a memory element 402 comprising the conglomerate material including nanocrystalline grains 415 embedded in an amorphous matrix 413 in an inter-electrode current path through the memory element 402. The memory element 402 is surrounded by dielectric (not shown) contacting first and second electrodes 404 and 406 at electrode surfaces. The memory element 402 has a varying width that is always less than the width of the first and second electrodes. In operation, as current passes between the first and second electrodes 404 and 406 and through the memory element 402 the inter-grain boundaries heat up within the conglomerate material, thereby causing phase change reactions at the inter-grain boundaries. Thus the volume of inter-grain boundaries within the conglomerate material is where a majority of the phase transformation occurs during device operation.

As will be understood, the conglomerate material comprising a chalcogenide with an additive or additives, as described herein, can be used in a variety of memory cell structures and is not limited to the memory cell structures described herein.

FIG. 18 illustrates a manufacturing process flow for manufacturing a memory cell including a conglomerate material with a structure of the memory cell shown in FIG. 2, wherein the conglomerate material has a first stoichiometry of the nanocrystalline grains and a second stoichiometry of the amorphous material in the amorphous matrix. Reference numerals used in the following description of the process of FIG. 18 are taken from FIG. 2. At step 450 the first electrode 211 having a width (or diameter) is formed extending through the dielectric layer (not shown). The first electrode 211 comprises TiN and the dielectric layer comprises SiN. Alternatively the first electrode 211 can have a sublithographic width (or diameter).

The first electrode 211 is connected to a connector extending through the dielectric layer to underlying access circuitry (not shown). The underlying access circuitry can be formed by standard processes as known in the art, and the configuration of elements of the access circuitry depends upon the array configuration in which the memory cells described herein are implemented. Generally, the access circuitry may include access devices such as transistors and diodes, word lines and sources lines, conductive plugs, and doped regions within a semiconductor substrate.

The first electrode 211 and the dielectric layer can be formed, for example, using methods, materials, and processes as disclosed in co-owned U.S. Pat. No. 8,138,028, which is incorporated by reference herein. For example, a layer of electrode material can be formed on the top surface of access circuitry (not shown), followed by patterning of a layer of photoresist on the electrode layer using standard photolithographic techniques so as to form a mask of photoresist overlying the location of the first electrode 211. Next, the mask of photoresist is formed overlying the location of the first electrode 211. Then the layer of electrode material is etched using the mask of photoresist. Next, dielectric material is formed and planarized.

At step 452 a conglomerate material is formed using physical vapor deposition in a sputtering system. The sputtering system includes a chamber in which a sputter target having an overdosed element of additive and a substrate are mounted. The term “overdosed” used herein refers to the amount of the additive in the sputter target is greater than that in the conglomerate material. For example, to form the conglomerate material with 5% of an additive, the sputter target may have 20% of element of that additive. Also, the chamber is configured with a gas source of the reaction gas, such as oxygen or nitrogen for use in causing addition of other components in the conglomerate material. The conglomerate material is formed including nanocrystalline grains 215 (less than 10 nm in the minimum dimension) embedded in an amorphous matrix 213. The conglomerate material comprises a chalcogenide with an amount of germanium effective to cause the conglomerate material to form the nanocrystalline grains 215 in the amorphous matrix 213. Also, the conglomerate material comprises a chalcogenide with one or more additives selected from a group including silicon, oxygen, nitrogen and carbon, in an amount or amounts effective to cause the conglomerate material to form the nanocrystalline grains 215 in the amorphous matrix 213.

Next, at step 454 a second electrode 214 is formed on the conglomerate material.

FIG. 19 is a simplified block diagram of an integrated circuit 500 including a memory array 502 having memory cells with memory elements comprised of a conglomerate material. A word line decoder at 504 having read, set and reset modes is coupled to and in electrical communication with a plurality of word lines 506 arranged along rows in the memory array 502. A bit line (column) decoder 508 is in electrical communication with a plurality of bit lines 510 arranged along columns in the array 502 for reading, setting, and resetting the phase change memory cells (not shown) in array 502. A current limiter 511, which is optional, is coupled to the bit lines in this example, which is controlled by the controller 524 during the reset operation, during the set operation, or during both operations as described above. A current limiter can comprise a controlled current resource or a variable resistance element, for example. Addresses are supplied on bus 512 to word line decoder and drivers 504 and bit line decoder 508. Sense circuitry (Sense amplifiers) and data-in structures in block 514, including voltage and/or current sources for the read, set, and reset modes are coupled to bit line decoder 508 via data bus 516. Data is supplied via a data-in line 518 from input/output ports on integrated circuit 500, or from other data sources internal or external to integrated circuit 500, to data-in structures in block 514. Other circuitry 520 may be included on integrated circuit 500, such as a general purpose processor or special purpose application circuitry, or a combination of modules providing system-on-a-chip functionality supported by array 502. Data is supplied via a data-out line 522 from the sense amplifiers in block 514 to input/output ports on integrated circuit 500, or to other data destinations internal or external to integrated circuit 500.

A controller 524 implemented in this example, using a bias arrangement state machine, controls the application of bias circuitry voltage and current sources 526 for the application of bias arrangements including read, program, erase, erase verify and program verify voltages and/or currents for the word lines and bit lines. In another embodiment, bias circuitry may include a current limiter instead of, or in addition to the current limiter 511, so as to limit the magnitude of the reset current, without melting or otherwise eliminating the nanocrystalline grains in the conglomerate material and to limit the magnitude of the set current to crystallization and elimination of the bodies of amorphous material between the nanocrystalline grains. In addition, bias arrangements for melting/cooling cycling may be implemented. Controller 524 may be implemented using special-purpose logic circuitry as known in the art. In alternative embodiments, controller 524 comprises a general-purpose processor, which may be implemented on the same integrated circuit to execute a computer program to control the operations of the device. In yet other embodiments, a combination of special-purpose logic circuitry and a general-purpose processor may be utilized for implementation of controller 524.

While the present technology is disclosed by reference to the preferred embodiments and examples detailed above, it is to be understood that these examples are intended in an illustrative rather than in a limiting sense. It is contemplated that modifications and combinations will readily occur to those skilled in the art, which modifications and combinations will be within the spirit of the invention and the scope of the following claims.

Claims

1. A memory device, comprising: a first electrode having an electrode surface;a conglomerate material on the electrode surface, the conglomerate material including nanocrystalline grains embedded in an amorphous matrix;a second electrode on the conglomerate material; andcircuitry to apply a first bias arrangement to induce formation of amorphous material between the nanocrystalline grains within a region over the electrode surface, effective to increase electrical resistance of the conglomerate material between the first and second electrodes above a first threshold without eliminating nanocrystalline grains in the region, and to apply a second bias arrangement to induce expansion of the nanocrystalline grains in the region by an amount effective to decrease electrical resistance of the conglomerate material between the first and second electrodes below a second threshold.

2. The device of claim 1, wherein the conglomerate material is composed of a phase change material.

3. The device of claim 1, wherein the conglomerate material is composed of a phase change material and an additive.

4. The device of claim 1, wherein after the first bias arrangement is applied the amorphous material surrounds the nanocrystalline grains, and after the second bias arrangement is applied the nanocrystalline grains surround the amorphous material.

5. The device of claim 1, wherein the conglomerate material comprises a chalcogenide with an amount of germanium effective to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix.

6. The device of claim 5, wherein the chalcogenide comprises GexSbyTez.

7. The device of claim 1, wherein the conglomerate material comprises a chalcogenide with one or more additives selected from a group including silicon, oxygen, nitrogen and carbon, in an amount or amounts effective to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix.

8. The device of claim 1, further including a current limiter to limit current flow through the conglomerate material during the first bias arrangement.

9. A method for operating a memory device having a memory element comprising a conglomerate material including nanocrystalline grains embedded in an amorphous matrix disposed between first and second electrodes, the method comprising: to store a first data value, applying a first bias arrangement to induce formation of amorphous material between the nanocrystalline grains within a region over the first electrode, by an amount effective to increase electrical resistance of the conglomerate material between the first and second electrodes above a first threshold without eliminating nanocrystalline grains in the region; andto store a second data value, applying a second bias arrangement to induce expansion of the nanocrystalline grains within the region by an amount effective to decrease electrical resistance of the conglomerate material between the first and second electrodes below a second threshold.

10. The method of claim 9, including using a current limiter during the first bias arrangement to limit current flow through the memory element.

11. A method for manufacturing a memory device, comprising: forming a first electrode having an electrode surface;forming a conglomerate material on the electrode surface, the conglomerate material including nanocrystalline grains embedded in an amorphous matrix;forming a second electrode on the conglomerate material; andforming circuitry to apply a first bias arrangement to induce formation of amorphous material between the nanocrystalline grains within a region over the electrode surface, effective to increase electrical resistance of the conglomerate material between the first and second electrodes above a first threshold without eliminating nanocrystalline grains in the region, and to apply a second bias arrangement to induce expansion of the nanocrystalline grains in the region by an amount effective to decrease electrical resistance of the conglomerate material between the first and second electrodes below a second threshold.

12. The method of claim 11, wherein the conglomerate material is composed of a phase change material.

13. The method of claim 11, wherein the conglomerate material is composed of a phase change material and an additive.

14. The method of claim 11, wherein said forming a conglomerate material includes depositing elements of the conglomerate material using physical vapor deposition.

15. The method of claim 11, wherein the conglomerate material comprises a chalcogenide with one or more additives selected from a group including silicon, oxygen, nitrogen and carbon.

16. The method of claim 11, wherein the conglomerate material comprises a chalcogenide with an amount of germanium effective to cause the conglomerate material to form the nanocrystalline grains in the amorphous matrix.

17. The method of claim 16, wherein the chalcogenide comprises GexSbyTez.

18. The method of claim 11, wherein the conglomerate material comprises a chalcogenide with one or more additives selected from a group including silicon, oxygen, nitrogen and carbon, in an amount or amounts effective to cause the conglomerate to form the nanocrystalline grains in the amorphous matrix.