FIELD OF THE INVENTION The invention relates to the field of random access memory (RAM) devices formed using a chalcogenide-based resistance variable memory element.
BACKGROUND OF THE INVENTION A well-known semiconductor memory component is a random access memory (RAM). RAM permits repeated read and write operations on memory elements. Typically, RAM memory elements are volatile, in that stored data is lost once the power source is disconnected or removed. Non-limiting examples of RAM devices which contain such memory elements include dynamic random access memory (DRAM), synchronized dynamic random access memory (SDRAM) and static random access memory (SRAM). DRAM's and SDRAM's typically store data in capacitors which require periodic refreshing to maintain the stored data.
Recently, resistance variable memory elements have been investigated for suitability as semi-volatile and non-volatile random access memory elements. A class of such devices include an insulating material formed of a chalcogenide glass disposed between two electrodes. A conductive material is incorporated into the material. The resistance of the material can be changed between high and low resistance states by application of suitable voltages across the memory element. D. D. Thornburg has discussed polarization of arsenic triselenide in an electric field. For instance, the polarization of arsenic triselenide allows the memory device to switch between different memory states. See Thornburg, D. D.,Memory Switching in Amorphous Arsenic Triselenide, J. NON-CRYST. SOLIDS11 (1972), at 113-120; Thornburg, D. D. and White, R. M.,Electric Field Enhanced Phase Separation and Memory Switching in Amorphous Arsenic Triselenide, J. APPL. PHYS. (1972), at 4609-4612.
When set in a particular resistance state, the particular resistance state of the memory element will remain intact for minutes, hours, or longer even after the voltage potentials are removed. Such a device can function, for example, as a semi or non-volatile resistance variable memory element having two resistance states, which in turn can define two logic states.
BRIEF SUMMARY OF THE INVENTION In one aspect, exemplary embodiments of the invention provide a resistance variable memory element and a method of forming the same in which a doped chalcogenide glass contains regions of polarizable metal-chalcogen material forming a conducting channel present within a chalcogenide glass backbone. The conducting channel can receive and expel metal ions in and out of it to set a particular resistance state for the memory element in response to write and erase voltages.
In another aspect, exemplary embodiments of the invention provide a resistance variable memory element and a method of forming the same in which the resistance variable memory element comprises at least one chalcogenide glass layer and at least one metal-containing layer formed between two electrodes. The chalcogenide glass layer further comprises a conducting channel formed from at least partially bonded regions of metal-chalcogen and glass. The conducting channel can receive and expel metal ions in and out of it to set a particular resistance state for the memory element in response to write and erase voltages.
In another aspect, embodiments of the invention provide a method for changing the resistance state of a resistance variable memory element. A conditioning voltage is applied to produce a conducting channel within a glass network. The conducting channel can receive and expel metal ions to set a particular resistance state for the memory element through subsequent programming voltages, such as write and erase voltages.
These and other features and advantages of exemplary embodiments of the invention will be better understood from the following detailed description, which is provided in connection with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGSFIGS. 1A-1F illustrates a cross-sectional view of a resistance variable memory device fabricated in accordance with a first embodiment of the invention.
FIGS. 2A-2F illustrates a cross-sectional view of a resistance variable memory device fabricated in accordance with a second embodiment of the invention.
FIGS. 3A-3F illustrates a cross-sectional view of a resistance variable memory device fabricated in accordance with a third embodiment of the invention.
FIGS. 4A-4F illustrates a cross-sectional view of a resistance variable memory device fabricated in accordance with a fourth embodiment of the invention.
FIG. 5 illustrates a processor-based system having one or more memory devices that contains resistance variable memory elements according to the various embodiments of the invention.
DETAILED DESCRIPTION OF THE INVENTION In the following detailed description, reference is made to various specific embodiments of the invention. These embodiments are described with sufficient detail to enable those skilled in the art to practice the invention. It is to be understood that other embodiments may be employed, and that various structural, logical and electrical changes may be made without departing from the spirit or scope of the invention.
The term “substrate” used in the following description may include any supporting structure including but not limited to a glass, plastic, or semiconductor substrate that has an exposed substrate surface. A semiconductor substrate should be understood to include silicon, silicon-on-insulator (SOI), silicon-on-sapphire (SOS), doped and undoped semiconductors, epitaxial layers of silicon supported by a base semiconductor foundation, and other semiconductor structures which may not be silicon-based. When reference is made to a semiconductor substrate in the following description, previous process steps may have been utilized to form regions or junctions in and/or over the base semiconductor or foundation.
Applicant has discovered that metal-chalcogen regions, such as silver-selenide, formed in a chalcogenide glass layer, for example, germanium-selenide, can be polarized upon application of a conditioning voltage and align to form a conducting channel within the chalcogenide glass layer. The conducting channel alters the resistance state of the glass from a very high resistance state, e.g. 1 GΩ, to a medium resistance state, e.g., 10 MΩ. A subsequently applied write voltage, having an energy lower than that of the conditioning voltage, can then program the glass to a lower resistance state, e.g. 10 kΩ, by causing available metal ions to move into the conducting channels where they remain after the write voltage is removed. The metal ions within the conducting channel can be removed by application of a negative polarity erase voltage. Because the conducting channel is previously formed by the conditioning voltage before a write or erase operation occurs, higher speed switching of the glass between resistance states can be achieved compared to trying to form and completely decompose conductive pathways each time the glass is written or erased to a resistance state. The glass layer can be used to construct memory elements.
For purposes of a simplified description, memory elements are described below in which a metal-chalcogen is described as silver-selenide, and the chalcogenide glass as germanium-selenide. However, these specific materials are not considered as limiting the invention.
The invention will now be explained with reference to FIGS.1A-F;2A-2F;3A-3F; and4A-4-F, which respectively illustrate exemplary embodiments of a resistancevariable memory element100,101,102 and103, and their methods of formation and operation, in accordance with the invention.
FIG. 1A depicts a first exemplary embodiment of a resistancevariable memory element100 and its method of formation in accordance with the invention. Afirst electrode2 is formed over asubstrate1. Thefirst electrode2 may comprise a conductive material, for example, various metals such as, one or more of tungsten, tantalum, aluminum, platinum, silver, or titanium nitride, among others. In addition, thefirst electrode2 can comprise a conductively-doped semiconductor material. Thefirst electrode2 should preferably not produce or expel metal ions, as discussed below.
AlthoughFIG. 1A illustrates afirst electrode2 provided onsubstrate1, it should be appreciated that additional layers may be provided betweenelectrode2 and thesubstrate1. For instance, a barrier layer may be used to prevent migration of metal ions fromlayer2. In addition, asemiconductor substrate1 containing circuit layers covered with an insulating layer can be provided belowfirst electrode2 if desired.
Next, aglass layer4 is formed over the firstconductive electrode2. Theglass layer4 is electrically coupled toelectrode2. Theglass layer4 is preferably achalcogenide glass layer4 that has been doped, e.g. photodoped, with a metal ion such as silver (Ag), and is more preferably a germanium-selenide glass layer4 having a GexSe100−xstoichiometry doped with Ag ions. The stoichiometric range forglass layer4 is preferably from about Ge18Se82to about Ge25Se75, and is more preferably about Ge25Se75when metal ions, such as Ag ions, are provided in theglass layer4 by a doping process.Glass layer4 is formed to a thickness of from about 150 Å to about 600 Å thick, and is preferably about 500 Å thick.
Althoughglass layer4 is described as a chalcogenide glass layer, other suitable glass layers may be employed as well. For instance, suitable glass material compositions for theglass layer4 can include, but are not limited to, AsSe (arsenic-selenide, such as As3Se2), GeS (germanium-sulfide), and combinations of Ge, Ag, and Se, among others. Any one of the suitable glass materials forglass layer4 and may further comprise small concentrations of dopants such as nitrogen nitrides, metals, and other group 13-17 elements from the periodic table.
The formation of thechalcogenide glass layer4 having a stoichiometric composition such as Ge25Se75in accordance with one exemplary embodiment of the invention, can be accomplished by any suitable method. For instance, by evaporation, co-sputtering germanium and selenium in the appropriate ratios, sputtering using a germanium-selenide target having the desired stoichiometry, or chemical vapor deposition with stoichiometric amounts of GeH4and SeH2gases (or various compositions of these gases), which result in a germanium-selenide film of the desired stoichiometry, are some non-limiting examples of methods which can be used to form theglass layer4.
After thechalcogenide glass layer4 is formed, metal ions are doped into theglass layer4 by a photodoping process. For instance, thechalcogenide glass layer4, such as Ge25Se75, can be photodoped with a metal such as Ag. Metal ions can be driven into theglass layer4 by applying a metal (Ag) layer on top of theglass layer4 and exposing theglass layer4 and metal layer to visible radiation. The metal layer can be formed over theglass layer4, for example, by sputtering, physical vapor deposition, or other well-known techniques in the art.
The metal doping ofglass layer4 causes theglass layer4 to contain polarizable metal-chalcogenregions30 andglass backbone regions50, as shown inFIG. 1B. In this context, polarizable regions are regions which can physically align in the presence of a suitable voltage applied across a memory element.
It should be appreciated that the polarizable metal-chalcogenregions30 are distinct regions within theglass layer4. Whenglass layer4 is doped with a metal ion, theglass layer4 will phase separate into polarizable metal-chalcogenregions30 andglass backbone regions50. See Maria Mitkova, et al.,Dual Chemical Role of Ag as an Additive in Chalcogenide Glasses, PHYSICALREVIEWLETTERS, Nov. 8, 1999, at 3848-3851. If Ag is used as the dopant metal ion and germanium selenide, e.g. Ge25Se75, is used forglass layer4, the polarizable metal-chalcogenregions30 are Ag2Se regions within a germanium selenide backbone. In essence, theglass backbone regions50 are non-metal containing glass regions with a stoichiometry determined by the loss of selenium (Se) from the germanium selenide glass to the formation of Ag2Se.
Referring back toFIG. 1A, asecond electrode10 is then formed over theglass layer4 and any residual metal ions, e.g. Ag, remain inglass layer4 to complete the formation of the resistancevariable memory element100. Thesecond electrode10 may comprise any conductive material, for example, various metals, such as, one or more of tungsten, tantalum, aluminum, platinum, silver, or titanium nitride among others. In addition, thesecond electrode10 can comprise a conductively-doped semi-conductive material, e.g., doped polysilicon.
Althoughelectrode10 may be directly applied toglass layer4, in a preferred embodiment, thesecond electrode10 is in contact with an intermediate metal-containinglayer5, which is provided overglass layer4. This intermediate metal-containinglayer5 is preferably a layer comprising Ag.
Although the doping of metal, e.g., Ag, into theglass layer4 will produce metal ions used, e.g, Ag ions withinglass layer4, the presence of the metal-containinglayer5 will serve as an additional source and receptacle for metal ions during write and erase operations. For example, for a germaniumselenide glass layer4 backbone containing polarizable Ag2Se metal-chalcogenregions30, during a ‘write’ process, the metal-containinglayer5 can be Ag and is a source of metal ions, e.g., Ag, which enterglass layer4. During an ‘erase’ process, the metal-containinglayer5 is the receptacle of the metal ions, e.g., Ag that move out of theglass layer4.
In another exemplary embodiment, themetal containing layer5 is omitted and thetop electrode10 is formed of a material capable of donating and receiving metal ions. For example,top electrode10 can be made of silver which would be in contact withglass layer4, and would then become a source and receptacle of metal ions during a write and erase operation. It is also possible to use anelectrode10, which donates or receives metal ions with metal-containinglayer5, which also donates or receives metal ions, in combination.
It should be appreciated that thefirst electrode2 and thesecond electrode10 can comprise the same or different materials. However, for example, if thefirst electrode2 and thesecond electrode10 comprise the same material such as tungsten or any other non-metal ion comprising metal, one side of thememory element100, preferably the side with thesecond electrode10, must have an excess of metal ions, e.g., Ag which, in the preferred embodiment, is metal-containinglayer5.
Because the metal ions, e.g., Ag ions which enter and leaveglass4 comes fromlayer5, if provided, orlayer10, iflayer5 is not provided, it is preferable thatelectrode2 not donate any metal ions. As a result, although intervening barrier layers are not illustrated in theFIG. 1A embodiment, intervening barrier layers can be present to prevent metal ion migration fromelectrode2 intoglass layer4, or fromelectrode10 intoglass layer4. The barrier layers, if provided, should not contain mobile metal ions.
A method of operating and manipulating the resistance state of the memory element depicted inFIG. 1A will now be described in reference toFIGS. 1B-1F.
Reference is now made toFIG. 1B which is a cross-sectional view of thememory element100 ofFIG. 1A prior to application of a conditioning voltage. AsFIG. 1B illustrates, thechalcogenide glass regions50 and polarizable metal-chalcogenregions30 have no long range order, i.e., they are randomly distributed. For a germaniumselenide glass layer4 and Ag ion configuration, the dopedchalcogenide glass layer4, contains regions of germanium-selenide50 and regions of polarizable silver-selenide30. Free Ag ions may also be present inglass layer4. The germanium-selenide regions50 serve as the glass backbone formemory element100.
Referring now toFIG. 1C, when a conditioning voltage (V1) of suitable energy, for example, is applied from a voltage source (DC)20, one or more regions of silver-selenide30 will polarize, that is, align to form a conductingchannel60. The aligned silver-selenide regions40form conducting channel60 which spans the entire thickness ofglass layer4. The application of V1induces the alignment of the polarizable silver-selenide regions. It has been found that a conditioning voltage (V1) about 200 mV under DC switching conditions and about 1.7V, 500 ns under AC conditions, is sufficient to physically align the Ag2Se regions30 and form the conductingchannel60.
After the conditioning voltage V1is applied,memory element100 is in a ‘medium’ state of resistance. Prior to application of the conditioning voltage illustrated inFIG. 1B, thememory element100 is in a ‘high’ state of resistance. As a non-limiting example, a ‘high’ state of resistance formemory element100 can be greater than 1 GΩ. A ‘medium’ state of resistance, produced by the alignment of the Ag2Se regions30 can be around 1 MΩ.FIG. 1C illustrates thememory element100 in the ‘medium’ state of resistance after applying a conditioning voltage V1.
The conditioning voltage V1is at a higher potential than subsequent potentials used to write, read, or erase thememory element100. This is due to the initial disorder of the polarizable silver-selenide regions30, as illustrated inFIG. 1B. Prior to application of the conditioning voltage V1, the structure of thememory element100 is in the most disordered state. Thus, to bring thememory element100 into a more structured state illustrated inFIG. 1C, a conditioning voltage V1which is larger than subsequently applied write, erase or read voltages is required.
Any suitable number, including all of the polarizable regions of silver-selenide30, can be polarized to form conductingchannel60 which extends throughout the thickness ofglass layer4. The amplitude of V1, necessary to induce formation of conductingchannel60, will depend upon the pulse width,glass layer4 composition, and thickness. With an exemplary embodiment of Ag2Se formed within a glass with an initially Ge2Se75stoichiometry before addition of Ag, having a thickness of 500 Å, and a metal-containinglayer5 of Ag having a thickness of 200 Å, a 1.7V pulse having a duration of 500 ns was found to be sufficient.
Thepreestablished conducting channel60 allows additional metal ions within theglass layer4, or from the metal-containinglayer5, and/orelectrode10, to move into and out of the conductingchannel60 upon application of a potential across the two electrodes. Thus, the resistance state of thememory element100 can be changed quickly. In other words, the movement of the Ag ions in the conductingchannel60 upon application of a write voltage V2, which has a potential less than the conditioning voltage V1, can lower the resistance state of thememory element100 from the medium resistance state of e.g., 1 MΩ, to a lower resistance state of e.g., 10 kΩ. When an erase voltage of inverse polarity to the write voltage is applied, the silver ions are driven out of the conductingchannel60 and back into theglass layer4 and metal-containinglayer5, and/orelectrode10, increasing the resistance state of thememory element100 back to the medium resistance state. The erase voltage need only be sufficient to drive Ag ions out of the conductingchannel60. The conductingchannel60 is not dispersed and is still maintained.
Because the conductingchannel60 always remains intact, the switching speeds and response of thememory element100 are enhanced because the Ag ions can move into and out of the conductingchannel60 without the need to reform thechannel60 every time thememory element100 is switched.
It should be appreciated that the presence of theglass regions50, here, germanium-selenide regions50, serve to isolate the polarizable metal-chalcogenregions30 from each other, here, polarizable silver-selenide regions30. The germanium-selenide regions50 also restrict the mobility and provide isolation between the polarized silver-selenide regions40. As a result, oncememory element100 is written to a low resistance state, enhanced data retention arises due to the polarized silver-selenide regions40 being held more rigidly in theglass backbone50.
It should also be appreciated that although only one conductingchannel60 is illustrated inFIGS. 1C-1F, one ormore conducting channels60 may be formed inglass layer4. Moreover, conditioning of thememory element100 is conducted only once, and after thememory element100 is conditioned, theconditioned structure100 will operate through normal write and erase operations.
FIG. 1D illustrates thememory element100 after a write operation is performed. A write voltage V2is applied from avoltage source20, to ‘write’ information into the resistancevariable memory element100. The write voltage V2, occurs at a lower potential than the conditioning voltage V1. For example, if the conditioning pulse is 200 mV,memory element100 should be written with a ‘write’ voltage V2of less than 200 mV. As shown inFIG. 1D, the additional Ag ions enter the preestablishedconductive channel60 to further complete the conductive path and lower the resistance of thememory element100. With this exemplary embodiment of Ag2Se formed within a glass with an initially Ge25Se75stoichiometry before addition of Ag, having a thickness of 500 Å, and a metal-containinglayer5 of Ag of thickness 200 Å, a write voltage of about 700 mV with a pulse width of about 100 ns was found to be sufficient.
Applying the write voltage V2causes Ag ions to move into the conductingchannel60 from the side with the positive potential, hereelectrode10. The Ag ions are supplied from any free Ag ions withinglass layer4, and the metal-containinglayer5, and/orelectrode10.FIG. 1D illustratesmemory element100 in the ‘low’ state of resistance, e.g., around 10 kΩ.
It should be appreciated that the preestablishedconductive channels60 may be affected by high temperatures as the metal ions and polarizable metal-chalcogenregions30 become more mobile. Accordingly, when this occurs, it may be desirable to periodically refresh the memory elements by periodically reapplying the conditioning pulse V1to reset theconductive channel60 and thereby resetting thememory element100 to its medium resistance state.
Referring now toFIG. 1E, a ‘read’ operation is illustrated in which a read potential V3, which is less than write potential V2, is applied to thememory element100. Current flow through thememory element100 is sensed by acurrent sensing amplifier32, which provides an output representing the resistance state of thememory element100.
A read voltage V3, which is below the threshold for writing thememory element100, e.g., V2, is sufficient. Where the write voltage V2is about 700 mV with a pulse duration of 100 ns, the read voltage V3can then be a potential less than about 200 mV with a pulse width less than about 500 ns. The read voltage V3does not disturb other memory elements in a memory element array, which are in the pre-conditioned medium resistance ‘OFF’ state, since the read voltage V3is lower than the write voltage V2. The read voltage V3may be applied in various manners, such as a sweep voltage, pulse voltage, or step voltage, among other methods.
FIG. 1F illustrates thememory element100 when an erase voltage is applied across theelectrodes2 and10 fromvoltage source20. An erase voltage V4having an inverse polarity from the write voltage V2is applied fromelectrode10 toelectrode2 to erase thememory element100. The erase voltage V4may also be of a smaller absolute magnitude than the write voltage V2.
The application of an erase voltage V4moves Ag ions out of the conductingchannel60 toward the electrode with the negative potential. This is electrode10 inFIG. 1F. The Ag ions will move out of the conductingchannel60 and into the metal-containinglayer5, theglass layer4, and/orelectrode10 if theelectrode10 contains Ag. Stated in another way, the erase is essentially a function of removing Ag ions from conductingchannel60. As a result, the erase is complete when the resistance of thememory element100 returns to the ‘medium’ state of resistance, i.e., around 1 MΩ.
It is important to note that after an erase operation, the conductingchannel60 ofFIG. 1C remains intact; thus, allowing for faster write and erase switching times. In other words, the erase voltage V4returns thememory element100 to the state of resistance illustrated inFIG. 1C. Thus, the erase voltage V4should be low enough to cause a resistance shift in thememory element100, but not of a magnitude which would destroy the conductingchannel60.
It should be appreciated that the conditioning, write, and erase pulse widths are dependent on the electric field amplitude, i.e., the applied voltage. Thus, shorter pulses will require higher voltages for V1, V2, and V4and vice versa. This is expected since the movement of Ag ions in the conductingchannel60 has an energy requirement for movement into and out of the conductingchannel60, which in turn is dependent upon the concentration of Ag ions which enters or leaves the conductingchannel60.
Reference is now made toFIG. 2A which shows another exemplary embodiment of the invention and its method of formation.
TheFIG. 2A embodiment has afirst electrode2 formed over asubstrate1. Thefirst electrode2 may comprise any of the conductive materials listed above for the same electrode as in theFIG. 1A embodiment. Similar to theFIG. 1A embodiment, additional barrier layers may be provided betweenelectrode2 andsubstrate1, if required to prevent metal ion migration. The barrier layers, if provided, should not contain mobile metal ions.
Next, aglass layer4 such as achalcogenide glass layer4 is formed over thefirst electrode2. Theglass layer4 is electrically coupled toelectrode2. Theglass layer4 is preferably achalcogenide glass layer4, and more preferably, a germanium-selenide glass layer4 having a GexSe100−xstoichiometry. The stoichiometric range forchalcogenide glass layer4 as depicted in theFIG. 2A embodiment is preferably from about Ge20Se80to about Ge43Se57, and is more preferably about Ge40Se60.Glass layer4 is formed to a thickness of from about 150 Å to about 500 Å thick, and preferably is about 150 Å thick.
For purposes of a simplified description, theglass layer4 ofstructure101 is described further below as achalcogenide glass layer4 and more specifically, a Ge40Se60layer. However, other suitable glass or polymer layers may be employed without affecting the utility of the invention. For instance, suitable glass material compositions for theglass layer4 can include but are not limited to, SiSe (silicon-selenide), AsSe (arsenic-selenide, such as As3Se2), GeS (germanium-sulfide), and combinations of Ge, Ag, and Se, among others. Any one of the suitable glass materials may further comprise small concentrations of dopants such as nitrogen nitrides, metals, andgroup 1, 2, and 13-17 elements from the periodic table.
The formation of theglass layer4 having a stoichiometric composition such as Ge40Se60in accordance with one exemplary embodiment of the invention, can be accomplished by any suitable method. For instance, evaporation, co-sputtering germanium and selenium in the appropriate ratios, sputtering using a germanium-selenide target having the desired stoichiometry, or chemical vapor deposition with stoichiometric amounts of GeH4and SeH2gases (or various compositions of these gases), which result in a germanium-selenide film of the desired stoichiometry, are some non-limiting examples of methods which can be used to form theglass layer4. It should be appreciated that theglass layer4 may comprise one or more layers of a glass material.
Still referring toFIG. 2A, a metal-containinglayer6, preferably silver-selenide, is deposited over thechalcogenide glass layer4. However, any suitable metal-containinglayer6 may be used so long as it interacts with the glass backbone such that it allows the transfer of metal ions intoglass layer4 upon application of a sufficient voltage across a memory element of which layers4 and6 are a part. For instance, besides silver-selenide, the metal-containinglayer6 may comprise silver, copper, or other transition metals. Other suitable metal-containinglayers6 which may be used include glass layers doped with a metal.
Preferably, the metal-containinglayer6 will comprise the same type of chalcogen component as is present inglass layer4. For example, ifglass layer4 is GexSe100−x, metal-containinglayer6 may be Ag2Se. The metal-containinglayer6 is formed to a thickness of from about 300 Å to about 1200 Å thick, and preferably is about 470 Å thick.
It should be appreciated that excess metal ions need to be provided either by metal-containinglayer6 itself, or through some other means for donation toglass layer4. For instance, metal-containinglayer6 can be formed to contain excess metal ions. That is, Ag2+xSe, where x represents excess Ag ions. Alternatively, if the excess metal ions are not part of the metal-containinglayer6, a separate second metal-containinglayer7 with a sufficient thickness that gives the desired excess amount of metal ions, e.g., Ag ions to the metal-containinglayer6 may be provided over or beneath the first metal-containinglayer6.
Anelectrode10 is provided over the conducting metal-containinglayer6, if metal-containinglayer7 is omitted, or is provided over metal-containinglayer7 if the latter is provided.Electrode10 need not donate any metal ions if one or both oflayers6 and7 provide sufficient metal ions for memory element operation.
In an exemplary embodiment, the second metal-containinglayer7 is provided and serves as a source and receptacle for metal ions doing write and erase operations. In another exemplary embodiment, thetop electrode10 may be the source and receptacle of additional metal ions when the second metal-containinglayer7 is omitted, and excess metal ions are not available inlayer6. In this case, thetop electrode10 may comprise silver, which donates and receives silver ions to and fromglass layer4.
Some non-limiting examples of forming the metal-containinglayer6 are physical vapor deposition techniques such as evaporative deposition, sputtering, chemical vapor deposition, co-evaporation, or depositing a layer of selenium above a layer of silver to form silver-selenide (Ag2Se) can also be used. It should be appreciated that the metal-containinglayer6 may comprise one or more layers of a metal-containing material. For purposes of a simplified description,FIGS. 2A-2F refer to the first metal-containinglayer6 as a silver-selenide layer6 and the second metal-containinglayer7 as asilver layer7. In thiscase electrode10 does not contribute metal ions to, or receive metal ions fromglass layer4.
Thesecond electrode10 may comprise any of the materials described above forelectrode10 of theFIG. 1A embodiment.FIG. 2A illustrates that thesecond electrode10 is in contact with an upper surface of the second metal-containinglayer7; however, intervening layers may be provided betweenlayers7 and10, if desired. As described above, the second metal-containinglayer7 can provide additional Ag ions. In addition, thesecond electrode10 can comprise Ag which can also provide additional Ag ions if the second metal-containinglayer7 is omitted frommemory element101.
In another exemplary embodiment, themetal containing layer7 is omitted and thetop electrode10, which is in contact with metal-containinglayer6, can provide and receive metal ions, e.g., Ag ions, and can be the source and receptacle of metal ions during a write and erase operation. It is also possible to use anelectrode10, which donates or receives metal ions with metal-containinglayer7, which also donates or receives metal ions in combination. It should be appreciated that thefirst electrode2 and thesecond electrode10 can comprise the same or different materials.
As described above, the first and second metal-containinglayers6 and7 can provide Ag ions. In addition, thesecond electrode10 can comprise Ag, if used, which can also provide Ag ions if the second metal-containinglayer7 is omitted frommemory element101, andlayer6 does not have excess Ag ions. Because the metal ions, e.g., Ag ions which enter and leaveglass4 is coming from the second metal-containinglayer7, if provided, orelectrode10, iflayer7 is not provided andlayer6 does not have excess Ag ions., it is preferable thatelectrode2 not donate any metal ions
As a result, although intervening barrier layers are not illustrated in theFIG. 2A embodiment, intervening barrier layers can be present to prevent metal ion migration fromelectrode2 intoglass layer4, or fromelectrode10 intoglass layer4. Barrier layers, if provided, should not contain mobile metal ions.
A method of operating and manipulating the resistance state of thememory element101 depicted inFIG. 2A will now be described in reference toFIGS. 2B-2F. For exemplary purposes, the methods of operation described inFIGS. 2B-2F is for amemory element101 comprising a Ge40Se60glass layer4 that is 150 Å thick, an Ag2Se layer 470 Å thick, and a silver layer 200 Å thick.
Reference is now made toFIG. 2B which is a cross-sectional view of theglass layer4 inmemory element101 ofFIG. 2A prior to application of a conditioning voltage acrossmemory element101. AsFIG. 2B illustrates, the germanium-selenide glass layer4 has no long range order, i.e., it has non-uniform distribution of Ge and Se within theglass layer4.FIG. 2B further illustrates the presence of germanium-germanium (Ge—Ge) bonds17 throughout theglass layer4. The presence of another species which can provide a more thermodynamically favorable energy than the Ge—Ge bond energy will ultimately break the Ge—Ge bonds17 and bond with the previously bonded Ge.
Referring now toFIG. 2C, a conditioning pulse having a potential V1, is applied acrossmemory element101. The conditioning pulse causes metal chalcogenide, e.g., Ag2Se from thelayer6 to enter intoglass layer4, thereby breaking Ge—Ge bonds17 in theglass layer4 and to formconductive channel11 within theglass4 backbone. The conditioning pulse's parameters are dependent upon the composition and thickness of the various layers comprisingmemory element101.
For a Ge40Se60glass layer4, a first Ag2Se layer6, and asecond Ag layer7 having the construction described, a conditioning pulse having a pulse duration from about 10 to about 500 ns and greater than about 700 mV has been found sufficient to formconductive channel11. The amplitude of the conditioning pulse will depend on the pulse width. The conductingchannel11 will form in the weakest part of thechalcogenide glass material4, i.e., in the areas that require the least amount of energy to form theconductive channel11. The conditioning pulse causes the conductingchannel11 to form by re-orientation of the GeSe and Ag2Se regions, as shown inFIG. 2C.
The Ag2Se provided from the first metal-containinglayer6, and driven into the glass layer's4 backbone, assists in forming the conductingchannel11 as it bonds with the germanium-selenide, i.e., as the Ag2Se bonds to the glass. It should be appreciated that a plurality of conductingchannels11 can be formed in thechalcogenide glass layer4. For purposes of a simplified description, only one conductingchannel11 is illustrated inFIGS. 2C-2F.
After application of the conditioning pulse,memory element101 is in a ‘medium’ state of resistance. Prior to application of a conditioning pulse, and as illustrated inFIG. 2B,memory element101 is in a ‘high’ state of resistance where the germanium-selenide regions are not oriented. For instance, a ‘high’ state of resistance which arises after the conditioning pulse is applied tomemory element101 can be about 1 GΩ. A ‘medium’ state of resistance can be around 1 MΩ.
In the medium resistance state, thememory element101 is still considered ‘OFF’ and remains in this conditioned state, with the Ag2Se regions, polarized and aligned in the direction of current flow, until the conductingchannel11 receives excess metal ions from the first metal-containinglayer6, if excess metal ions are present, and from the secondmetal containing layer7, and/orelectrode10 during a ‘write’ operation.
Therefore, applying a conditioning pulse across thememory element101 breaks the weak Ge—Ge bonds17 within the Ge40Se60glass layer4 and allows Ag2Se and ions thereof to bond to germanium-selenide sites. In part, the conditioning pulse V1, reorients the non-uniform state of the chalcogenide glass layer4 (FIG. 2B) into a more organized and structured state having aligned Ag2Se areas as illustrated inFIG. 2C. However, thememory element101 ofFIG. 2C is still in a medium or ‘OFF’ state of resistance.
Referring now toFIG. 2D, during a ‘write’ operation, excess Ag ions from metal-containinglayer6, Ag ions from metal-containinglayer7, and/orelectrode10 enter theglass4 and will cluster in the conductingchannel11, and more specifically, cluster to the germanium-selenide and Ag2Se bonded regions; thus, forming a low resistance conductive path asclustering structures12 inFIG. 2D illustrate. Theseclustering structures12, i.e., regions of Ag/Ag+, are formed throughout the conductingchannel11. The presence of theclustering structures12 provides a low resistance state formemory element101. A ‘write’ mode exists when a voltage V2less than the conditioning voltage V1is applied acrossmemory element101, thereby generating an ‘ON’ (low resistance) state formemory element101. Low resistance is about 10 kΩ.
It should be appreciated that the portion of the glass backbone around the conductingchannel11 does not contain much Ag ions. In fact, the majority of thechalcogenide glass layer4 does not contain Ag ions. The Ag ions from a ‘write’ operation proceed into the conductingchannel11 from the first metal-containinglayer6 if excess metal ions are present, the second metal-containinglayer7, and/orelectrode10. One exemplary write potential V2is preferably a pulse from about 8 to about a 150 ns that is less than the potential of V1, e.g., less than 700 mV. A write potential V2of about 400 mV has been found to be adequate with thememory element101. The amplitude of the write potential will vary depending on the pulse width.
As a result, during a write operation the Ag ions take the path of least resistance intoglass layer4. In this case, the path of least resistance is provided by the conductingchannel11. The Ag ions will migrate toward the negative potential, here,electrode2, when applied across thememory element101. Accordingly, the movement of the Ag ions into the conductingchannel11 renderschannel11 more conductive.
When an erase potential V4, having an inverse polarity to that of the write potential V2is applied to thememory element101, the Ag ions will leaveconductive channel11 and move back into the first metal-containinglayer6. Thememory element101 reverts back to the ‘medium’ state resistance, as illustrated inFIG. 2E. An exemplary erase potential V4is a pulse from about 8 to about 150 ns that is from about negative 400 mV (−400 mV) to about negative 700 mV (−700 mV) in amplitude. As with the write potential V2, the amplitude of the erase potential V4will depend on the pulse width.
It should be appreciated that application of an erase potential V4fromvoltage source20 across thestructure101, serves only to drive the free Ag ions (unbound Ag ions) out of the conductingchannel11 back to their original source The conductingchannel11 remains in place even after an erase potential V4is applied across thememory element101, so long as the erase potential V4does not greatly exceed the magnitude of the conditioning potential V1in reverse polarity.
It has been further discovered that applying another positive potential V3, to an already ‘ON’memory element101 structure, i.e, one in a low resistance state, illustrated inFIG. 2D, results in an even lower resistance ‘ON’ state caused by the presence of additional Ag/Ag+ ion clusters12, as illustrated inFIG. 2F. In essence, applying multiple ‘write’ pulses tomemory element101 can reduce the resistance state ofmemory element101 to a much lower resistance. In some instances, the resistance ofmemory element101 can be well below 10 kΩ.
In an exemplary embodiment ofmemory element101, a 10 ns, 1.7V conditioning pulse V, was applied to cause thememory element101, initially at 1 GΩ, to move into a ‘medium’ state of resistance of approximately 1 MΩ. A 10 ns, 700 mV write pulse V2was applied to thememory element101 to move it to a low resistance state of approximately 10 kΩ. A 10 ns, negative 550 mV erase pulse V4was applied to return thememory element101 to a medium resistance state. It was also observed that applying a 10 ns, 700 mV write pulse V3repeatedly to thememory element101 yielded lower and lower resistance states below 10 kΩ. Thus, thememory element101 could be used to set different detectable logic states in accordance with the number of applied write pulses V3.
For instance, a ‘read’ operation in which a read potential V5, which is less than write potential V2, can applied to thememory element101. Current flow through thememory element101 can be sensed by a current sensing amplifier, which can provide an output representing the resistance state of the memory element101 (not pictured).
A read voltage V5, which is below the threshold for writing thememory element101, e.g., V1, is sufficient. Where a 10 ns, 700 mV write pulse V2is used, the read voltage V5can then be in the range from any pulse less than about 500 ns and less than or equal to about 200 mV. The read voltage V5does not disturb other memory elements in a memory element array, which are in the pre-conditioned medium resistance ‘OFF’ state, since the read voltage V5is lower than the write voltage V2. The read voltage Vs may be applied in various manners, such as a sweep voltage, pulse voltage, or step voltage, among other methods.
FIG. 3A-3F depicts a third exemplary embodiment of a resistancevariable memory device102 constructed in accordance with the invention.
Afirst electrode2 is formed over asubstrate1. Thefirst electrode2 may comprise any of the conductive materials listed above as in theFIGS. 1A and 2A embodiments.
Next, afirst glass layer4 is formed over thefirst electrode2. Thefirst glass layer4 is electrically coupled toelectrode2. Thefirst glass layer4 can comprise the same materials as in prior embodiments and have the same stoichiometric ranges as theglass layer4 inFIG. 2A. For purposes of a simplified description, thefirst glass layer4 is described further below as a Ge40Se60chalcogenide glass layer4.Glass layer4 is formed to a thickness of from about 150 Å to about 500 Å thick, and preferably is about 150 Å thick.
The formation of thechalcogenide glass layer4, having a stoichiometric composition, such as Ge40Se60, can be accomplished by any of the methods described above for forming theglass layer4 ofFIG. 2A. Thefirst glass layer4 may comprise one or more layers of a glass material.
Still referring toFIG. 3A, a first metal-containinglayer6, preferably silver-selenide, is formed over the firstchalcogenide glass layer4. The formation of the first metal-containinglayer6, such as silver-selenide, can be accomplished by any of the methods described above for forming the metal-containinglayer6 ofFIG. 2A. The first metal-containinglayer6 may comprise one or more layers of a metal-containing material. The first metal-containinglayer6 is formed to a thickness of from about 300 Å to about 1200 Å thick, and preferably is about 470 Å thick.
Next, asecond glass layer8 is formed over the first metal-containinglayer6. Thesecond glass layer8 allows deposition of silver above a silver-selenide layer6, for instance. Thesecond glass layer8 can be utilized as a diffusion control layer to prevent metal ions from migrating fromelectrode10 into thememory element102. Thesecond glass layer8 is formed to a thickness of from about 100 Å to about 300 Å thick, and preferably is about 150 Å thick.
The formation and composition of thesecond glass layer8 is the same as described above for the formation and composition of theglass layer4 ofFIG. 3A. For purposes of a simplified description, thesecond glass layer8 is described as a chalcogenide glass layer having a stoichiometry similar to thefirst glass layer4 i.e., Ge40Se60. Further, one or more layers of glass material can be provided if desired forglass layer8. Thesecond glass layer8 may be formed to a thickness of from about 100 Å to about 300 Å thick, and preferably is about 150 Å thick.
Although thefirst glass layer4 and thesecond glass layer8 are described above as having a stoichiometry and material composition similar to each other i.e., Ge40Se60, it should be appreciated that thefirst glass layer4 and thesecond glass layer8 can possess different stoichiometries from each other, different thicknesses, and they can even be formed of different glasses.
As in the second embodiment, excess metal ions need to be provided in this embodiment as well, either by excess metal ions in the first metal-containinglayer6, by an optional second metal-containinglayer7 provided aboveglass layer8, or byupper electrode10. For instance, the first metal-containinglayer6 can be formed containing excess metal ions. Alternatively, if the excess metal ions are not part of the first metal-containinglayer6, i.e., added specifically or deposited with an excess metal, the metal ions need to be added as a separate second metal-containinglayer7 and/or anupper electrode10. The second metal-containinglayer7 should have a sufficient thickness that gives the desired excess amount of metal ions to theglass layer4.
The second metal-containinglayer7 can comprise any metal ions so long as it provides metal ions to enable formation of a conducting channel in theglass layer4 after application of a conditioning pulse. For instance, the second metal-containinglayer7 may comprise silver or copper. In an exemplary embodiment, the second metal-containinglayer7 is present and serves as a source and receptacle for additional metal ions.
Asecond electrode10 is formed over thesecond glass layer8 or over the secondmetal containing layer7, if provided, as shown inFIG. 3A, to complete the formation of thememory element102. Thesecond electrode10 may comprise any of the conductive materials listed above for theelectrode10 described in reference toFIGS. 1A and 2A.FIG. 3A illustrates that thesecond electrode10 is in contact with an upper surface of the second metal-containinglayer7; however, intervening layers may be provided betweenlayers7 and10, if desired. As described above, the second metal-containinglayer7 can provide additional Ag ions. In addition, thesecond electrode10 can comprise Ag which can also provide additional Ag ions if the second metal-containinglayer7 is omitted fromstructure102.
It should be appreciated that thefirst electrode2 and thesecond electrode10 can comprise the same or different materials. However, for example, if thefirst electrode2 and thesecond electrode10 comprise the same material, such as tungsten or any other non-metal ion comprising metal, one side of thememory element102, preferably the side with thesecond electrode10, must have an excess of metal ions, Ag in the preferred embodiment, either inlayer6 or preferably as the second metal-containinglayer7.
As a result, although intervening barrier layers are not illustrated in theFIG. 3A embodiment, intervening barrier layers can be present to prevent metal ion migration fromelectrode2 intoglass layer4, or fromelectrode10 intoglass layer4, when the excess metal ions are provided bylayers6 and/or7. Barrier layers, if provided, should not contain mobile metal ions.
A method of operating and manipulating the resistance state of thememory element102 depicted inFIG. 3A is described below in reference toFIGS. 3B-3F. For exemplary purposes, the methods of operation described inFIGS. 3B-3F is for amemory element102 comprising a first Ge40Se60glass layer4 that is 150 Å thick, an Ag2Se layer 470 Å thick, a second Ge40Se60glass layer8 that is 150 Å thick and a silver layer 200 Å thick.
Reference is now made toFIG. 3B which is a cross-sectional view of theglass layer4 ofmemory element102 ofFIG. 3A prior to application of a conditioning pulse V1. AsFIG. 3B illustrates, theglass layer4, formed of Ge40Se60, has no long range order.FIG. 3B further illustrates the presence of germanium-germanium (Ge—Ge) bonds17 throughout theglass layer4. The presence of another species which can provide a more thermodynamically favorable energy will break the Ge—Ge bonds17 and bond with the previously bonded Ge. Accordingly, the Ge—Ge bond17 is not strong and can easily be broken.
Referring toFIG. 3C, when a conditioning pulse V1is applied acrossmemory element102, excess Ag ions from the first and/or second metal-containinglayers6,7 and/or from electrode10 (if ions are available), enter intoglass layer4 and break some of the Ge—Ge bonds17. Thisforms conducting channel11 via incorporation of Ag2Se from the first metal-containinglayer6 and is illustrated inFIG. 3C. The conditioning pulse's V1parameters are dependent upon composition and thickness of the layers comprisingmemory element102. Moreover, the methods ofoperating memory element101 depicted inFIGS. 2C-2F, is similar to the methods ofoperating memory element102 for write, read and erase operations. Thus, as described above with reference toFIGS. 2C-2F, the methods ofoperating memory element102 can proceed in a similar manner as illustrated inFIGS. 3C-3F.
FIG. 4A depicts a fourth exemplary embodiment of a resistancevariable memory device103 constructed in accordance with the invention.
Afirst electrode2 is formed over asubstrate1. Thefirst electrode2 may comprise any of the conductive materials listed above for theelectrode2 described in theFIGS. 1A, 2A and3A embodiments. Next, afirst glass layer4 is formed over thefirst electrode2. Thefirst glass layer4 is electrically coupled toelectrode2. Thefirst glass layer4 can comprise the same material as provided for theglass layer4 inFIGS. 2A and 3A.
For purposes of a simplified description, thefirst glass layer4 is described further below as a Ge40Se60chalcogenide glass layer4. The formation of the firstchalcogenide glass layer4 can be accomplished by any of the methods described above for forming theglass layer4 ofFIGS. 2A and 3A. Thefirst glass layer4 may comprise one or more layers of a glass material. Thefirst glass layer4 is formed to a thickness of from about 150 Å to about 500 Å thick, and preferably is about 150 Å thick.
Still referring toFIG. 4A, a first metal-containinglayer6, preferably silver-selenide, is formed over the firstchalcogenide glass layer4. The formation of the first metal-containinglayer6 can be accomplished by any of the methods described above for forming the metal-containinglayer6 ofFIGS. 2A and 3A. The first metal-containinglayer6 may comprise one or more layers of a metal-containing material. The first metal-containinglayer6 is formed to a thickness of from about 300 Å to about 1200 Å thick, and preferably is about 470 Å thick.
Next, asecond glass layer8 is formed over the first metal-containinglayer6. Thesecond glass layer8 may be used as a diffusion control layer to control the migration of metal ions into theglass layer4. The formation and composition of thesecond glass layer8 is the same as described above for the formation and composition of theglass layer4 ofFIGS. 2A and 3A. For purposes of a simplified description, thesecond glass layer8 is described as a chalcogenide glass layer having a stoichiometry similar to thefirst glass layer4 e.g., Ge40Se60. Further, one or more layers of glass material can be provided if desired.
Although thefirst glass layer4 and thesecond glass layer8 are described above as having a stoichiometry and material composition similar to each other, e.g., Ge40Se60, it should be appreciated that thefirst glass layer4 and thesecond glass layer8 can possess different stoichiometries from each other, be different thicknesses, and they can even be different glasses. Thesecond glass layer8 may be formed to a thickness of from about 100 Å to about 300 Å thick and preferably is about 150 Å thick.
Next, a second metal-containing layer9, preferably silver, is formed over thesecond glass layer8. The formation of the second metal-containing layer9 can be accomplished by any of the methods described above for forming the metal-containinglayer6 ofFIGS. 2A and 3A. The second metal-containing layer9 may comprise one or more layers of a metal-containing material. The second metal-containing layer9 is formed to a thickness of from about 100 Å to about 500 Å thick, and preferably is about 200 Å thick.
It should be appreciated that excess metal ions need to be provided either by the first metal-containinglayer6 or second metal-containing layer9, and/orsecond electrode10. For instance, the first metal-containinglayer6 can be formed containing excess metal ions. Alternatively, if the excess metal ions are not part of the first metal-containinglayer6 i.e., added specifically or deposited with an excess metal, the additional metal ions can be provided from the second metal-containing layer9 and/orsecond electrode10. The second metal-containing layer9 should have a sufficient thickness that gives the desired excess amount of metal ions to the first metal-containinglayer6. In an alternate embodiment, a third metal-containinglayer7 can be provided, if desired. Preferably, the third metal-containing layer comprises silver.
The second metal-containing layer9 can comprise any metal ions so long as it provides metal ions to the conductingchannel11 formed in thechalcogenide glass layer4 after application of a conditioning voltage across theelectrodes2 and10.
In an exemplary embodiment, the presence of the third metal-containinglayer7 serves as the source and receptacle for metal ions. For example, during a ‘write’ process, the third metal-containinglayer7 is the source of the metal ions that move into the conductingchannel11. During an ‘erase’ process, the third metal-containinglayer7 is the receptacle of the metal ions that move out of the conductingchannel11.
Asecond electrode10 is next formed over the third metal-containinglayer7, as illustrated inFIG. 4A, to complete the formation of thememory device103. Thesecond electrode10 may comprise any of the conductive materials listed above for theelectrode10 as described above in theFIGS. 2A and 3A embodiments.FIG. 4A illustrates that thesecond electrode10 is in contact with an upper surface of the third metal-containinglayer7; however, intervening layers may be provided betweenlayers7 and10, if desired. As described above, the third metal-containinglayer7 can provide additional Ag ions. In addition, thesecond electrode10 can comprise Ag which can also provide additional Ag ions if the third metal-containinglayer7 is omitted frommemory element103.
In another exemplary embodiment, the thirdmetal containing layer7 is omitted and the second metal-containing layer9, can provide and receive metal ions, e.g., Ag ions, and can be the source and receptacle of metal ions during a write and erase operation. It is also possible to use anelectrode10, which donates or receives metal ions with the third metal-containinglayer7 or second metal-containing layer9, which also donates or receives metal ions in combination.
It should be appreciated that thefirst electrode2 and thesecond electrode10 can comprise the same or different materials. However, for example, if thefirst electrode2 and thesecond electrode10 comprise the same material such as tungsten or any other non-metal ion comprising metal, one side of thememory element103, preferably the side with thesecond electrode10, must have an excess of metal ions, e.g., Ag.
As described above, the third metal-containinglayer7 can provide Ag ions or the second metal-containing layer9 can. In addition, thesecond electrode10 can comprise Ag, if used, which can also provide Ag ions if the third metal-containinglayer7 is omitted frommemory element103, if desirable. Because the metal ions, e.g., Ag ions which enter and leaveglass4 is coming from the third metal-containinglayer7, if provided, orlayer10, or layer9, iflayer7 is not provided, it is preferable thatelectrode2 not donate any metal ions
As a result, although intervening barrier layers are not illustrated in theFIG. 4A embodiment, intervening barrier layers can be present to prevent metal ion migration fromelectrode2 intoglass layer4, or fromelectrode10 intoglass layer4. Barrier layers, if provided, should not contain mobile metal ions.
A method of operating and manipulating the resistance state of the memory element depicted inFIG. 4A is described below in reference toFIGS. 4B-4F. For exemplary purposes, the methods of operation described inFIGS. 4B-4F is for amemory element103 comprising a first Ge40Se60glass layer4 that is 150 Å thick, a first Ag2Se layer 470 Å thick, a second Ge40Se60glass layer8 that is 150 Å, a second Ag2Se layer 200 Å thick, and a silver layer 300 Å thick.
Reference is now made toFIG. 4B which is a cross-sectional view of thememory element103 ofFIG. 4A prior to application of a conditioning pulse. AsFIG. 4B illustrates, the Ge40Se60glass layer4 has no long range order.FIG. 4B further illustrates the presence of germanium-germanium (Ge—Ge) bonds17 throughout theglass layer4. The presence of another species which can provide a more thermodynamically favorable energy than the Ge—Ge bond energy will break the Ge—Ge bonds17 and bond with the previously bonded Ge. Accordingly, the Ge—Ge bonds17 are not strong and can easily be broken.
Referring now toFIG. 4C, a conditioning pulse V, is applied tomemory element103.Memory element103 is conditioned in a similar manner as described above with regard tomemory elements101 and102. Conditioning thememory element103, is done only once and after thememory element103 is conditioned, the conditionedmemory element103 will operate through normal write and erase operations.
Accordingly, applying a conditioning pulse from thevoltage source20 forms a conductingchannel11 via incorporation of Ag2Se from the metal-containinglayer6 into the glass backbone which is illustrated inFIG. 4C. The Ag2Se becomes polarized and aligned within theglass4 backbone to formconductive channel11. The conditioning pulse's parameters are dependent upon the thickness of the layers comprisingmemory element103. Moreover, similar to the methods ofoperating memory elements101 and102 depicted inFIGS. 2C-2F and3C-3F, the method of operatingmemory element103 depicted inFIGS. 4C-4F, proceeds in an analogous manner as described above with reference toFIGS. 2C-2F and3C-3F.
It should be further appreciated that with regard tomemory elements101,102 and103, the presence of an additional metal-containinglayer7, which provides the Ag ions, can enhance the switching characteristics of thememory elements101,102 and103. For instance, since there are more available Ag ions to move in and out of the preformed conductingchannels11, thememory elements101,102 and103 can operate with greater speed.
Although the embodiments described above inFIGS. 1A-4F, refer to the formation of only one resistancevariable memory element100,101,102 and103, it must be understood that the invention contemplates the formation of any number of such memory elements. A plurality of resistance variable memory elements can be fabricated in a memory array and operated with memory access circuits. Thus, the resistancevariable memory elements100,101,102 and103 can be utilized in many electronic devices. Specifically, the methods and operation of the memory elements disclosed herein, can be used in any device whenever it is desired to have a resistance variable memory element with faster switching times.
The resistancevariable memory elements100,101,102 and103 of the invention may be used in memory applications as well as in creating various CMOS type circuits.
The invention is not limited to the details of the illustrated embodiments. Accordingly, the above description and drawings are only to be considered illustrative of exemplary embodiments which achieve the features and advantages of the invention. Modifications and substitutions to specific methods, process conditions, and structures can be made without departing from the spirit and scope of the invention. Accordingly, the invention is not to be considered as being limited by the foregoing description and drawings, but is only limited by the scope of the appended claims.