The present application claims priority from Japanese patent application JP 2010-067204 filed on Mar. 24, 2010, the content of which is hereby incorporated by reference into this application.
The present invention concerns a solid memory device and a recording method thereof and it particularly relates to a semiconductor memory device capable of rewriting for storing information by utilizing a material whose electric resistance changes reversibly by flowing a current to the device.
In recent years, resistance change type memories have been studied as a substitute for flash memories which are now approaching the limit of refinement and, as an example, phase-change memories have been studied vigorously using chalcogenide materials as the recording material. In a basic structure of the phase-change memory, a recording material is put between metal electrodes. The phase-change memory is a resistance, change type solid memory for storing information by utilizing that the recording material between the electrodes has different states of resistance.
The phase-change memory stores information by utilizing that the resistance value of a phase-change material such as Ge2Sb2Te5 is different between an amorphous state and a crystalline state. The resistance is high in the amorphous state and low in the crystalline state. Accordingly, reading is conducted by applying a potential difference across both ends of a device, measuring a current flowing through the device and judging whether the device is in a high resistance state or low resistance state.
In the phase-change memory, data is rewritten by changing the state of the phase-change film between the amorphous state and the crystalline state by the Joule heat generated by current. A reset operation, that is, the operation of changing the film to the amorphous state at a high resistance is conducted by flowing a relatively large current, to the phase-change film thereby melting the film and then quenching the same by rapidly decreasing the current. On the other hand, the setting operation, that is, the operation of changing the film to the crystalline state at a low resistance is conducted by flowing a relatively small current to the phase-change material and maintaining the material to a temperature higher than the temperature of crystallization. Since the volume of the phase-change material that changes the state is decreased by proceeding refinement and the necessary current is decreased, the phase-change memory is suitable to the refinement.
As a method of improving the integration degree of the phase-change memory, JP-A-2008-160004 discloses a technique of forming a plurality of through holes that pass through entire layers to a stack structure formed by alternately stacking gate electrode materials and insulating films each by plurality by corrective fabrication and depositing to fabricate a gate insulating film, a channel layer, and a phase-change film to the inner side of the through holes.
JP-A-2009-117854 discloses a technique of adding a resistance material such as TiN or C between metal electrodes and making it to act as a heater for decreasing the voltage which is necessary when the phase-change material is changed from the amorphous state to the crystalline state.
Change of the electric resistivity of the phase-change material in accordance with the temperature and the electric field intensity is explained in D. Adler et al., “Threshold Switching in Chalcogenide-Glass Thin Films”. J. Appl. Phys. 51(6), pp. 3289-3309 (1980). Specifically, in the Non-Patent Document, in the phase-change material, the electric resistance changes by several digits in the amorphous state in accordance with the temperature and the electric field. This shows that the electric resistivity in the amorphous state changes greatly depending on the constitution of a device to be measured and the current cycle voltage conditions, etc. For avoiding misunderstanding caused by the change of the electric resistivity or the electroconductivity depending on such measuring conditions, description is to be made in the present specification while showing the resistivity and the conductivity as values in the crystalline state unless otherwise specified.
As has been described above, information is rewritten by using Joule heat generated by a flowing current different from other memories. Accordingly, it is important how to utilize the generated Joule heat.
At first, since rewriting is conducted in the phase-change memory by the Joule heat generated by flowing a current, the amount of current necessary for rewriting is generally ten times as large as that of a flash memory. Accordingly, the data transfer rate in a solid memory using the phase-change material is limited by a permissible combustion power. For improving the integration degree of the phase-change memory, a structure of a vertical memory described in JP-A-2008-160004 is effective. However, also in the vertical type memory, it is an important technique of reducing a necessary current for rewriting in order to improve the data transfer rate. For the improvement, when the technique of the heater layer described in JP-A-2009-117854 is introduced there, this imposes a problem that the voltage necessary for rewriting can be lowered but the current is increased contrarily. That is, according to the concept of JP-A-2009-117854, since the temperature of the phase-change material is increased by thermal diffusion due to the heat generation of TiN, it is necessary to flow the current concentrically to the TiN film and, as a result, the amount of the current is increased.
However, in the vertical type memory as described in JP-A-2008-160004, a thin Si film is used for introducing electric energy to a memory bit portion of the phase-change material. In the thin Si film, since the number of free electrons is smaller different from the metal material described in JP-A-2009-117854, it is important to decrease the write current rather than the writing voltage.
Secondly, although not described in the known documents, since the state of the this phase-change material film is changed by the temperature hysteresis in the phase-change memory, a phenomenon occurs inevitably in which the state of already written adjacent bits is changed from the amorphous state to the crystalline state by thermal diffusion upon rewriting one bit. The phenomenon is to be referred to as cross erase. Unless the cross erase is suppressed, the reliability of the phase-change memory device cannot be ensured. The cross erase is sometimes referred to as thermal disturb in a general meaning. While a solid state memory using a phase-change material comprises a thin semiconductor material film such as Si, an insulating material film such as SiO2 and thin phase-change material film such as Ge2Sb2Te5, since the thermal conductivity of such materials is predetermined, the distance between adjacent memory bits is decreased as refinement is progressed, so that cross erase tends to occur easily.
The present invention intends to solve the problems described above and provide a structure of a phase-change memory of a vertical type memory structure capable of attaining high speed transfer rate and high reliability by decreasing the write current or suppressing the cross erase, as well as a writing method thereof.
Summary of the principal of invention disclosed in the present specification for solving the problems described above is as follows.
In a first aspect of the invention, a semiconductor memory device comprises a stack in which a plurality of inter-gate insulating layers and a plurality of gate layers are stacked alternately, a channel layer formed along the lateral side of the stack, an interface layer formed along the lateral side of the channel layer and a phase-change material layer formed along the lateral side of the interface layer, in which the thermal conductivity of the interface layer is lower than the thermal conductivity of the channel layer, and the electric resistivity of the interface layer is higher than the electric resistivity of the phase-change material layer in the crystalline state.
Further, in a second aspect of the invention, the semiconductor memory device includes a phase-change material layer with a thickness of less than 4 nm and an interface layer formed so as to be in contact with the phase-change material and comprising one of an alloy system of Si and chalcogenide, a material system in which an oxide thereof forms a compound at the boundary relative to the phase-change material layer and oxygen of the oxide is substituted by Te, a metal oxide having an interfacial energy of 3 mJ/m2 or less, and a metal nitride having an interfacial energy 3 mJ/m2 or less.
Further, in a third aspect of the invention, a memory device includes a cell array having
a stack in which a plurality of inter-gate layer insulating layers and a plurality of gate layers are stacked alternately, a channel layer formed along the lateral side of the stack, and a phase-change material layer formed along the lateral side of the channel layer, and
a device controller that controls the voltage for each of the plurality of gate layers and supplies a current flowing by way of the channel layer to the phase-change material layer situated on the lateral side of each of the plurality of gate layers, thereby writing information, in which
the device controller writes data successively from the upstream in the moving direction of the carriers in the channel portion.
Further, in a fourth aspect of the invention, a memory device includes:
a cell array having a first stack in which a plurality of first inter-gate insulating layers and a plurality of a first gate layers are stacked alternately, a second stack in which a plurality of second inter-gate insulating layers and a plurality of a second gate layers are stacked alternately, first channel layer formed along the lateral side of the first stack, a first phase-change layer formed along the lateral side of the first channel, a second channel layer formed along the lateral side of the second stack, a second phase-change layer formed along the lateral side of the second channel layer, and an insulating layer formed between the first phase-change material layer and the second phase-change material layer,
a device controller that controls the voltage of each of the plurality of first and second gate layers and supplies a current flowing by way of the first and the second channel layers to the first and the second phase-change material layers situated on the lateral side of each of the plurality of first and second gate layers, and
a codec that modulates information inputted from the outside and supplies the same to the device controller, in which
each of the plurality of first gate layers and the first phase-change material layer situated on the lateral side of each of the plurality of first gate layers are paired to form a first bit,
each of the plurality of second gate layers and the second phase-change material layer situated on the side of each of the plurality of second gate layers are paired to form a second bit in the cell array, and
the codec modulates the information inputted from the outside such that the first and the second phase-change material layers corresponding to the first bit and the second bit situated at an identical height among the plurality of the first bits and the plurality of the second bits takes one of the states of crystalline state-crystalline state, crystalline state-amorphous state, and amorphous state-crystalline state.
According to the invention, it is possible to decrease the write current or improve the reliability of the phase-change memory of a vertical memory structure.
Preferred embodiments of the invention are to be described specifically with reference to the drawings. Throughout the entire drawings for explaining the examples, components having identical functions carry the same reference numerals for which duplicate descriptions are omitted. Further, those portions described for characteristic constitutions are not restricted to each of the embodiments but identical effects can be obtained in other cases where they have common constitutions.
The structure can be attained by stacking the gate polysilicon layers 21p, 22p, 23p, and 24p, and the insulating film 11, 12, 13, 14, and 15 successively to form the stack, then forming connection hole connected to a diode PD to a portion of the stack after formation of the stack by etching or the like, and then forming the gate insulating film 9, the channel polysilicon layer 8p, the thin interface layer film 100, and the phase-change memory material 7 successively to the side wall of the connection hole. While the thin interface layer film 100 is separated from the bottom of the connection hole, it may be disposed onto the bottom. This is identical also in the structure of
Further, in the structure of
According to the vertical type memory structure described above, as a number of the stack in the direction of the height increases, the number of the gate polysilicon layers covered by the gate insulating film layer 9 and the phase-change material layer 7 formed upon layer formation for once is increased. Accordingly, this has an effect of increasing the number of cells that can be formed at a time, compared with the case of forming the layer while dividing the gate insulating film 9 and the phase-change material layer 7 on every gate polysilicon layer and the bit cost can be decreased.
Another feature is that the phase-change material layer is formed so as to cover the channel layer (they are formed in the order of gate, channel, phase-change material layer). In the lateral memory cell chain structure, since the channel is formed in a substrate, the phase-change material layer has to be formed above the gate. Therefore, it has to divert the gate and a contact is necessary for connecting the channel layer and the phase-change material layer. On the other hand, in this example, the phase-change material layer is formed so as to cover the channel layer. Accordingly, it is not necessary to divert the gate and the structure can be made finer by saving the contact and this can decrease the bit cost.
Connection 38p connects channel layer 8p and bit line 3; bit lines 3a and 3b are also shown.
In the same manner as for the structure in
In the vertical memory structures shown in
On the other hand, when the thickness of the insulating film layers 11, 12, 13, 14, and 15 is decreased excessively, since rewrite regions in the phase-change material layer 7 are close to each other, thermal disturb may be generated possibly between adjacent memory cells to each other. Accordingly, when the thickness for the insulating film layers 11, 12, 13, 14, and 15 is changed, increase of the channel conductance and the thermal disturb are in a trade off relation. In such a case, the channel layer situated between the gate polysilicon layers can be reversed intensely by using a material of high dielectric constant such as SiN for the insulating film layers 11, 12, 13, 14, and 15, so that the current in the channel layer increases without reducing the thickness of the insulating layers 11, 12, 13, 14, and 15 to conduct efficient rewrite operation. Needless to say, it is possible to decrease also the thickness of the insulating film layers 11, 12, 13, 14, and 15 to such an extent as not generating thermal disturb and using a material of high dielectric constant such as SiN for the insulating film.
Further, the structure shown in
Then, the effect of decreasing the write current of the interface layer 100 is to be described. For showing the advantage quantitatively, a simulator suitable to the analysis for characteristics of the vertical type memory is at first constituted, a guide line necessary for decreasing the write current of the phase-change memory is shown through the analysis for the result of a preliminary experiment, and the effectiveness of the vertical memory structure of the invention is to be shown quantitatively through the analysis thereof.
Generally, for the analysis of the write process of the phase-change memory, a Poisson equation or a Laplace equation is often used as a method for determining the current distribution. They are methods on the assumption that the current is 0 in a model in which an electric field distribution is calculated and then an electric conductivity is multiplied to the calculated value to determine the distribution of current flowing in the phase-change material and the generation of Joule heat. A sufficient accuracy can be expected for a device structure of a serial resistance connection type in which a phase-change material is disposed between metal electrodes. On the other hand, in the vertical type memory as shown in
In this case, the following constant current formula modified from the Maxwell equation is used for the calculation of a current density distribution j.
[Equation 1]
∇j=0,
j=−σ·∇φ (equation 1)
in which σ is an electric conductivity and φ is a potential.
A thermal diffusion equation is used for the calculation of a temperature distribution.
in which T is a temperature, t is a time, C is a volume heat capacity, K is a thermal conductivity, and Joule heat generation per unit volume is represented as the second term on the right side.
As a preliminary experiment, a device of a structure shown in
In the same manner,
Particularly, in a case of the vertical memory described in JP-A-2008-160004, while the thin Si film and the thin phase-change film are adjacent to each other and the thermal conductivity of the Si material is as high as 176 W/m·K, which is about equal with that of the W material, the phenomenon identical with that in the analysis described above is generated. Further, in the vertical memory structure, the electric property of the thin Si film is deteriorated since the material is diffused in the thin Si film or the temperature of the thin Si film increases when the thin phase-change film is melted.
In view of the result described above, in the phase-change memory device of the vertical memory structure, it can be seen that formation of a thin film of an interface layer material having a lower thermal conductivity than the thin Si film between the thin Si film and the thin phase-change material film is effective with a view point of decreasing the write current and improving the reliability of the phase-change memory device. It has been described for the structure that the interface layer 100 is in contact on its lateral side with the phase-change material layer 7 and in contact on its other lateral side with the polysilicon channel layer 8p in
Further, it is necessary for the material forming the interface layer that the material thermally insulates the thin Si film and the thin phase-change material film, as well as maintains electric connection for flowing a current by way of the interface layer 100 to the phase-change material layer 7. An example of the material is an Si—Te material. Specific examples of the material suitable to the interface layer are to be described later.
Then, characteristic analysis was conducted for the phase-change memory device of vertical structure shown in
For making the difference clear with respect to the heater material described in JP-A-2009-117854, a relation between the electric conductivity and the thermal conductivity is arranged in
For making the effect of the invention clearer, the result of calculation for the distribution of current and temperature is shown. For easy understanding, it is shown for the result of using the device structure shown in
As apparent from the result of the simulation described above, it can be seen that the structure of the invention in which an interface layer of high resistance and low thermal conductivity is formed between the Si channel and the phase-change material has a remarkable current decreasing effect and has an excellent performance as a phase-change memory device of vertical memory structure.
As described above, it is preferred that the interface layer 100 is in contact with the phase-change material layer 7 on one side thereof with a view point of the heat insulating effect. In this case, it directly undergoes the effect of the heat generation of the phase-change material layer 7. Accordingly, since it is necessary to be in a stable solid state during writing, the interface layer preferably has a melting point higher than that of the phase-change material.
As has been described above, the interface layer preferably comprises a material having a thermal conductivity lower than that of the channel portion (polysilicon channel 8p in this embodiment) and a resistivity higher than that of the phase-change material layer. Then, it is shown what is such a material.
As described above, at the minimum feature size of 32 nm by lithography, the film thickness of the phase-change material was about 4 nm. For proceeding the refinement further, it is necessary for the phase-change material to conduct reversible switching between amorphous and crystalline states at the film thickness of less than 4 nm. It has been generally considered that crystallization becomes difficult and switching operation is no more shown when the thickness of the phase-change material is about 6 nm or less. Then, by utilizing the resistance measurement device described above, the film thickness and the switching characteristics of the phase-change material sandwitched by various interface material films were measured. In this example, a Ge2Sb2Te5 compound material was used as the phase-change material.
(1) It has a necessary and sufficient adhesiveness so as to withstand a stress caused by volume change accompanying the phase change between the crystalline state and the amorphous state.
(2) It does not hinder the crystallization of the phase-change material.
(3) It has good adhesiveness with a semiconductor material (Si) as a current channel.
It is considered that an Si2Te3 material satisfies such performances. An SiTe material also satisfies the same required performances though the melting point is lower. In view of the result of the experiments described above, it can be seen that a first system including an alloy system of Si and chalcogenide is suitable as the interface layer material. For the material system, a first material system such as Si—Te system, Si—Sb system, Si—Bi system, Si—Sn system, and Si—Ge system is suitable. Unless otherwise specified particularly, those represented as “X-Y” show that they contain alloys of X and Y and may contain elements other than X and Y.
Further, as a second material system in which an oxide thereof is a material having good adhesiveness with Si and the phase-change material and oxygen is substituted by Te belonging to an identical periodical group, materials of Cr—Te system, Zn—Te system, Mn—Te system, Zr—Te system, and Hf—Te system are also suitable.
The experiment described above shows the results for the case of using the Ge2Sb2Te5 compound material as the phase-change material. In a case of using a metal oxide as the interface layer, no good result could be obtained when the thickness of the phase-change material was 2 nm. In a case of the metal oxide such as ZrO2 (with addition of Y2O3) it can be considered that a metal material and a phase-change material form a compound at a bonded face, which improves the adhesiveness but, at the same time, inhibits crystal growing of the phase-change material. Then, an experiment was conducted by using a Ge 5%-Sb 70%-Te 25% material as a typical eutectic phase-change material having a high crystal growing rate as the phase-change material.
A simple method of measuring the surface energy and the interfacial energy is to be described additionally. In this case, SiTe, SiSb, ZrO2, and AlTiN were investigated as the material for the interface layer. An angle of contact with pure water was measured for the material for the interface layer and Ge2Sb2Te5 as a typical phase-change material. For the test, specimens of the following two type structures were prepared: Si substrate/interface layer (50 nm), and Si substrate/interface layer (50 nm)/phase-change film (50 nm). Films were formed by sputtering. Si2Te3 and ZrO2 were formed by using sputtering targets having corresponding compositions. SiSb and AlTiN were formed by simultaneously sputtering of Si and Sb, and AlN and TiN respectively. For removing the spontaneous oxide film on the surface of the Si substrate, reverse sputtering for about 10 sec was conducted to the substrate before sputtering. Since it is forecast for actual devices that the film thickness is several nm and the adhesiveness has thickness dependence, confirmation in the state of the thin film is necessary. However, for confirming the property of the material per se, as a first stage, a sufficiently thick film was used. Further, while ZrO2 used herein contains Y2O3 by about 3% for suppressing volume expansion of ZrO2 as that used for usual devices, it is described as ZrO2 for the sake of simplicity.
A method of approximately estimating the interfacial energy γi-PC per unit area at the boundary between the interface layer and the phase-change material is to be described.
Assuming the surface tension of the interface layer as γi, the surface tension of pure water in air as γw, and the interfacial energy between the interface layer and the pure water as γiw, it is represented according to the Young's equation as:
[Equation 3]
γiw+γw cos θiw=γi (equation 3)
The factors for energy generation are mainly classified into three types, that is, dispersive force (main cause for van der Waals force), dipole-dipole interaction, and hydrogen bond. When the energies are expressed as γd, γp, and γn, respectively, they are shown according to the expanded Fowkes equation as:
[Equation 4]
γiw=γi+γw−2√{square root over (γidγwd)}−2√{square root over (γipγwp)}−2√{square root over (γihγwh)} (equation 4)
[Equation 5]
γ=γd+γp+γh (equation 5)
Values for respective term relative to water have been known and γwd=72.8 mJ/m2, γwd=29.1 mJ/m2, and γwp=1.3 mJ/m2, γwh=42.4 mJ/m2. For SiO2 and ZrO2, it is known that γSiO2=760 mJ/m2, and γZrO2=800 mJ/m2. According to actual measurement for the angle of contact, it was θiw=5° for SiO2 and θiw=52° for ZrO2. Assuming that hydrogen bond does not exert between the materials and pure water and γih=0, then γSiO2d=320.4 mJ/m2, γSiO2P=439.6 mJ/m2, γZrO2d=251.3 mJ/m2, and γZrO22=548.7 mJ/m2, and the dipole-dipole interaction is larger than the dispersion force in the calculation. This can be understood based on a large difference of the electronegativity between Si and oxygen or between Zr and oxygen. The electronegativity is 1.90 for Si, 1.33 for Zr, and 3.44 for oxygen. Accordingly, it can be understood that electrons in the molecule are localized on oxygen, which is attributable to the generation of the dipole-dipole interaction.
Then, description is to be made to SiTe and SiSb as the phase change material. Constituent elements of them have substantially the same electronegativity (Ge: 2.01, Sb: 2.05, Te: 2.10, Si: 1.90). Accordingly, it can be assumed that the dipole-dipole interaction is small and only the dispersion force is concerned between the material and pure water. Based on the assumption described above and from (equation 3) to (equation 5), the following relation can be obtained.
As described above, when the angle of contact θiw is measured, γid, that is, γi can be calculated. Based on the calculated values, the interfacial energy γi-PC between the phase-change material and the interface layer material can be determined as:
[Equation 7]
γi-PC=γi+γPC−2√{square root over (γidγPCd)} (equation 7)
That is, the interfacial energy γi-PC between the phase-change material and the interface layer material can be calculated by measuring the angle of contact between the thin film of a single material and pure water. The gist of the above consideration is that the interfacial energy between the phase-change material and the interface layer material can be determined approximately by measuring the surface energy based on the angle of contact with pure water as an intermediary.
Then, the problems in the use of the third material system and means for the solution thereof are to be described. In the case of the third material system, since the materials are generally insulators, they cannot satisfy the requirement of the electric conductivity described above as they are. The means for the solution is shown below.
Based on the concept of controlling the electric conductivity by the selection of the film thickness, a metal nitride can also be used as the interface layer material of the invention. A fourth material system, in which the adhesiveness with Si and the phase-change material is taken into consideration in the same manner as described above, includes, for example, an Al—Ti—N system, an Al—Ta—N system, and an Al—Zr—N system.
As described above, the first to fourth material systems are shown as the interface layer material of the invention. When taking such material systems into consideration, it can be seen that suitable materials as the interface layer materials are those materials satisfying that: (1) a compound of at least about 1 atom layer is formed at the boundary between the interface layer material and the phase-change material layer, (2) the thickness of the compound is at such an extent as not hindering the crystallization of the phase-change material layer (specifically, the thickness of the compound is preferably ¼ or less to the thickness of the phase-change material layer, or 2 nm or less) and (3) the surface energy of the interface layer material and that of the phase-change material are close to each other (interfacial energy, 3 mJ/m2 or less).
While examples of binary system/ternary system materials are shown as the interface layer material, it is a well-known technique to control melting point, electric conductivity, adhesiveness, etc. to appropriate levels by changing the composition and adding a third or fourth element to such material systems, and the control may be conducted optionally.
Further, this example provides an effect particularly in the case of the structure as in
Then, description is to be made to a recording method of suppressing cross-erase as a second object of the invention.
Then, as the lateral refinement is proceeded, since the aspect ratio becomes greater, the size in the vertical direction is also decreased. Then, a gap between the gate polysilicon layers GP is decreased. In this structure, information is stored in the phase-change material layer situated on the side of the gate polysilicon film GP. Accordingly, the distance between the positions of the phase-change material layers storing different bits respectively is narrowed. Since information is rewritten by applying heat to the phase-change material layer, as the distance between the adjacent bits is decreased, cross erase is generated under the effect of heat upon writing to adjacent cells. This problem occurs in the same manner also in the structure shown in
Then, anisotropy of the thermal conductivity of the Si channel is considered. As is well-known, the thermal conductivity of a metal material is approximated well through modeling on free electron gas approximation, for example, by a Drude model. For Si used for the channel, since substantially all free electrons are moved along the electric field during writing, it is considered that such free electrons (or holes) transport a heat energy as a kinetic energy. In this case, anisotropy of the thermal conductivity is generated along the current flowing direction. For the structure in
Then, in this example, writing is conducted orderly from the upstream to the downstream of the flow of carriers. This can suppress cross erase to the upstream. In this case, while cross erase occurs at the downstream of the data inputted in correspondence to one write command, this causes no problem since a new data is to be written.
In the structure described above, a flow of writing data to the cell array 1015 is shown below. A data write command and a write data from the host controller 1000 are sent by way of the interface 1011 to the chip controller 1012. Upon receiving the write command, the chip controller 1012 instructs the device controller 1014 to conduct writing and transfers the write data. The device controller 1014 has a buffer and temporarily holds the write data transferred from the chip controller 1012. Further, the device controller 1014 generates a physical address to write a row of data temporarily held in the buffer from an instructed logic address by the instruction of the chip controller 1012, and executes current pulse control or the like for writing the data to the row of physical address in the cell array 1015. In this case, the device controller 1014 sets up the gate polysilicon layer GP situated at the upstream of carriers and writes the data held in the buffer. Then, it successively sets up the gate polysilicon layers GP toward the downstream and controls so as to write the write data held in the buffer.
As described above, the device controller 1014 allocates a plurality of bits arranged in the vertical direction (plurality of bits using a common phase-change material layer) to one row of data and conducts writing successively from the upstream where the carriers flow, thereby capable of suppressing cross erase. For the specific method of writing from the upstream where the carriers flow, various other methods may be considered in addition to the method described above. For example, a plurality of bits arranged in the vertical direction are adapted as a unit to be invalidated (erased) collectively and the device controller may conduct control so as to select a gate polysilicon layer GP at the upstream relative to the flow of carriers when a first write command is inputted after the invalidation and then select gate polysilicon layers GP at the downstream successively on every input of the write commands. In this case, while it may be a possibility of making the administration of the physical address complicate, the write time can be shortened since it is not necessary to repeat write operations for one command.
It will be understood easily that the signs are reversed relative to the direction of the current flow between a case where the carriers are free electrons and the case where the carriers are holes.
Then, cross erase in the lateral direction is to be investigated. In the phase-change memory of the vertical memory structure shown in
Then, a modulation code for suppressing the cross erase is to be described specifically. An example of a code that represents an 8-bit data by conversion to a 14-bit data is shown and this is referred to as 8-14 modulation.
In the constitution described above, a flow of recording data into the cell array 1015 by using a modulation method of this example is shown below. A data write command from the host controller 1000 is sent by way of an interface 1011 to a chip controller 1012. Based on the instruction from the chip controller 1012, the codec 1013 modulates the data to be written based on a modulation code rule.
The device controller 1014 generates a physical address to write a row of modulated data from an instructed logic address by the instruction of the chip controller 1012, and executes current pulse control or the like for writing the data to the row of the physical address in the cell array 1015. The data read out is executed by executing the sequence described above in the opposite direction.
Further, the modulation method in Example 4 can be realized by combination with the writing method in Example 3. In this case, since the cross erase in the vertical direction and the lateral direction can be suppressed, a semiconductor device of high reliability can be realized. Needless to say, the writing methods in Example 3 and Example 4 can be applied independently.
Number | Date | Country | Kind |
---|---|---|---|
2010-067204 | Mar 2010 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6927410 | Chen | Aug 2005 | B2 |
7375365 | Hsiung | May 2008 | B2 |
7463512 | Lung | Dec 2008 | B2 |
7678606 | Chen | Mar 2010 | B2 |
7851778 | Kang et al. | Dec 2010 | B2 |
7888155 | Chen | Feb 2011 | B2 |
8115239 | Lankhorst et al. | Feb 2012 | B2 |
8173987 | Lung | May 2012 | B2 |
8410468 | Zheng | Apr 2013 | B2 |
20060278900 | Chang et al. | Dec 2006 | A1 |
20070170413 | Matsui et al. | Jul 2007 | A1 |
20080149913 | Tanaka et al. | Jun 2008 | A1 |
20110049454 | Terao et al. | Mar 2011 | A1 |
Number | Date | Country |
---|---|---|
2007-531260 | Nov 2007 | JP |
2008-160004 | Jul 2008 | JP |
2009-117854 | May 2009 | JP |
WO 2007148405 | Dec 2007 | WO |
Entry |
---|
D. Adler et al. “Threshold Switching in Chalcogenide-Glass Thin Films”, J. Appl. Phys. 51(6), Jun. 1980, pp. 3289-3309. |
Number | Date | Country | |
---|---|---|---|
20110235408 A1 | Sep 2011 | US |