Embodiments described herein relate generally to a resistance-change memory.
Recently, a resistance-change memory has been attracting attention as a candidate to succeed a semiconductor memory.
The resistance-change memory is characterized in that the resistance of a resistance-change film is changed by the application of a voltage pulse to store data therein in a nonvolatile manner. The resistance-change memory is a two-terminal element and is simple in structure. The advantage of the resistance-change memory is that a higher capacity can be obtained more easily than heretofore by constructing a cross-point memory cell array.
In the cross-point type, a selective element needs to be connected in series to a resistance-change element in each memory cell. In a unipolar resistance-change memory in which voltage pulses in writing and erasing have the same polarity, a diode is needed. In a bipolar resistance-change memory in which voltage pulses in writing and erasing have opposite polarities, a so-called selector is needed to suppress a current in a voltage region lower than a threshold voltage in both polarities.
In a cross-point resistance-change memory, when a current in an on-state exponentially increases with an applied voltage, the current in an on-state is much more suppressed in a low voltage region than in a high-voltage region. This can be used to suppress a sneak current running through unselected memory cells without the installation of the selector.
However, even in such a resistance-change memory in which an on-current exponentially increases with an applied voltage, it is difficult to sufficiently suppress the sneak current running through unselected memory cells.
Hereinafter, a resistance-change memory according to embodiments is described with reference to the drawings. It is to be noted that components having the same function and configuration are given the same reference signs throughout the following explanation and are repeatedly described only when necessary.
In general, according to one embodiment, a resistance-change memory includes a memory cell and a control circuit. The memory cell comprises first and second electrodes, and a variable resistance layer disposed between the first electrode and the second electrode. The control circuit applies a voltage between the first electrode and the second electrode to perform writing, erasing, and reading. During the writing, the control circuit applies a first voltage pulse between the first electrode and the second electrode, and then applies a second voltage pulse different in polarity from the first voltage pulse after applying the first voltage pulse.
First, the concept of the embodiments is described.
The resistance-change memory according to the embodiments has a resistance-change element that changes in resistance. The resistances (e.g. two high resistances [off] and low resistances [on]) of the resistance-change element are programmed by a current or a voltage. The resistance-change memory stores data in accordance with the resistance of the resistance-change element.
As shown, when a positive-direction voltage is applied to the resistance-change element in an off-state, resistance decreases after the voltage exceeds a certain (Vset), and the resistance-change element makes the transition to an on-state.
Furthermore, when a negative-direction voltage is applied to the resistance-change element in the on-state, the resistance-change element again increases in resistance. The process of this resistance increase occurs step by step depending on the applied voltage. For example, when the negative-direction voltage is applied up to Vreset2, the resistance-change element does not completely return to the off-state, and remains in an intermediate state. The intermediate state is a state higher in resistance than the on-state.
Moreover, if the negative-direction voltage is applied to the resistance-change element in the intermediate state up to Vreset, the resistance-change element makes the transition to the off-state from the intermediate state. Here, when the positive-direction voltage is applied, the resistance-change element makes the transition to the on-state from the intermediate state at a voltage Vset2 lower than a voltage Vset at which the resistance-change element makes the transition to the on-state from the off-state. The intermediate state is higher in resistance than the on-state, and has a resistance less than or equal to the off-state.
In the resistance-change element having such characteristics, setting to the intermediate state instead of the on-state is defined as “write”, setting to the off-state is defined as “erasing”, and a read voltage is greater than or equal to Vset2 and less than Vset. Thus, it is possible to add a function substantially similar to that when a selector is installed in the resistance-change element as a memory cell.
A resistance-change memory according to the first embodiment is described. Here, a cross-point resistance-change memory is described as the resistance-change memory by way of example.
[1] Memory Array
As shown, the memory cell array is in a cross-point form. Word lines WL0, WL1, and WL2 extend in an X-direction, and are arranged at predetermined intervals in a Y-direction. Bit lines BL0, BL1, and BL2 extend in the Y-direction, and are arranged at predetermined intervals in the X-direction.
Memory cells MC(0-0), (0-1), . . . , (2-2) are arranged at the intersections of word lines WL0, WL1, and WL2 and bit lines BL0, BL1, and BL2. In this way, the resistance-change memory has a cross-point memory cell array structure. Later-described resistance-change elements are used for the memory cells.
Although the memory cell array in which the resistance-change elements are arranged between the word lines and the bit lines is shown here, a stack memory cell array structure in which the memory cell arrays are stacked may be used.
[2] Resistance-Change Element
As shown in
First, voltage pulse conditions that permit the transition between the three states are classified as follows. Here, the voltage pulse conditions mean the polarity, amplitude, and width of a voltage pulse.
a. Voltage Pulse Condition 1
This voltage pulse condition permits the transition to the on-state from the off-state or the intermediate state.
b. Voltage Pulse Condition 2
This voltage pulse condition permits the transition to the intermediate state from the on-state.
c. Voltage Pulse Condition 3
This voltage pulse condition permits the transition to the off-state from the on-state or the intermediate state.
d. Voltage Pulse Condition 4
This voltage pulse condition permits the transition to the on-state from the intermediate state.
The above-mentioned on-state, off-state, and intermediate state have the following relationship.
Generally speaking, as shown in
However, in some cases, the state transition of the resistance-change element is basically dependent on voltage or time. Therefore, at least one of the pulse amplitude and the pulse width of the third voltage pulse is greater than that of the second voltage pulse. Similarly, at least one of the pulse amplitude and the pulse width of the fourth voltage pulse is smaller than that of the first voltage pulse.
If the state transition of the resistance-change element is dependent on voltage rather than time, Voltage pulse conditions 1, 2, 3, 4, A, and B may be decided only by the voltage (amplitude and polarity).
For example, in case of some resistance-change elements, voltage and time required for the state transition has a relationship described in formula (1).
Voltage ∝1/log(time)+k formula (1)
In this case, it's desirable to use the voltage (amplitude and polarity) as the pulse conditions of the operation. That is, the pulse amplitude of the third voltage pulse is greater than that of the second voltage pulse. Similarly, the pulse amplitude of the fourth voltage pulse is smaller than that of the first voltage pulse.
In the same way, if the state transition of the resistance-change element is dependent on time rather than voltage, it's desirable to use the time (pulse width) as pulse conditions of the operation.
[3] Writing, Erasing, and Reading
Write, erase, and read operations in the resistance-change element according to the embodiment are described.
(1) Writing
More specifically, as shown in
(2) Erasing
(3a) Reading 1
As shown in
When a resistance-change element targeted for reading is in the intermediate state (when the resistance-change element is an element in which data has been written), the resistance-change element instantaneously makes the transition to the on-state from the intermediate state if the positive voltage is applied thereto, and a current in the on-state is read. After the application of the positive voltage is finished, the resistance-change element returns to the intermediate state from the on-state.
When the resistance-change element targeted for reading is in the off-state (when the resistance-change element is an element in which data has been erased), the resistance-change element maintains the off-state, and a current in the off-state is read.
(3b) Reading 2
As shown in
When a resistance-change element targeted for reading is in the intermediate state (when the resistance-change element is an element in which data has been written), the resistance-change element instantaneously makes the transition to the on-state from the intermediate state if the positive voltage is applied thereto, and a current in the on-state is read. Subsequently, the negative voltage is applied, and the resistance-change element makes the transition to the intermediate state from the on-state.
When the resistance-change element targeted for reading is in the off-state (when the resistance-change element is an element in which data has been erased), the resistance-change element maintains the off-state, and a current in the off-state is read. Subsequently, the negative voltage is applied, but the resistance-change element in the off-state remains in the off-state.
The voltages are only used as the conditions of the operations in the above explanation. Therefore, these operations are used for the resistance-change element which has the state transition depending on voltage rather than time or depending on both voltage and time.
[4] Advantages
According to the first embodiment, the resistance-change elements separate into the on-state and the off-state that have a great current difference in reading. However, except for reading, the element in which data has been written and the element in which data has been erased are both in the intermediate state or the off-state, and a suppressed current runs through the resistance-change elements.
Since the resistance-change element is always kept in a state higher in resistance than the on-state except for reading, a sneak current running through unselected memory cells can be suppressed. That is, all the resistance-change elements but the selected resistance-change element targeted for reading are in a current-suppressed condition, and have a function substantially equivalent to that of a memory cell equipped with a selector.
Furthermore, according to the first embodiment, it is possible to provide a bipolar resistance-change memory which substantially enables a selector function without the installation of a selector in each memory cell and which can avoid an increased operating voltage, a complicated process, and increased costs.
A resistance-change memory according to the second embodiment is described. In the case described in the second embodiment, an ion-conducting resistance-change memory is provided as a memory cell. It is to be noted that the structure of a memory cell array is similar to that according to the first embodiment and is therefore not described.
[1] Resistance-Change Element
For example, an ion-conducting resistance-change memory is used as a resistance-change element. The ion-conducting resistance-change memory is described below in detail.
A resistance-change element MC comprises a first electrode 1a and a second electrode 1b, and a variable resistance layer 1c disposed between the first electrode 1a and the second electrode 1b. The variable resistance layer 1c has a filament 3 formed between the first electrode 1a and the second electrode 1b.
Here, the shape, for example, the length and thickness of the filament 3 in an on-state is at least greater than the shape, for example, the length and thickness of a filament in an off-state.
A control circuit 2 applies a voltage between the first electrode 1a and the second electrode 1b to perform writing, erasing, or reading.
A high-resistance material 1d comprises, for example, amorphous silicon, polycrystalline silicon, or a metal sulfide (Cu2S, AgS). The high-resistance material 1d may comprise an insulator.
One of the first electrode 1a and the second electrode 1b functions as a lower electrode, and the other functions as an upper electrode, for example.
The lower electrode is an electrode that serves as a foundation for forming the variable resistance layer 1c. The upper electrode is an electrode that is formed after the variable resistance layer 1c is formed.
As shown, the filament 3 may extend from the first electrode 1a, or may extend from the second electrode 1b.
A specific example of the ion-conducting resistance-change element is described below.
In the resistance-change element MC shown by way of example in
The current-voltage characteristics when the resistance-change element is in the on-state, the off-state, and the intermediate state are shown. The example shown in
As shown in
[2] Writing, Erasing, and Reading
Write, erase, and read operations when the resistance-change elements having the characteristics shown in
(1) Writing
As shown, a voltage pulse P1 is applied to a selected resistance-change element, and then a voltage pulse P2 is applied. The voltage (pulse amplitude) of voltage pulse P1 is, for example, 8 V, and the voltage of voltage pulse P2 is, for example, −2 V.
When voltage pulse P1 is applied, the resistance-change element makes the transition to the on-state from the off-state. Further, when voltage pulse P2 is applied, the resistance-change element makes the transition to the intermediate state from the on-state.
As shown in
At the same time, a voltage pulse of 3 V is applied to unselected word lines WL1 and WL0, and a voltage pulse of 5 V is applied to unselected bit lines BL1 and BL2. As a result, a voltage pulse of +3 V is applied to unselected resistance-change elements MC(1-2), MC(2-2), MC(0-1), and MC(0-0), respectively. A voltage pulse of −2 V is applied to unselected resistance-change elements MC(1-1), MC(2-1), MC(1-0), and MC(2-0), respectively. In each case, the states of the unselected resistance-change elements do not change.
Furthermore, as shown in
At the same time, a voltage pulse of 1 V is applied to unselected word lines WL1 and WL0 and unselected bit lines BL1 and BL2. As a result, a voltage pulse of −1 V is applied to unselected resistance-change elements MC(1-2), MC(2-2), MC(0-1), and MC(0-0), respectively. A voltage pulse of 0 V is applied to unselected resistance-change elements MC(1-1), MC(2-1), MC(1-0), and MC(2-0), respectively. In each case, the states of the unselected resistance-change elements do not change.
The writing described above allows the selected resistance-change element alone to make the transition to the intermediate state.
(2) Erasing
As shown, a voltage pulse P3 is applied to a selected resistance-change element. When voltage pulse P3 is applied, the resistance-change element makes the transition to the off-state from the intermediate state. The voltage (pulse amplitude) of voltage pulse P3 is, for example, −5 V. The product of the pulse amplitude and pulse width of voltage pulse P3 is greater than the product of the pulse amplitude and pulse width of voltage pulse P2.
As shown, a voltage pulse of 0 V is applied to a selected word line WL2, and a voltage pulse of 5 V is applied to a selected bit line BL0. As a result, a voltage pulse P3 of −5 V is applied to selected resistance-change element MC(0-2), and resistance-change element MC(0-2) makes the transition to the off-state.
At the same time, a voltage pulse of 3.0 V is applied to unselected word lines WL1 and WL0, and a voltage pulse of 2.0 V is applied to unselected bit lines BL1 and BL2. As a result, a voltage pulse of −2.0 V is applied to unselected resistance-change elements MC(1-2), MC(2-2), MC(0-1), and MC(0-0), respectively. A voltage pulse of 1.0 V is applied to unselected resistance-change elements MC(l-1), MC(2-1), MC(l-0), and MC(2-0), respectively. In each case, the states of the unselected resistance-change elements do not change.
The erasing described above allows the selected resistance-change element alone to make the transition to the off-state.
(3) Reading
As shown, a voltage pulse P4 is applied to a selected resistance-change element, and then a voltage pulse P2 is applied. The voltage (pulse amplitude) of voltage pulse P4 is, for example, +4 V, and the voltage of voltage pulse P2 is, for example, −2 V. The product of the pulse amplitude and pulse width of voltage pulse P4 is smaller than the product of the pulse amplitude and pulse width of voltage pulse Pl. Voltage pulse P4 is greater than voltage pulse P1 in at least one of pulse amplitude and pulse width.
When voltage pulse P4 is applied, the resistance-change element makes the transition to the on-state from the intermediate state. Further, when voltage pulse P2 is applied, the resistance-change element makes the transition to the intermediate state from the on-state.
As shown in
At the same time, a voltage pulse of 2 V is applied to unselected word lines WL1 and WL0 and unselected bit lines BL1 and BL2. As a result, a voltage pulse of +2 V is applied to unselected resistance-change elements MC(1-2), MC(2-2), MC(0-1), and MC(0-0), respectively. A voltage pulse of 0 V is applied to unselected resistance-change elements MC(1-1), MC(2-1), MC(1-0), and MC(2-0), respectively. In each case, the states of the unselected resistance-change elements do not change.
Furthermore, as shown in
At the same time, a voltage pulse of 1 V is applied to unselected word lines WL1 and WL0 and unselected bit lines BL1 and BL2. As a result, a voltage pulse of −1 V is applied to unselected resistance-change elements MC(1-2), MC(2-2), MC(0-1), and MC(0-0), respectively. A voltage pulse of 0 V is applied to unselected resistance-change elements MC(1-1), MC(2-1), MC(1-0), and MC(2-0), respectively. In each case, the states of the unselected resistance-change elements do not change.
[3] Advantages
The cross-point memory cell array has the following general problem.
As shown in
Since the sneak current always runs through the memory cell in the reverse direction, a selector that suppresses the reverse current has heretofore been installed in the resistance-change element in each memory cell to solve this problem. According to the present embodiment, the reverse current is suppressed without the installation of the selector as described above, so that this problem can be avoided.
In the present embodiment, the intermediate state of the resistance-change element is higher in resistance than the on-state, and the transition from this intermediate state to the on-state can be made by a voltage lower than a voltage necessary for the transition to the on-state from the off-state. By using, as a read voltage, a voltage which is less than the voltage for the transition to the on-state from the off-state and which is greater than or equal to the voltage for the transition to the on-state from the intermediate state, currents in low-voltage regions in the reverse and forward directions are suppressed without decreasing the on/off ratio. Accordingly, the resistance-change element can obtain substantially the same characteristics as a memory cell equipped with a selector.
Moreover, whether a selected resistance-change element is in the intermediate state or off-state can be determined by a current in the on-state or off-state. Even when the resistance-change element makes the transition to the on-state from the intermediate state in a nonvolatile manner under voltage pulse condition A, the resistance-change element can be returned to the intermediate state by successively applying voltage pulse condition B, and information before reading is not lost.
Although each of voltage pulses P1, P2, P3, and P4 comprises a single voltage pulse in the present embodiment described, the present embodiment can be implemented by various voltage waveforms as long as voltage pulses P1, P2, P3, and P4 satisfy above-mentioned voltage pulse conditions 1, B, 3, and A. For example, as shown in
As described above, according to the embodiments, it is possible to provide a resistance-change memory which can suppress the sneak current running through the unselected memory cells without the installation of a selector in the memory cell.
Moreover, a function substantially similar to that when the resistance-change element and a selector are connected in series can be obtained without the installation of a selector in each memory cell. Therefore, it is possible to avoid problems such as an increased operating voltage, a complicated process, and increased costs that are caused when a selector is actually connected.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2011-064933 | Mar 2011 | JP | national |
This application is a division of and claims the benefit of priority under 35 U.S.C. §120 from U.S. Ser. No. 14/621,071 filed Feb. 12, 2015, which is a division of U.S. Ser. No. 14/016,614 filed Sep. 3, 2013 (now U.S. Pat. No. 9,053,786 issued Jun. 9, 2015), which is a continuation application of PCT Application No. PCT/JP2011/071769 filed Sep. 16, 2011 and claims the benefit of priority from Japanese Patent Application No. 2011-064933 filed Mar. 23, 2011, the entire contents of each of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 14621071 | Feb 2015 | US |
Child | 15425388 | US | |
Parent | 14016614 | Sep 2013 | US |
Child | 14621071 | US |
Number | Date | Country | |
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Parent | PCT/JP2011/071769 | Sep 2011 | US |
Child | 14016614 | US |