EP3984072A1 - Method for determining a production parameter for a resistive random-access memory cell - Google Patents

Abstract

The invention relates to a method for determining at least one value (t_{TE_opt}, t_{OX_opt}, X_opt) of at least one production parameter (t_TE, t_OX, x) for a resistive memory cell, the resistive memory cell comprising a thin-film stack, said method comprising the following steps: - providing (S1) a plurality of reference memory cells (10) corresponding to a plurality of technological variants of the thin-film stack; - measuring (S2) an initial resistance value (R_i) for each reference memory cell; - determining (S3, S4), for each reference memory cell (10), a value of a programming parameter chosen from among the resistance in a high-resistance state (R_HRS) and the programming window; - establishing (S5) a relationship between the programming parameter and the initial resistance (R_i) based on the initial resistance values (R_i) and the values of the programming parameter; and - determining said at least one value (t_{TE_opt}, t_{OX_opt}, X_opt) of said at least one production parameter (t_TE, t_OX, x) for which the programming parameter is greater than or equal to a target value (R_{HRS_tg}), based on said relationship between the programming parameter and the initial resistance (R_i) and on at least one dependency relationship between the initial resistance (R_i) and said at least one production parameter (t_TE, t_OX, x).

Description

DESCRIPTION

TITLE: PROCESS FOR DETERMINING A MANUFACTURING PARAMETER OF A RESISTIVE RAM CELL

TECHNICAL AREA

The present invention relates to the field of resistive random access memories RRAM (for "Resistive Random Access Memories" in English). The invention relates to a method for determining a value of one or more manufacturing parameters of a resistive memory cell, in order to improve the programming window of the resistive memory cell. The invention also relates to a method of manufacturing a resistive memory cell having a high programming window.

STATE OF THE ART

[0002] Resistive memories, in particular resistive oxide memories (OxRAM, for "Oxide-based Random Access Memories"), are non-volatile memories intended to replace flash type memories. In addition to a high integration density, they have a high operating speed, great endurance and good compatibility with the manufacturing processes currently used in the microelectric industry, in particular with the end of line process (BEOL , for “Back-End Of Line” in English) of CMOS technology.

OxRAM resistive memories include a multitude of memory cells, also called memory points. Each OxRAM memory cell consists of an MlM (Metal-lsolant-Metal) capacitor comprising an active material of variable electrical resistance, in general a transition metal oxide (eg Hf02, Ta205, Ti02 ...), arranged between two metal electrodes. The memory cell reversibly switches between two resistance states, which correspond to logical values "0" and "1" used to encode an information bit. In some cases, more than two resistance states can be generated, allowing multiple bits of information to be stored in a single memory cell.

The information is written in the memory cell by switching it from a highly resistive state (or "H RS", for "High Resistance State" in English), called also “OFF” state, in a weakly resistive state (“LRS”, for “Low Resistance State”), or “ON” state. Conversely, to erase the information from the memory cell, the latter is switched from the weakly resistive state (“OFF”) to the strongly resistive state (“ON”).

[0005] The change in resistance of the memory cell is governed by the formation and breakage of a conductive filament of nanometric section between the two electrodes.

[0006] Immediately after manufacture, the resistive memory cell is in a virgin state characterized by a very high (so-called initial) resistance, much greater than the resistance of the cell when it is in the highly resistive state. The oxide layer is indeed insulating in its initial state. In order for the memory cell to be used, it is necessary to perform a so-called "forming" step. This step consists of a partially reversible breakdown of the oxide in order to generate the conductive filament for the first time (and therefore place the memory cell in the low resistive state). After this breakdown, the initially insulating oxide layer becomes active and the cell can switch between the low resistive state and the high resistive state by erase and write operations.

[0007] The forming step is accomplished by applying between the two electrodes of the memory cell a voltage (called “forming”) of value much higher than the nominal operating voltage of the memory cell (used during the cycles of write-erase following), for example a voltage of the order of 2.5 V for a nominal voltage of the order of 1.5 V. To obtain a forming voltage compatible with the supply voltage of the circuit to which belongs memory cell, one solution consists in adjusting certain manufacturing parameters of the memory cell. For example, the forming voltage can be increased by increasing the thickness of the oxide layer or by decreasing the thickness of the electrodes.

[0008] A drawback of OxRAM resistive memories is the great variability of the electrical resistance of a memory cell in the highly resistive state. This variability is observed not only over the course of the write-erase cycles on the same cell, but also from cell to cell.

This problem of variability of electrical resistance is a real brake on industrialization, because it induces a reduction in the programming window, defined as the ratio between the resistance in the highly resistive state and the resistance in the weakly resistive state. There is consequently a risk of losing the information stored in the memory cell. This concern remains despite numerous efforts made in the fields of programming OxRAM resistive memories. Indeed, the shape, the duration and the maximum amplitude of the programming pulses can be chosen in order to maximize the programming window over the highest possible number of write-erase cycles.

[0010] Furthermore, studies have been carried out recently in order to replace the oxides of the transition metal with less expensive and more easily industrializable materials: the oxides of silicon. Document US2016 / 27641 1 describes a matrix of memory cells each comprising a layer of resistive material based on substoichiometric silicon oxide (SiOx, with x between 1 and 2) arranged between two electrodes, for example made of titanium.

SUMMARY OF THE INVENTION

[001 1] The object of the invention is to provide an additional means of optimizing the programming window of a resistive memory cell, for example of a cell based on silicon oxide.

According to a first aspect of the invention, one tends towards this objective by providing a method for determining at least one value of at least one manufacturing parameter of a resistive memory cell, the resistive memory cell comprising a stack of thin films, said method comprising the following steps:

provide several reference memory cells corresponding to several technological variants of the thin film stack; measuring for each reference memory cell an initial resistance value;

determining for each reference memory cell a value of a programming parameter chosen from the resistance in a highly resistive state and the programming window;

establishing a relationship between the programming parameter and the initial resistance from the initial resistance values and the values of the programming parameter;

determining said at least one value of said at least one manufacturing parameter for which the programming parameter is greater or equal to a target value, from said relationship between the programming parameter and the initial resistance and from at least one dependency relationship between the initial resistance and said at least one manufacturing parameter.

The determination method according to the first aspect of the invention makes it possible to demonstrate the relationship which exists between the initial resistance of the memory cell and the resistance of the memory cell in the highly resistive state or the programming window. . Knowing this relationship and the dependence between initial strength and manufacturing parameter (s), it is possible to determine at least one optimum value of one or more manufacturing parameters of the memory cell.

[0014] The programming window of a resistive memory cell can therefore now be optimized by adjusting one or more manufacturing parameters of the memory cell, in addition to the programming conditions or the choice of materials.

The manufacturing parameters are therefore no longer adjusted as a function of a target value of the forming voltage, but as a function of a target value of the resistance in the highly resistive state or (directly) a target value of the programming window.

Preferably, the determination method comprises the following steps:

determining, from said relationship between the programming parameter and the initial resistance, at least one value of the initial resistance for which the programming parameter is greater than or equal to the target value; and

determining said at least one value of said at least one manufacturing parameter from said at least one value of the initial resistance.

[0017] In a first embodiment of the determination method, the programming parameter is the resistance in the highly resistive state and the step of determining the values of the programming parameter comprises the following operations:

program the reference memory cells in the high resistive state;

measuring for each reference memory cell a resistance value in the highly resistive state. The resistance in the highly resistive state is preferably a second degree polynomial function of the logarithm of the initial resistance.

[0019] In a second embodiment of the determination method, the programming parameter is the programming window and the step of determining the values of the programming parameter comprises the following operations:

programming the reference memory cells in a low resistive state;

measuring for each reference memory cell a resistance value in the low resistive state;

program the reference memory cells in the high resistive state;

measuring for each reference memory cell a resistance value in the high resistive state; and

calculate for each reference memory cell a value of the programming window from the measured values of resistance in the low resistive state and resistance in the high resistive state.

[0020] Preferably, the stack of thin films includes a first electrode disposed on a substrate, an oxide layer disposed on the first electrode and a second electrode disposed on the oxide layer.

In a preferred embodiment of the determination method, said at least one manufacturing parameter is chosen from the thickness of the second electrode, the thickness of the oxide layer and the proportion of oxygen in the oxide layer.

[0022] A second aspect of the invention relates to a method of manufacturing a resistive memory cell. This manufacturing process includes the following steps:

determining a value of at least one manufacturing parameter, following a determination method according to the first aspect of the invention;

forming on a substrate a stack comprising successively a first electrode, an oxide layer and a second electrode, by applying the value of said at least one manufacturing parameter. [0023] The oxide layer is preferably formed from a substoichiometric silicon oxide (SiOx) or from a porous silicon oxide. In a substoichiometric silicon oxide, the stoichiometric coefficient (x) of oxygen (ie the proportion of oxygen) is strictly less than 2.

[0024] The first electrode is for example made of titanium nitride and the second electrode is for example made of titanium.

[0025] The invention also aims to manufacture a resistive memory cell of OxRAM type having a high programming window, the memory cell comprising a layer of silicon oxide.

[0026] According to a third aspect of the invention, one tends towards this objective by providing a manufacturing process comprising the following steps:

determining values of manufacturing parameters allowing the resistive memory cell to have an initial resistance of between 10 ⁷ W and 3 × 10 ⁹ W, preferably between 3 × 10 ⁷ W and 10 ⁹ W;

forming on a substrate a stack comprising successively a first electrode, the layer of silicon oxide and a second electrode, by applying said values of manufacturing parameters.

[0027] The manufacturing process according to the third aspect of the invention may also have one or more of the characteristics below, considered individually or in any technically possible combination:

the manufacturing parameters are the thickness of the second electrode, the thickness of the oxide layer and the proportion of oxygen in the oxide layer;

the silicon oxide is porous and the proportion of oxygen in the silicon oxide layer is between 1, 6 and 2, preferably between 1, 8 and 1, 9;

the silicon oxide is porous and the thickness of the silicon oxide layer is between 4 nm and 7 nm;

the silicon oxide is porous and the thickness of the second electrode is between 3 nm and 7 nm;

the silicon oxide is non-porous and the proportion of oxygen in the silicon oxide layer is between 1 and 1, 6, preferably between 1, 2 and 1, 4; the silicon oxide is non-porous and the thickness of the silicon oxide layer is between 3 nm and 4 nm;

the silicon oxide is non-porous and the thickness of the second electrode is between 4 nm and 6 nm;

the silicon oxide layer is formed by sputtering; the first and second electrodes are formed by sputtering; and

the first electrode is titanium nitride and the second electrode is titanium.

BRIEF DESCRIPTION OF THE FIGURES

Other features and advantages of the invention will emerge clearly from the description which is given below, by way of indication and in no way limiting, with reference to the appended figures, among which:

FIG. 1 diagrammatically represents a first embodiment of a method for determining a manufacturing parameter value of a resistive memory cell;

FIG. 2 illustrates different deposition regimes during the sputtering of a source of silicon in the presence of oxygen;

FIG. 3 shows, for a plurality of TiN / SiOx / Ti reference memory cells, the resistance in the highly resistive state as a function of the initial resistance;

Figure 4 shows, for the same reference memory cells, the resistance in the highly resistive state as a function of the forming voltage.

For greater clarity, identical or similar elements are marked with identical reference signs in all of the figures.

DETAILED DESCRIPTION

[0030] [Fig 1]: Figure 1 shows steps S1 to S7 of a method for determining a value of at least one manufacturing parameter of a resistive memory cell, according to a first mode of implementation of the 'invention. When the resistive memory cell is fabricated following this parameter value, the memory cell programming window reaches a maximum value or a value close to the maximum value. The programming window PW (also called “memory window”) of a resistive memory cell is equal to the resistance of the cell in the highly resistive state (or “H RS”, for “High Resistance State”), denoted hereafter RHRS, divided by the resistance of the same cell in the weakly resistive state (or “LRS”, for “Low Resistance State”), denoted hereafter RLRS (PW = RHRS / RLRS).

The resistive memory cell whose programming window is sought to be improved comprises a stack of thin layers (<100 nm thick each). Conventionally, this stack is formed on a substrate, for example made of silicon, and comprises:

a first electrode 11 disposed on the substrate and called hereinafter "lower electrode";

a layer of variable electrical resistance material 12, also called "resistive material", arranged on the first electrode 1 1; and a second electrode 13 disposed on the layer of resistive material and referred to hereinafter as “upper electrode”.

[0032] The resistive memory cell is preferably an oxide-based random access memory cell, commonly known as "OxRAM" (for "Oxide-based Random Access Memory" in English). The resistive material is then an oxide, for example a transition metal oxide (eg HfC> 2, Ta20s, PO2, etc.) or a silicon oxide. The electrodes can be formed from doped silicon, a silicide, a metal (eg titanium, tantalum, tungsten, etc.) or a material of a metallic nature, such as titanium nitride (TiN) or tantalum nitride (TaN).

The first step S1 of the method consists in providing a number n of reference memory cells 10, where n is a natural number greater than or equal to 2, preferably greater than or equal to 20. Plus the number n of memory cells of Reference 10 is important, the more precise the determination method will be. In order not to unnecessarily burden FIG. 1, only three reference memory cells 10 have been shown. The reference memory cells 10 and the resistive memory cell to be manufactured comprise the same type of stack of thin layers. The stacks are said to be of the same type when the number of active layers is identical and the materials used are of the same type. For example, the stack of reference memory cells 10 (and of the resistive memory cell to be manufactured) comprises a lower electrode 11 of titanium nitride, a layer of resistive material 12 of silicon oxide (SiOx) and an upper electrode 13 of titanium (stack of TiN / SiOx / Ti type).

The reference memory cells 10 differ in the values of their manufacturing parameters. Among these manufacturing parameters, there may be mentioned by way of example the thickness tox of the oxide layer 12, the thickness ÎTE of the upper electrode 13 and the stoichiometric coefficient x of the oxide layer 12 (corresponding to in a proportion of oxygen relative to the other elements forming the resistive material). The reference memory cells 10 can have different values of the same manufacturing parameter (for example the thickness ÎTE of the upper electrode) or different values of several manufacturing parameters. Each reference memory cell 10 is manufactured according to a set of manufacturing parameters and at least one manufacturing parameter of each set differs from the other sets of parameters. In this sense, the reference memory cells 10 represent technological variants of the same stack of thin layers.

In the case of a TiN / SiOx / Ti type stack, the manufacturing parameters which vary between the n reference memory cells 10 are preferably the tox thickness of the SiOx layer 12, the ÎTE thickness of the upper titanium electrode 13 and the proportion of oxygen x of the SiOx (the thickness of the lower electrode has no influence on the initial resistance, its thickness is for example of the order of 40 nm) . For example, the tox thickness of the SiOx layer 12 varies between 1 nm and 20 nm, the ÎTE thickness of the upper titanium electrode 13 varies between 1 nm and 20 nm and the proportion of oxygen x of the SiOx varies between 1 and 2. The silicon oxide can therefore be substoichiometric (x <2) or be silicon dioxide (x = 2). The silicon dioxide is preferably porous, while the substoichiometric silicon oxide can be porous or non-porous (i.e. devoid of pores).

In the case of a metal / "high-k" / metal dielectric material stack, where the metal of the upper electrode (eg Hf, Ti, Ta ...) plays the role of the oxygen scout for the "high-k" dielectric material (ie of high dielectric permittivity, eg Hf02, T1O2, Ta205 ...), the thickness of the layer of "high-k" dielectric material can vary between 1 nm and 20 nm and the thickness of the upper electrode (oxygen scavenger layer) can vary between 1 nm and 20 nm. In in the case of a “high-k” dielectric material of the “MOx” metal oxide type, where M is a transition metal (eg Hf, Ti, Ta, etc.), the proportion of oxygen x can also vary between 1 and a value corresponding to the stoichiometric oxide (x = 2 for HfC> 2 or T1O2, x = 2.5 for Ta2C> 5 ...).

[0037] The initial resistance Ri of each reference memory cell 10 is then measured during a step S2. The initial resistance is the electrical resistance obtained after manufacturing the memory cell, before the conductive filament is formed for the first time (in other words, before the "forming" step). The initial resistance Ri can be measured by applying a measurement voltage Ui (for example 100 mV) between the electrodes 11 and 13 of the memory cell 10, by measuring the current h of the cell (through the oxide layer 12 ) subjected to this voltage Ui then by calculating the ratio of the measurement voltage Ui to the measured current h (Ri = U1 / I1).

[0038] The reference memory cells 10 are then programmed in the highly resistive state ("HRS") during a step S3. A first so-called “forming” voltage (for example of the order of 3 V) is applied between the electrodes of the memory cells 10 to activate the resistive material and place the memory cells 10 in the weakly resistive state (“LRS”). , then a second so-called erase voltage, of lower absolute value than the first voltage is applied to switch the reference memory cells 10 from the weakly resistive state to the strongly resistive state (the erase voltage is generally negative , for example between -1 V and -2 V).

[0039] Then, the resistance in the highly resistive state RHRS is measured for each reference memory cell 10 during a step S4. Analogously to the initial resistance Ri, the resistance RHRS can be measured by applying a measurement voltage U2 (for example 100 mV) between the electrodes of the memory cell 10 (in the highly resistive state), by measuring the current I2 of the cell subjected to this voltage U2 then by calculating the ratio of the measurement voltage U2 to the current I2 measured (RHRS = U2 / I2).

In step S5, an RHRS relationship (RÎ) between the resistance in the highly resistive state RHRS and the initial resistance Ri is established from the resistance values Ri and the resistance values RHRS measured respectively during the steps S2 and S4. For example, the resistance values RHRS and Ri of the memory cells of reference 10 can be plotted on a graph. Each point of the graph corresponds to a reference memory cell 10 and therefore to a technological variant of the stack (ie a combination of technological parameters). The points of the graph are then described, during an operation called “fit”, by a curve or an equation of the type RHRS = f (Ri). The relation RHRS (RÎ) can therefore take the form of a curve or of an equation. The relation between the resistance in the strongly resistive state RHRS and the initial resistance Ri is preferably written in the form of a second degree polynomial, with as variable the logarithm of the initial resistance Ri.

[0041 j Step S6 consists in determining, using the relationship RHRS (RÎ), at least one value Ri_ _op t of the initial resistance Ri for which the resistance in the highly resistive state RHRS is greater than or equal to a predetermined RHRSJ _Q target value. This RHRSJ _Q target value can be set according to a programming window target value (preferably the maximum) or can be equal to a percentage of the maximum of the resistance in the high resistive state RHRS (e.g. 90% maximum resistance RHRS). The maximum of the resistance RHRS can be deduced from the relation RHRS (RII) established in step S5.

In this first embodiment of the method, the resistance in the weakly resistive state RLRS of the reference memory cells 10 is assumed to be constant (and therefore independent of the technological parameters). In fact, the RLRS resistance of the OXRAM cells programmed in the low resistive state is controlled by the programming current in the low resistive state. For example, for a TiN / SiOx / Ti type stack, the resistor RLRS is equal to approximately 10 ⁴ W when the programming current is approximately equal to 100 mA. A maximum of the resistance in the highly resistive state RHRS then corresponds to a maximum of the programming window.

A value, several distinct values or a (continuous) range of values of the initial resistance Ri can thus be obtained at the end of step S6, depending on the target value chosen or the resistance values RHRS taken into consideration (greater than the target value RHRsjg and / or equal to the target value RHRsjg). All these values can be qualified as “optimal” or “optimized” insofar as they make it possible to approach or even reach a maximum of the programming window. Finally, in step S7, at least one optimum value tTE_opt / tox_opt / Xopt of one or more manufacturing parameters is determined from the optimum value Ri_ _0p t (or optimum values) of initial resistance. These manufacturing parameters are not necessarily the same as those which differentiate the reference memory cells 10. They are preferably chosen from the thickness tox of the oxide layer 12, the thickness ÎTE of the upper electrode 13 and the proportion of oxygen x in the oxide layer 12.

In a preferred embodiment of step S7, the values of all the manufacturing parameters having an influence on the initial resistance Ri are determined from the optimum value Ri_ _0p t of initial resistance. In an alternative embodiment, values of only part of these manufacturing parameters are determined from the optimum value Ri_ _0p t of initial resistance. The values of the other manufacturing parameters (including those having no influence on the initial resistance, for example the thickness ÎBE of the lower electrode 1 1, the role of which is to ensure good electrical contact) can be determined in another way. They can in particular be imposed by integration constraints.

The optimum value of a manufacturing parameter can be determined from an optimum value Ri_ _o t of initial resistance knowing the dependence of this parameter on the initial resistance Ri. For example, the initial resistance Ri of a resistive memory cell increases with the thickness tox of the oxide layer 12 and with the proportion of oxygen x. On the other hand, it decreases when the thickness ÎTE of the upper electrode 13 increases (up to a certain threshold).

[0047] An experimental design can be implemented in order to establish relationships of dependence between the initial strength Ri and the various manufacturing parameters. This experimental design can in particular consist in varying the three aforementioned manufacturing parameters (thickness tox of the oxide layer 12, thickness ÎTE of the upper electrode 13 and proportion of oxygen x in the oxide layer 12), preferably by crossing all the parameter values, and measuring the initial resistance corresponding to each set of values.

In the case of the TiN / SiOx / Ti stack, the following relationships were obtained by fixing two parameters then by varying the last parameter (with Ri in W, x without unit, tox and ÎTE in nm): [0049] [Math 1]

log (Ri) = 12.6. x— 16.6

[0050] with tox = ÎTE = 5 nm.

Thus, the Math 1 equation above expresses the variation of the initial resistance Ri as a function of the stoichiometric coefficient x of oxygen and where the thicknesses tox of the oxide layer 12 and ÎTE of the upper electrode 13 were set at 5 nm.

[0052] [Math 2]

R _t = 4.10 ^-6 x exp (5.4099. T _ox )

With ÎTE = 5 nm and x = 1, 8.

Thus, the Math 2 equation above expresses the variation of the initial resistance Ri as a function of the thickness tox of the oxide layer 12 and where the stoichiometric coefficient x of the oxygen has been set at 1 , 8 and the thickness ÎTE of the upper electrode 13 was set at 5 nm.

[0055] [Math 3]

Ri = 9. 10 ⁹ X exp (- 0.97. T _TE )

[0056] with tox = 5 nm and x = 1, 9.

Thus, the Math equation 3 above expresses the variation of the initial resistance Ri as a function of the thickness ÎTE of the upper electrode 13 and where the tox thickness of the oxide layer 12 has been fixed. at 5 nm and where the stoichiometric x coefficient of oxygen has been set at 1.9.

[0058] The above equations were obtained from experimental values and are dependent on the deposition equipment used.

When there are several optimum values Ri_ _0pt of the initial resistance, several optimum values of the manufacturing parameter (s) can be obtained.

In a second embodiment of the method, not shown in the figures, it is assumed that the resistance in the low resistive state RLRS of the reference memory cells 10 varies. The method then comprises, in addition to the steps S1 -S4 described above, a step of programming the reference memory cells 10 in the weakly resistive state, a step of measuring the resistance RLRS of the reference memory cells 1 0 in the weakly resistive state and a step of calculating the programming windows of the reference memory cells 1 0 from the measured values of the resistors RLRS and RHRS. The resistance RLRS of the reference memory cells 10 in the weakly resistive state is advantageously measured before the step S3 of programming the reference memory cells 10 in the strongly resistive state, after the forming step (which therefore constitutes l (step of programming the reference memory cells 10 in the weakly resistive state).

[0061] Instead of determining an RHRS relationship (RII) between the resistance in the highly resistive state RHRS and the initial resistance Ri, a relationship between the programming window and the initial resistance is determined in step S5. A target value of the programming window is then considered in step S6 (instead of a target value of the resistance in the high resistive state RHRS).

An example of implementation of the determination method according to the invention will now be described.

The resistive memory cell whose programming window is sought to be optimized as well as the reference memory cells 10 provided for this purpose comprise the stack of thin TiN / SiOx / Ti films described above.

[0064] The silicon oxide is in this example porous and was obtained by reactive sputtering in a vacuum deposition chamber. The deposition chamber is equipped with a silicon target and has two gas inlets, one for oxygen (O2), the other for an inert gas such as argon. The sputtering reactor includes a direct voltage (DC) generator and a magnetron. The bias of the source supplied by the DC generator is advantageously pulsed. The parameters having an influence on the proportion of oxygen x of the SiOx are the power applied by the DC generator, the working pressure, the flows of the neutral gas and of the oxygen, the frequency, the TON / TREV ratio of the duration of the deposition phases (generator "ON" state) over the duration of the electrostatic discharge phases (generator "OFF" state) and the duty cycle of the DC generator pulses (equal to TON / (TREV + TON)).

[0065] [Fig 2]: Figure 2 shows the effect of the bias voltage applied to a silicon target (by the DC generator) as a function of the flow of oxygen entering the deposition chamber (expressed in sccm, the abbreviation of "Standard Cubic Centimeter per Minute" in English, or the number of cm ³ of gas flowing through minute under standard pressure and temperature conditions, ie at a temperature of 0 ° C and a pressure of 1013.25 hPa) on the state of the silicon target. The relationship between the target bias voltage and the oxygen flow rate forms a hysteresis which fixes the state of the silicon target: amorphous silicon (a-Si) for low oxygen flow rates (<7 sccm), substoichiometric silicon oxide (SiOx, with x between 1 and 2 excluded) for intermediate oxygen flow rates (7-18 sccm) and silicon dioxide (S1O2) for high oxygen flow rates (> 18 sccm) . The stoichiometry of the deposited silicon oxide can thus be controlled by virtue of the flow of oxygen entering the deposition chamber.

Eight reference memory cells were manufactured according to different values of manufacturing parameters listed in Table 1 below. The x-stoichiometry of SiOx is controlled via the flow of oxygen injected into the chamber. The other deposition parameters are identical between the 8 reference memory cells (temperature in the chamber: 25 ° C; DC generator power: 1 kW, main argon flow rate: 50 sccm; argon flow rate on the rear face of the substrate : 15 sccm; pressure in the chamber: 1 to 3 mTorr depending on the oxygen flow rate; cryogenic pump valve in intermediate position).

[0067] [Table 1]

Ό068] Table 1 also gives for these 8 reference memory cells the measured values of the initial resistance Ri and of the resistance in the strongly resistive RHRS. The resistance in the low resistive state RLRS is assumed to be constant and equal to 10 ⁴ W. The relationship between the oxygen flow rate values DO2 (between 4 sccm and 7 sccm) and the values of the proportion of oxygen x is the next :

[0069] [Math 4]

D ₀₂ = 10. x— 13

For an oxygen flow rate DO2 greater than or equal to 7 sccm, the proportion of oxygen x is equal to 2.

FIG. 3 is a graph on which the measured values of resistance Ri and RHRS of the 8 reference memory cells have been plotted. These points were then extrapolated using a C curve. The equation for C curve (obtained experimentally) is as follows:

[0072] [Math 5]

RHRS = -2.2. 10 ⁵ . (log (R _t ) † + 4. 10 ^6. log (R _t ) - 2. 10 ⁷

[0073] with Ri and RHRS in W.

Curve C, in the form of a bell or parabola, shows that there is a maximum of the resistance in the highly resistive state RHRS - and therefore a maximum of the programming window - for an initial resistance Ri of approximately 1 0 ⁸ W. An explanation for this bell-shaped dependence could be as follows: at low initial resistance Ri, it is not possible to achieve a high RHRS resistance value due to an intrinsic limitation of the resistance. of the memory cell. At a high initial resistance Ri, a high forming voltage is necessary to be able to use the memory cell and this high voltage generates a large quantity of defects in the SiOx layer. As the faults are still present when the memory cell is erased (return to the highly resistive state caused by dissolution of the conductive filament), the resistance of the highly resistive state is reduced.

According to curve C of Figure 3, an initial resistance Ri between 3.10 ⁷ W and 10 ⁹ W corresponds to a resistance in the highly resistive state RHRS greater than or equal to RHRsjgi = 10 ⁶ W. To obtain a programming window greater than or equal to 100, the resistive memory cell (TiN / SiOx / Ti) will therefore be manufactured so that its initial resistance Ri is between 3.10 ⁷ W and 10 ⁹ W.

There are multiple combinations of parameter values to obtain an initial resistance Ri of between 3.10 ⁷ W and 10 ⁹ W. As indicated previously, one of these combinations can be obtained by fixing a parameter (for integration reasons for example), then by varying the other two parameters. To facilitate the search for an initial resistance Ri between 3.10 ⁷ W and 10 ⁹ W, and taking into account the intended application, the tox_opt thickness of the oxide layer 12 can be set at a value between 4 nm and 7 nm. Alternatively or additionally, the thickness tTE_ _0pt of the upper electrode 13 can be fixed at a value between 3 nm and 7 nm. Alternatively or additionally, the oxygen concentration x _0pt can be set at a value between 1, 6 and 2 ( _i.e. an oxygen flow rate between 5 sccm and 8 sccm), preferably between 1, 8 and 1, 9.

[0077] [Fig 4]: Figure 4 shows the resistance values in the highly resistive state RHRS of the 8 previous reference memory cells, associated with the values of the forming voltage Vf which were applied to these cells. This figure shows by way of comparison that, when the manufacturing parameters are adjusted in order to achieve a forming voltage less than or equal to 2 V (typical value to be compatible with the memory supply circuit), a programming window is obtained which is approximately ten times smaller than the maximum programming window (reached for a forming voltage of approximately 3 V). The determination method according to the invention therefore allows a significant improvement in the programming window of resistive memory cells compared to current practice.

Still according to curve C of Figure 3, an initial resistance Ri between 10 ⁷ W and 3.10 ⁹ W corresponds to a resistance in the highly resistive state RHRS greater than or equal to RHRs_tg2 = 5.10 ⁵ W. For obtain a programming window greater than or equal to 50, the resistive memory cell (TiN / SiOx / Ti) will therefore be manufactured so that its initial resistance Ri is between 10 ⁷ W and 3.10 ⁹ W.

The silicon oxide SiOx can also be non-porous and substoichiometric (x <2). To facilitate the search for an initial resistance Ri between 3.10 ⁷ W and 10 ⁹ W, and taking into account the intended application, the tox_opt thickness of the oxide layer 12 can be set at a value between 3 nm and 4 nm. Alternatively or additionally, the thickness tTE_ ₀ pt of the upper electrode 13 can be set at a value between 4 nm and 6 nm. Alternatively or additionally, the oxygen concentration x _0p t can be set at a value between 1 and 1, 6, preferably between 1, 2 and 1, 4.

More generally, an extrapolation of the curve C makes it possible to determine the thickness of the oxide layer (non-porous) for a desired value of Ri as follows: log (Ri) = 1, 1 .tox + 0.7 where the thickness of the top electrode ÎTE was set at 10 nm and where the stoichiometric coefficient x was set at 1.2.

In the same way, an extrapolation of the curve C makes it possible to determine the stoichiometric coefficient x for a desired value of Ri as follows: log (Ri) = 1 9.X + 1 6 where the thickness of the Tox oxide layer (non-porous) was set at 3 nm and where the thickness of the top ÎTE electrode was set at 5 nm.

Another aspect of the invention relates to a method of manufacturing a resistive memory cell, and more particularly an OxRAM memory cell comprising a TiN / SiOx / Ti type stack.

The manufacture of the resistive memory cell successively comprises a step of depositing the lower electrode 1 1 on a substrate (for example made of silicon), a step of depositing the oxide layer 12 on the lower electrode 1 1 and a step of depositing the upper electrode 13 on the oxide layer 12. By following at each step the parameter value (s) obtained by means of the determination method according to the invention, the resistive memory cell will have a high programming window.

[0084] The silicon oxide (whether porous or non-porous) of the TiN / SiOx / Ti stack can be obtained by sputtering a source of silicon in the presence of oxygen. The lower titanium nitride electrode and the upper titanium electrode can be formed by sputtering (reactive in the case of TiN).

It will be noted that the invention is not limited to the embodiments described with reference to the figures and variants could be envisaged without departing from the scope of the invention.

Claims

[Claim 1] Method for determining at least one value (tTE_opt, tox_opt, Xopt) of at least one manufacturing parameter (ÎTE, tox, x) of a resistive memory cell, the resistive memory cell comprising a stack of thin layers , said method comprising the following steps:

- provide (S1) several reference memory cells (10) corresponding to several technological variants of the stack of thin layers;

- measuring (S2) for each reference memory cell an initial resistance value (Ri);

- determining (S3, S4) for each reference memory cell (10) a value of a programming parameter chosen from the resistance in a highly resistive state (RHRS) and the programming window;

- establish (S5) a relation between the programming parameter and the

initial resistance (Ri) from the values of initial resistance (Ri) and the values of the programming parameter; and

- determine said at least one value (tTE_opt, tox_opt, Xopt) of said au

minus one manufacturing parameter (ÎTE, tox, x) for which the

programming parameter is greater than or equal to a target value (RhiRsjg), from said relation between the parameter of

programming and the initial resistance (Ri) and at least one dependency relationship between the initial resistance (Ri) and said at least one manufacturing parameter (ÎTE, tox, x).

[Claim 2] A method according to claim 1, comprising the following steps:

- determine (S6), from said relationship between the programming parameter and the initial resistance (Ri), at least one value (Ri_opt) of the initial resistance for which the programming parameter is greater than or equal to the target value ( RHRsjg); and

- determining (S7) said at least one value (tTE_opt, tox_opt, Xopt) of said at least one manufacturing parameter (ÎTE, tox, x) from said at least one value of the initial resistance (Ri_opt). [Claim 3] A method according to claim 1 or 2, wherein the programming parameter is resistance in the high resistive state (RHRS) and wherein the step of determining the values of the programming parameter comprises the following steps:

- program

(S3) the reference memory cells (10) in the high resistive state;

- measure (S4) for each reference memory cell a resistance value in the highly resistive state (RHRS).

[Claim 4] The method of claim 3, wherein the resistance in the highly resistive state (RHRS) is a second degree polynomial function of the logarithm of the initial resistance (Ri).

[Claim 5] The method of claim 1 or 2, wherein the programming parameter is the programming window and wherein the step of determining the values of the programming parameter comprises the following operations:

- program the reference memory cells in a weakly resistive state;

- measure for each reference memory cell a value of

resistance in the low resistive state;

- program (S3) the reference memory cells in the highly resistive state;

- measure (S4) for each reference memory cell a resistance value in the highly resistive state (RHRS); and

- calculate for each reference memory cell a value of the programming window from the measured values of resistance in the low resistive state and resistance in the high resistive state.

[Claim 6] A method according to any one of claims 1 to 5, wherein the stack of thin films comprises a first electrode (11) disposed on a substrate, an oxide layer (12) disposed over the first electrode ( 1 1) and a second electrode (13) arranged on the oxide layer (12) and in which said at least one manufacturing parameter is chosen from the thickness of the second electrode (ÎTE), the thickness of the oxide layer (tox) and the proportion of oxygen (x) in the oxide layer (12).

[Claim 7] A method of manufacturing a resistive memory cell, comprising the following steps:

- determining a value (tTE_opt, tox_opt, Xopt) of at least one manufacturing parameter (ÎTE, tox, x), by following a method according to any one of claims 1 to 5;

- forming on a substrate a stack comprising successively a first electrode (1 1), an oxide layer (12) and a second electrode (13), by applying the value of said at least one manufacturing parameter.

[Claim 8] The method of claim 7, wherein the oxide layer (12) is formed of a substoichiometric silicon oxide (SiOx).

[Claim 9] A method according to claim 7, wherein the oxide layer (12) is formed of a porous silicon oxide.

[Claim 10] A method according to one of claims 7 to 9, wherein the first electrode (1 1) is made of titanium nitride and the second electrode (13) is of titanium.