CH719581A2 - Solid electrolyte battery and its manufacturing process by protonation. - Google Patents

Abstract

The invention relates to a battery (20) with a solid electrolyte (8) and its production method, the method comprising the following successive steps: – a step of protonation of a body (11) comprising, preferably entirely, a ceramic material capable of being protonated, to form a protonated layer (13) on the body (11), – a step of depositing a metallic element forming an anode (14) on the protonated layer (13) of a first side (7) of the body (11), – a step of assembling a cathode (15) on a second side (9) of the body (11), preferably opposite the first side (7) of the anode ( 14), and – a step of forming dendrites (18) from the metallic element in the protonated layer (13) of the body (11).

Description

Technical field of inventions

[0001] The invention relates to solid electrolyte batteries, called all-solid-state batteries or “all solid-state batteries” in English.

[0002] The invention also relates to the method of manufacturing such a solid electrolyte battery.

[0003] The invention also relates to electronic systems, such as a watch, a laptop computer, a mobile telephone or a motor vehicle, comprising such a solid electrolyte battery.

Technology background

[0004] Solid or all-solid electrolyte batteries are alternatives to lithium-ion type accumulators. Unlike the latter, which include a liquid electrolyte, all-solid batteries include a solid electrolyte placed between an anode and a cathode.

[0005] Such batteries have the advantage of having a higher energy density than lithium-ion batteries, and therefore have a greater storage capacity, which is promising in many fields of application.

[0006] It is known to use ceramic compounds as solid electrolyte, such as LLZO type compounds.

The LLZO type compound has a high ionic conductivity. This ceramic compound includes lithium, lanthanum, zirconium and oxygen, and has for example the chemical formula Li7La3Zr2O12 or Li7La3Zr2O7. It can also be doped with tantalum or aluminum, in order to stabilize its cubic phase, which is conductive to lithium ions. It then has, for example, the chemical formula Li64La3Zr2Ta06O12.

[0008] A disadvantage of ceramic compounds lies in the contact between the anode, for example lithium, and the solid electrolyte. Indeed, it is important to avoid the presence of impurities and roughness between the two elements, because they create constriction currents and cavities, which generate the formation of lithium dendrites which pass through the ceramic compound and produce short circuits. In fact, these constriction currents can exceed a current threshold value, which causes the appearance of dendrites, in particular of lithium, in the ceramic compound.

To remedy this problem, one solution is to place a conductive liquid between the ceramic compound and the lithium anode. This improves contact between the two.

However, we then find the same problems linked to liquid electrolyte batteries, in particular the risk of liquid leaking outside the battery, and the consequences which result from this. Furthermore, the risk of formation of lithium dendrites is not resolved with the presence of a liquid.

Summary of the invention

[0011] The invention aims to remedy the aforementioned drawbacks, and aims to provide a production method making it possible to form a solid electrolyte battery which improves the contact between the anode and the solid electrolyte, without having to resort to a liquid contact element.

[0012] To this end, the invention relates to a process for producing a solid electrolyte battery.

[0013] The invention is remarkable in that the method comprises the following successive steps: – a step of protonation of a body comprising, preferably entirely, a ceramic material capable of being protonated, to form a protonated layer on the body, – a step of depositing a metallic element forming an anode on the protonated layer of a first side of the body, – a step of assembling a cathode on a second side of the body, preferably opposite the first side of the anode, and – a step of forming dendrites from the metallic element in the protonated layer of the body.

The protonated layer of the ceramic is less hard than the initial ceramic, so that it is easier to form dendrites in this layer. The dendrites improve the contact between the metallic element and the body of the solid electrolyte, in particular because the contact surface is increased by the contact irregularities formed by the dendrites. In addition, the part of the body that remains unprotonated, which is harder, prevents these dendrites from propagating to the cathode and causing a short circuit. In addition, the risk of the appearance of constriction currents, and thus the formation of dendrites in this non-protonated part, is avoided.

[0015] According to a particular embodiment of the invention, the ceramic material is to be chosen from: – zirconium oxide with lithium and/or lanthanum, doped or undoped of the LLZO type, – a beta-solid electrolyte material alumina, doped or undoped, of the Na-b''-Al2O3 type, – a solid electrolyte material based on ternary, quaternary or higher order sulphide, for example of the Li5PS5X type (where X is to be chosen from the elements CI, Br or I) or of the Li2S-P2S5 type, – a solid electrolyte material based on ternary, quaternary or higher order halogens, for example of the Li3MX6 type (or M is a metal or an alloy of metals, and X a halogen),-a solid electrolyte material driver of lisicon type ions (for lithium super ionic conductor), for example li4 ± xsi1-xxxo4 (where x is to choose from the elements p, al, or ge ), and – a solid electrolyte material conducting sodium ions of the NASICON type (for sodium super ionic conductor), for example of the NaxMM'(XO4)3 type (where M and M' are metals and elements Si, P or S).

[0016] According to a particular embodiment of the invention, in the protonation step, the body is immersed in a protic or acidic solvent, such as water, acetone, mineral oil or ethanol. .

[0017] According to a particular embodiment of the invention, the method comprises an additional step of heating the body to a predefined temperature to clean the body of impurities, the predefined temperature preferably being between 350°C and 450°C , the additional heating step preceding the step of depositing the metallic element.

[0018] According to a particular embodiment of the invention, the dendrite formation step comprises a repeated succession of current flow cycles between the anode and the cathode.

[0019] According to a particular embodiment of the invention, the metal element is melted on the body during the step of deposition of the metal element.

[0020] According to a particular embodiment of the invention, the metallic element comprises a material to be chosen from: – alkali metals, such as lithium, sodium, potassium, rubidium, cesium or francium, – alkaline earth metals, such as beryllium, magnesium, calcium, strontium, barium or radium, – all transition metals, which belong to columns 3 to 11 of the periodic table, including lanthanides and actinides, and – alloys of these metals.

According to a particular embodiment of the invention, the method comprises an additional step of removing part of the protonated layer of the body in order to deposit the cathode directly on the non-protonated part of the body.

According to a particular embodiment of the invention, the additional step of removing part of the protonated layer of the body is carried out by polishing the second side of the body.

[0023] According to a particular embodiment of the invention, the cathode comprises a material to be chosen from: – a lithium-nickel-manganese-cobalt oxide of the NMC type, such as LiNixMnyCozO2 or Li2-x-y-zNixMnyCozO2 with x+y +z ≤1, – a lithium-nickel-manganese oxide of the LNMO type, such as LiNi0.5Mn1.504, – a lithiated iron phosphate oxide of the LFP type, such as LiFePO4, – a lithium-manganese oxide of the LMO type , such as LiMn2O4, and – a lithium-nickel-cobalt-aluminum oxide of NCA type, such as LiNiCoAlO2.

[0024] The invention also relates to a solid electrolyte battery comprising an anode, a cathode, and a solid ceramic electrolyte, characterized in that the solid electrolyte is provided with a protonated layer and a non-protonated part. protonated superimposed, the cathode being deposited on the body, the anode comprising a metallic element deposited on the protonated layer of the body opposite the cathode, the metallic element comprising dendrites infiltrated in the protonated layer of the body.

According to a particular embodiment of the invention, the dendrites are blocked by the non-protonated part of the body.

[0026] According to a particular embodiment of the invention, the metallic element comprises a material to be chosen from: – alkali metals, such as lithium, sodium, potassium, rubidium, cesium or francium, – alkaline earth metals, such as beryllium, magnesium, calcium, strontium, barium or radium, – all so-called transition metals, which belong to columns 3 to 11 of the periodic table, including lanthanides and actinides, and – alloys of these metals.

[0027] According to a particular embodiment of the invention, the ceramic material is to be chosen from: – zirconium oxide with lithium and/or lanthanum, doped or undoped of the LLZO type, – a beta-solid electrolyte material alumina, doped or undoped, of the Na-b''-Al2O3 type, – a solid electrolyte material based on ternary, quaternary or higher order sulphide, for example of the Li6PS5X type (where X is to be chosen from the elements CI, Br or I) or of the Li2S-P2S5 type, – a solid electrolyte material based on ternary, quaternary or higher order halogens, for example of the Li3MX6 type (where M is a metal or an alloy of metals, and X a halogen),-a solid electrolyte material driver of lisicon type ions (for lithium super ionic conductor), for example li4 ± xsi1-xxxo4 (where x is to choose from the elements p, al, or ge ), and – a solid electrolyte material conducting sodium ions of the NASICON type (for sodium super ionic conductor), for example of the NaxMM'(XO4)3 type (where M and M' are metals and elements Si, P or S).

According to a particular embodiment of the invention, the cathode is stuck to the non-protonated part of the body.

[0029] According to a particular embodiment of the invention, the cathode comprises a material to be chosen from: – a lithium-nickel-manganese-cobalt oxide of the NMC type, such as LiNixMnyCozO2 or Li2-x-y-zNixMnyCozO2 with x+y +z ≤1, – a lithium-nickel-manganese oxide of the LNMO type, such as LiNi0.5Mn1.504, – a lithiated iron phosphate oxide of the LFP type, such as LiFePO4, – a lithium-manganese oxide of the LMO type , such as LiMn2O4, and – a lithium-nickel-cobalt-aluminum oxide of NCA type, such as LiNiCoAlO2.

[0030] The invention also relates to an electronic system, for example a watch, a drone, a laptop computer, a mobile telephone or a motor vehicle, comprising such an all-solid battery.

Brief description of the figures

[0031] Other particularities and advantages will emerge clearly from the description given below, for information only and in no way limiting, with reference to the appended drawings, in which: – Figure 1 is a synoptic diagram representing the stages of the process according to the invention; and – Figures 2a) to 2f) are schematic representations in straight section of the battery after each step of the process for producing the battery according to the invention.

Detailed description of the invention

The invention relates to a method 10 for producing a solid electrolyte battery 20. Such a battery 20 comprises an anode 14, a cathode 15 and an electrolyte arranged between the cathode 15 and the anode 14. calls solid electrolyte 8, an electrolyte which is not liquid.

The electrolyte 8 is formed from a body 11 comprising a material capable of undergoing protonation. In other words, it is capable of exchanging H<+>ions with protons. Preferably the body 11 comprises this material entirely.

[0034] The ceramic material used is to be chosen from: – zirconium oxide with lithium and/or lanthanum, doped or undoped, LLZO type, – a solid beta-alumina electrolyte material, doped or undoped, of the type Na-b''-Al2O3, – a solid electrolyte material based on ternary, quaternary or higher order sulphide, for example of the Li6PS5X type (where X is to be chosen from the elements CI, Br or I) or of the Li2S type -P2S5, – a solid electrolyte material based on ternary, quaternary or higher order halogens, for example of the Li3MX6 type (where M is a metal or an alloy of metals, and X a halogen), – a solid electrolyte material lithium ion conductor of the LISICON type (for lithium super ionic conductor), for example of the Li4±xSi1-xXxO4 type (where X is to be chosen from the elements P, Al, or Ge), and – a solid electrolyte material conductor sodium ions of the NASICON type (for sodium super ionic conductor), for example of the NaxMM'(XO4)3 type (where M and M' are metals and X is to be chosen from the elements Si, P or S).

The ceramic material preferably comprises this material in its entirety.

Preferably, the LLZO type compound is chosen, because it has high ionic conductivity.

To produce the battery 20, a process is used comprising a first step of protonation 1 of the ceramic body 11. The body 11 is immersed in a protic or acidic solvent, such as water, acetone, mineral oil or ethanol, in order to replace atoms in the ceramic with a proton. Preferably, water is chosen as the protic solvent.

The body is immersed for a long time, at least a day, preferably several days, or even a week or more, depending on the size of the body 11 and the protonated layer that one wishes to obtain.

The body has for example the shape of a pellet having a thickness of 0.7mm in order to form a small battery 20. The body has preferably been previously polished to have parallel faces.

Preferably, to accelerate the process, the liquid is heated to a predetermined temperature, for example to 50°C.

[0041] In the case of the LLZO type compound, the formula for protonation with water is as follows: LLZO+ H2O→HLLZO + LiOH.

Whatever the liquid used, the protonated HLLZO type compound is obtained. The protonated HLLZO type compound is softer than the unprotonated LLZO type compound, which is a very hard ceramic.

Following this step, the body 11 comprises a protonated layer 12, 13 around the body 11. The layer 12, 13 is arranged around the entire body 11, if the body is completely immersed in the liquid.

The layer has, for example, a thickness of 20 μm. A first layer 13 is placed on a first side 7 of the body 11, and a second layer 12 is placed on a second side 9 of the body 11.

The method 10 comprises a second step 2 of removing the second protonated layer 12 from the second side 9 of the body 11 in order to be able to deposit the cathode 15 directly on a non-protonated part of the body 11 in a subsequent step. In fact, the conductivity between the cathode 15 and a non-protonated part is better than between a cathode 15 and a protonated part.

Preferably, the second removal step 2 comprises polishing the second side 9 of the body 11. The polishing makes it possible to remove the layer of protonated material 12 to expose a non-protonated part of the body 11. We use by example a polishing tool with a grain size of 600 to remove the HLLZO type protonated layer.

[0047] In a third step 3, the body 11 is heated to a predefined temperature to clean the body 11 of impurities. The predefined temperature is preferably between 300 and 500°C, preferably between 350°C and 450°C. This temperature range avoids denaturation or decomposition of the material of body 11, whether protonated or non-protonated. In particular, we want to remove carbonate type molecules from the surface of body 11, because they increase the resistance at the interface of the electrode and the electrolyte. The heating time is for example three hours.

The fourth step 4 consists of depositing a metal element forming an anode 14 on the protonated part of the first side of the body 11. The first side 7 is chosen opposite the second side 9 of the body 11. Thus, the cathode 15 and the anode 14 are arranged on either side of body 11.

[0049] The metallic element comprises a material to be chosen from: – alkali metals, such as lithium, sodium, potassium, rubidium, cesium or francium, – alkaline earth metals, such as beryllium , magnesium, calcium, strontium, barium or radium, – all transition metals, which belong to columns 3 to 11 of the periodic table, including lanthanides and actinides, and – alloys of these metals .

The metallic element preferably comprises this material in its entirety.

Preferably, lithium is chosen for its favorable physical and chemical properties for its use as anode 14.

The molten metallic element is deposited on the first protonated side 7 of the body 11. In other words, the metallic element is deposited in molten form on the first side 7. In this state, the metallic element adheres to the body 11 of the first side 7, in particular to maximize the extent of the contact face between the metal element and the body 11.

The method comprises a fifth step 5 of assembling a cathode 15 on the body 11 of the second side 9 opposite the anode 14, which is not protonated following the polishing of the second step 2.

[0054] To this end, a glue 16 of polymer material is used to assemble them, called a catholyte, the glue 16 being ion conductive so that the passage of ions can occur.

For example, a polymer glue 16 is used comprising polyethylene oxide of the PEO type, a lithium salt of the LiTFSi type (for lithium bis-(trifluoromethanesulfonyl)-imide), as well as THF (for tetrahydrofuran). . The polymer glue 16 is dissolved in THF (for tetrahydrofuran), then is deposited on the second side 9, for example by means of a “drop casting” type method, then the cathode 15 is deposited on the polymer glue 16 after drying of the THF, so that the cathode 15 adheres to the second side 9 permanently.

[0056] The cathode 15 comprises for example a material to be chosen from: – a lithium-nickel-manganese-cobalt oxide of the NMC type, such as LiNixMnyCozO2 or Li2-x-y-zNixMnyCozO2 with x+y+z ≤1, – a lithium oxide -nickel-manganese of LNMO type, such as LiNi05Mn15O4, – a lithiated iron phosphate oxide of LFP type, such as LiFePO4, – a lithium-manganese oxide of LMO type, such as LiMn2O4, and – a lithium-nickel-cobalt oxide - NCA type aluminum, such as LiNiCoAlO2.

The cathode 15 preferably comprises this material in majority, as well as the polymer glue and carbon in order to improve its ionic and electronic conductivity.

The sixth step 6 consists of forming dendrites 18 in the remaining protonated layer 13 from the metallic element of the anode 14. The dendrites 18 are elongated elements which penetrate into the protonated layer 13, which is more fragile than the non-protonated part 11. The dendrites 18 are formed naturally by the passage of current. Cracks appear in the protonated layer 13, which are then filled by the metallic element coming from the anode 14.

To this end, the sixth step 6 comprises a repeated succession of current flow cycles between the anode 14 and the cathode 15. At each cycle, a current is applied to the terminals of the battery, to the anode 14 and to the cathode. The current is for example chosen so as to have 0.1 mA /cm<2>.

Several cycles are carried out, preferably less than ten, alternating the polarity of the current. A positive current follows a negative current, and vice versa.

The dendrites 18, preferably made of lithium, penetrating into the protonated layer 13 promote the quality of the ionic contact by increasing the contact surface between the anode 14 and the solid electrolyte 8.

[0062] In Figure 2a), a body 11 is shown comprising entirely a ceramic material of the LLZO type. After the first protonation step, the body 11 comprises a protonated layer 12, 13 around the body 11, as shown in Figure 2b). A first layer 13 is arranged on a first side 7 of the body 11 and a second layer 12 is arranged on a second side 9 of the body 11

The body 11 is then polished on the second side 9 of the body 11, so as to reveal a non-protonated part on this side. The body 11 of Figure 2c) thus has a non-protonated part of the second side 9 and a protonated layer 13 of a first side 7 of the body 11.

According to the fourth step, an anode 14 is formed on the first protonated side 7 of the body 11, by the deposition of a molten metallic element, preferably lithium, as shown in Figure 2d). The body 11 remains substantially identical after the fifth cleaning step,

A cathode 15 is glued to the second non-protonated side 9 of the body 11, using polymer glue 16, as shown in Figure 2e).

[0066] Figure 2f) shows the sixth step of dendrite formation, during which a current is applied in cycles to the anode 14 and the cathode 15 of the battery by means of a current generator 19. We observe dendrites 18 formed in the cracks of the protonated layer 13 of the body 11. These dendrites 18 are blocked by the non-protonated part of the body 11, which is harder than the protonated layer 13.

The dendrites 18 are fine elongated elements, which extend into the protonated layer 13 from the anode 14.

[0068] Thus, we obtain a battery 20 with an anode 14 and a cathode 15 on each side of the electrolyte 8, the body 11 having a layer of protonated ceramic 13 and a non-protonated part superimposed.

Such a battery 20 can be used in any electronic system, such as a watch, a drone, a mobile phone, a laptop, or even an electronic automobile vehicle. In the case of a motor vehicle, the size of the battery is of course more important.

Naturally, the invention is not limited to the embodiments described with reference to the figures and variants could be considered without departing from the scope of the invention.

Claims (17)

1. Method for producing (10) a battery (20) with solid electrolyte (8), characterized in that the method comprises the following successive steps: – a step of protonation (1) of a body (11) comprising, preferably entirely, a ceramic material capable of being protonated, to form a protonated layer (12, 13) on the body (11), – a step of depositing (4) a metallic element forming an anode (14) on the protonated layer (13) of a first side (7) of the body (11), – a step of assembling (5) a cathode (15) on a second side (9) of the body (11), preferably opposite the first side (7) of the anode (14), and – a step of forming (6) dendrites (18) from the metallic element in the protonated layer (13) of the body (11). 2. Production method (10) according to claim 1, characterized in that the ceramic material is to be chosen from: – zirconium oxide with lithium and/or lanthanum, doped or undoped, LLZO type, – a solid beta-alumina electrolyte material, doped or undoped, of the Na-b''-Al2O3 type, – a solid electrolyte material based on ternary, quaternary or higher order sulphide, for example of the Li6PS5X type (where X is to be chosen from the elements Cl, Br or I) or of the Li2S-P2S5 type, – a solid electrolyte material based on ternary, quaternary or higher order halogens, for example of the Li3MX6 type (where M is a metal or an alloy of metals, and X is a halogen), – a solid electrolyte material conducting lithium ions of the LISICON type (for lithium super ionic conductor), for example of the Li4±xSi1-xXxO4 type (where X is to be chosen from the elements P, Al, or Ge), and – a solid electrolyte material conducting sodium ions of the NASICON type (for sodium super ionic conductor), for example of the NaxMM'(XO4)3 type (where M and M' are metals and X is to be chosen from the elements Si, P or S). 3. Production method (10) according to claim 1 or 2, characterized in that in the protonation step (1), the body (11) is immersed in a protic or acidic solvent, such as water, acetone, mineral oil or ethanol. 4. Production method (10) according to any one of the preceding claims, characterized in that it comprises an additional step of heating (3) the body (11) to a predefined temperature to clean the body (11) impurities, the predefined temperature preferably being between 350°C and 450°C, the additional heating step (3) preceding the deposition step (4) of the metallic element. 5. Production method (10) according to any one of the preceding claims, characterized in that the step of forming (6) dendrites (18) comprises a repeated succession of current flow cycles between the anode (14) and the cathode (15). 6. Production method (10) according to any one of the preceding claims, characterized in that the metal element is melted on the body (11) during the step of deposition (4) of the metal element . 7. Production method (10) according to any one of the preceding claims, characterized in that the metallic element comprises a material to be chosen from: – alkali metals, such as lithium, sodium, potassium, rubidium, cesium or francium, – alkaline earth metals, such as beryllium, magnesium, calcium, strontium, barium or radium, – all transition metals, which belong to columns 3 to 11 of the periodic table, including lanthanides and actinides, and – alloys of these metals. 8. Production method (10) according to any one of the preceding claims, characterized in that it comprises an additional step of removing (2) a part of the protonated layer (12) of the body (11) in order to deposit the cathode (15) directly on the non-protonated part of the body (11). 9. Production method (10) according to claim 6, characterized in that the additional step of removing (2) a part of the protonated layer of the body (11) is carried out by polishing the second side (9) of the body (11). 10. Production method (10) according to any one of the preceding claims, characterized in that the cathode (15) comprises a material to be chosen from: – a lithium-nickel-manganese-cobalt oxide of the NMC type, such as LiNixMnyCozO2 or Li2-x-y-zNixMnyCozO2 with x+y+z ≤1, – a lithium-nickel-manganese oxide of the LNMO type, such as LiNi05Mn15O4, – a lithiated iron phosphate oxide of the LFP type, such as LiFePO4, – a lithium-manganese oxide of the LMO type, such as LiMn2O4, and – a lithium-nickel-cobalt-aluminum oxide of NCA type, such as LiNiCoAlO2. 11. Battery (20) with solid electrolyte (8) comprising an anode (14), a cathode (15) and a solid ceramic electrolyte (8), characterized in that the solid electrolyte (8) is provided with a protonated layer (13) and a non-protonated part superimposed, the cathode (15) being deposited on the body (11), the anode (14) comprising a metallic element deposited on the protonated layer (13) of the body (11 ) opposite the cathode (15), the metallic element comprising dendrites (18) infiltrated in the protonated layer (13) of the body (11). 12. Battery (20) with solid electrolyte (8) according to claim 11, characterized in that the dendrites (18) are blocked by the non-protonated part of the body (11). 13. Battery (20) with solid electrolyte (8) according to claim 11 or 12, characterized in that the metallic element comprises a material to be chosen from: – alkali metals, such as lithium, sodium, potassium, rubidium, cesium or francium, – alkaline earth metals, such as beryllium, magnesium, calcium, strontium, barium or radium, – all of the so-called transition metals, which belong to columns 3 to 11 of the periodic table, including the lanthanides and actinides, and – alloys of these metals. 14. Battery (20) with solid electrolyte (8) according to any one of claims 11 to 13, characterized in that the ceramic material is to be chosen from: – zirconium oxide with lithium and/or lanthanum, doped or undoped, LLZO type, – a solid beta-alumina electrolyte material, doped or undoped, of the Na-b''-Al2O3 type, – a solid electrolyte material based on ternary, quaternary or higher order sulphide, for example of the Li6PS5X type (where X is to be chosen from the elements CI, Br or I) or of the Li2S-P2S5 type, – a solid electrolyte material based on ternary, quaternary or higher order halogens, for example of the Li3MX6 type (where M is a metal or an alloy of metals, and X is a halogen), – a solid electrolyte material conducting lithium ions of the LISICON type (for lithium super ionic conductor), for example of the Li4±xSi1-xXxO4 type (where X is to be chosen from the elements P, Al, or Ge), and – a solid electrolyte material conducting sodium ions of the NASICON type (for sodium super ionic conductor), for example of the NaxMM'(XO4)3 type (where M and M' are metals and X is to be chosen from the elements Si, P or S). 15. Battery (20) with solid electrolyte (8) according to any one of claims 11 to 14, characterized in that the cathode (15) is stuck to the non-protonated part of the body (11). 16. Battery (20) with solid electrolyte (8) according to any one of claims 11 to 15, characterized in that the cathode (15) comprises a material to be chosen from: – a lithium-nickel-manganese-cobalt oxide of the NMC type, such as LiNixMnyCozO2 or Li2-x-y-zNixMnyCozO2 with x+y+z ≤1, – a lithium-nickel-manganese oxide of the LNMO type, such as LiNi05Mn15O4, – a lithiated iron phosphate oxide of the LFP type, such as LiFePO4, – a lithium-manganese oxide of the LMO type, such as LiMn2O4, and – a lithium-nickel-cobalt-aluminum oxide of NCA type, such as LiNiCoAlO2. 17. Electronic system, for example a watch, a laptop computer, a mobile telephone or a motor vehicle, comprising a battery (20) with solid electrolyte (8), according to any one of claims 11 to 16.