JP2023015796A - Solid electrolyte, powder for producing solid electrolyte, and production method of solid electrolyte - Google Patents

Abstract

To provide easily sinterable powder which is preferable for production of a NASICON type LTP solid electrolyte, and the NASICON type LTP solid electrolyte having great density and being excellent in electric conductance.SOLUTION: There is provided a solid electrolyte being formed of a sinter body whose bulk part is formed of a NASICON type LTP, and whose neck part has cobalt oxide which exists thereon.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a solid electrolyte, a powder for producing a solid electrolyte, and a method for producing a solid electrolyte.

All-solid-state secondary batteries are strongly expected as next-generation rechargeable batteries.
An all-solid-state secondary battery consists mainly of positive and negative electrodes and a solid electrolyte. In the lithium-ion all-solid-state secondary battery, which is currently attracting attention in particular, the solid electrolyte must have electrical conductivity, mechanical strength, NASICON-type LTP-based solid electrolytes with excellent properties such as chemical stability, especially LATP solid electrolytes such as Li _1.3 Al _0.3 Ti _1.7 (PO ₄ ) ₃ with excellent performance are mainly used. being considered.

In order to efficiently produce an all-solid secondary battery with high productivity at a low cost, it is preferable to produce the electrode and the LTP or LATP solid electrolyte by an integral sintering method.
LTP and LATP solid electrolytes are generally produced by a sintering method, and the sintering temperature is 1000° C. or higher. On the other hand, the general sintering temperature of the olivine-type (olivine-type) positive electrode active material is about 800° C. in order to suppress diffusion with the electrode.
For this reason, when performing integral sintering, the sintering temperature is limited to 800° C., which is lower than that of the LTP and LATP solid electrolytes, due to the bottleneck of the positive electrode active material. Incidentally, when sintered at 1000° C., diffusion occurs between the electrode and the LTP or LATP solid electrolyte, and there arises a problem that electrical properties such as generation of a high resistance phase due to solid phase reaction become poor.

When the sintering temperature is about 800°C, the relative density of LTP and LATP with no sintering aid added is about 60%, which is very low compared to about 80% when sintered at 1000°C. It will be even lower.

Therefore, the sintering temperature is 800 ° C. or less, it is possible to increase the density, and it is indispensable for manufacturing an easily sinterable LTP solid electrolyte with high mechanical strength and excellent electrical conductivity. Powders for producing solid electrolytes and methods for producing them have been desired.

In Patent Document 1, when simultaneously firing an olivine type positive electrode active material and a NASICON type solid electrolyte, diffusion of Li metal elements (Mn, Co, Ni) from the positive electrode active material to the solid electrolyte is suppressed, Disclosed is an all-solid secondary battery and a manufacturing method that suppresses the influence of There, a transition metal that diffuses into the electrolyte layer is added, which suppresses the reaction and improves the sinterability. Here, the addition of the transition metal is carried out during synthesis of the electrolyte or to the synthesized electrolyte as an oxide, carbonate or acetate. In the method of adding oxides, non-uniformity occurs in the local structure due to the particle size and dispersibility of the particles. There is a problem in particle dispersion control.

JP 2015-11864 A

DISCLOSURE OF THE INVENTION The present invention has been made to solve the conventional problems described in the background art above, and includes a NASICON-type LTP or LATP solid electrolyte having high density and excellent electrical conductivity and sinterability, and a solid electrolyte thereof. An object of the present invention is to provide a sintering powder suitable for the production of electrolytes.
Another object of the present invention is to provide a method for producing an easily sinterable NASICON-type LTP or LATP solid electrolyte with a sintering temperature of 800° C. or less, high density and excellent electrical conductivity.

The configuration of the present invention is shown below.
(Configuration 1)
The bulk part is made of NASICON type LTP,
A solid electrolyte consisting of a sintered body with cobalt oxide present in the neck.
(Configuration 2)
The solid electrolyte according to configuration 1, wherein the bulk portion is composed of one or more electrolytes selected from the group consisting of NASICON-type LATP and NASICON-type LAGP.
(Composition 3)
The solid electrolyte according to configuration 1, wherein the bulk portion is made of NASICON-type LATP.
(Composition 4)
A powder comprising a solid electrolyte base material and a coating material covering the surface of the solid electrolyte base material,
The solid electrolyte base material is made of NASICON type LTP,
The coating material contains cobalt (Co) ions,
A powder for producing a solid electrolyte, wherein the thickness of the coating material is on the order of an atomic layer.
(Composition 5)
5. The powder according to configuration 4, wherein the solid electrolyte base material comprises one or more selected from the group consisting of NASICON-type LATP and NASICON-type LAGP.
(Composition 6)
6. The powder of configuration 5, wherein the solid electrolyte matrix comprises NASICON-type LATP.
(Composition 7)
7. The powder of any one of arrangements 4-6, wherein cobalt ions are contained only in the coating.
(Composition 8)
8. The powder of any one of configurations 4-7, wherein the coating material comprises cobalt nitrate.
(Composition 9)
dissolving a cobalt salt in a solvent capable of azeotroping with water to form a solution;
preparing a dispersion (slurry) by adding and dispersing a solid electrolyte base material made of NASICON type LTP into the solution;
drying the dispersion to obtain a solid;
pulverizing the solid to obtain a powder containing cobalt ions;
obtaining a molded body by molding the powder;
A method for producing a solid electrolyte, wherein the molded body is sintered in an environment in which oxygen is present.
(Configuration 10)
10. The method for producing a solid electrolyte according to configuration 9, wherein the solid electrolyte base material comprises one or more selected from the group consisting of NASICON-type LATP and NASICON-type LAGP.
(Composition 11)
The method for producing a solid electrolyte according to Structure 9, wherein the solid electrolyte base material is NASICON-type LATP.
(Composition 12)
12. The method for producing a solid electrolyte according to any one of Structures 9 to 11, wherein the cobalt salt is cobalt nitrate.
(Composition 13)
13. The method for producing a solid electrolyte according to configuration ₁₂ , wherein the cobalt nitrate is Co(NO ₃ ) 2.6H ₂ O.
(Composition 14)
14. The method for producing a solid electrolyte according to any one of Structures 9 to 13, wherein the solvent contains one or more selected from the group consisting of methanol, ethanol and propanol.
(Composition 15)
15. The method for producing a solid electrolyte according to configuration 14, wherein the solvent is ethanol.
(Composition 16)
16. The method for producing a solid electrolyte according to any one of Structures 9 to 15, wherein the sintering is performed in an atmospheric environment.
(Composition 17)
17. The method for producing a solid electrolyte according to any one of Structures 9 to 16, wherein the sintering temperature is 600°C or higher and 800°C or lower.
(Composition 18)
Production of a solid electrolyte according to any one of Structures 9 to 17, wherein the ratio B/A of the molar amount B of the cobalt salt to the molar amount A of the solid electrolyte base material is 0.001 or more and 0.1 or less. Method.

INDUSTRIAL APPLICABILITY According to the present invention, an easily sinterable NASICON-type LTP solid electrolyte with high density and excellent electrical conductivity and a sintering powder suitable for producing the solid electrolyte are provided. Also provided is a method for producing an easily sinterable NASICON-type LTP solid electrolyte having a sintering temperature of 800° C. or less, high density and excellent electrical conductivity.

It is an explanatory view showing the structure of the sintered body of the present invention. FIG. 2 is a flow chart for manufacturing the easily sinterable solid electrolyte of the present invention. It is an explanatory view showing the structure of powder. FIG. 2 is a characteristic diagram showing the sintering temperature dependence of the relative density of the easily sinterable solid electrolyte of the present invention with the amount of Co added as a parameter. FIG. 2 is a characteristic diagram showing the dependence of the relative density of the sinterable solid electrolyte of the present invention on the amount of Co added, and the sintering condition is 800° C. under atmospheric pressure. FIG. 4 is a characteristic diagram showing Co addition amount dependence of the relative density of the solid electrolyte when the sintering condition is 800° C. under Ar gas. 1 is a SEM photograph of a fracture surface structure of a sintered body formed by sintering at 800° C. without adding Co. FIG. 1 is an SEM photograph of a fracture surface structure of a sintered body (easily sinterable solid electrolyte (Co-LATP)) formed by adding Co and sintering at 800° C. FIG. 1 is a SEM photograph of a fracture surface structure of a sintered body (easily sinterable solid electrolyte (Co-LATP)) formed by adding Co and sintering at 1000° C. FIG. FIG. 2 is a characteristic diagram showing electrical conductivity characteristics of the easily sinterable solid electrolyte of the present invention formed by sintering at 800° C. FIG. FIG. 3 is a characteristic diagram showing electrical conductivity characteristics of the easily sinterable solid electrolyte of the present invention formed by sintering at 1000°C.

The present invention will be described in detail below. Although the detailed description of the present invention set forth below may be based on representative aspects, embodiments, and examples, these are exemplary and the present invention is directed to such aspects, embodiments, and examples. and is not limited to the examples.
Note that "A to B" indicates A or more and B or less.

(Embodiment 1)
Embodiment 1 describes a method for producing a NASICON-type LTP easily sinterable lithium ion solid electrolyte of the present invention.

The present invention improves the sinterability of solid electrolytes by uniformly and simply coating the surfaces of electrolyte particles with a very small amount of ions of an element (cobalt (Co)) that serves as a sintering aid through dissolution and precipitation reactions. be. As a result, sintering at a relatively low temperature of 800° C., which suppresses the reaction and diffusion of the electrode placed in contact with the solid electrolyte and the active material composing the electrode, produces a solid electrolyte with a necessary and sufficient high electric power. Conductivity and high relative density can be obtained. Here, when the relative density is high, generally high mechanical strength is obtained.
The details are shown below.

FIG. 2 shows the manufacturing process of the all-solid electrolyte according to Embodiment 1. As shown in FIG.
First, a cobalt salt is dissolved in a solvent (step S01).
In the present invention, the solid electrolyte powder is characterized in that its surface is covered with a coating material containing cobalt, and a cobalt salt is used as the coating material containing cobalt.
Here, as the cobalt salt, cobalt nitrate can be preferably mentioned, and cobalt nitrate hexahydrate (Co(NO ₃ ) _{2.6H 2 O} ) can be particularly preferably used. With cobalt nitrate, the nitrate group volatilizes during sintering and only cobalt remains, so it is possible to minimize residual impurities. Furthermore, by using a hydrate of cobalt nitrate, particularly Co(NO ₃ ) ₂ .6H ₂ O, it is possible to obtain a coating material that dissolves well in a solvent and contains a small amount of cobalt extremely uniformly.

The solvent is a solvent that can be azeotroped with water, for example, a solvent containing one or more selected from the group consisting of methanol, ethanol, and propanol, and particularly preferably ethanol. Here, for example, as a solvent containing ethanol, a solvent in which water is added to ethanol can be mentioned.
It should be noted that this dissolution is preferably carried out with stirrer stirring or application of ultrasonic waves. Room temperature is preferred because of ease of handling and low cost.

Next, the NASICON-type LTP solid electrolyte base material is put into the solvent and dispersed to prepare a dispersion (step S02).
Here, LTP is more preferably one or more selected from the group consisting of LATP and NASICON-type LAGP. Using LATP and/or LAGP makes it easier to obtain a solid electrolyte with higher performance.
Here, the LATP in the present invention is lithium-aluminum-titanium-phosphorus in which the atomic number ratio x of Al constituting it (x of Li _1+x Al _x Ti _2-x (PO ₄ ) ₃ ) is 0 or more and 1 or less Refers to acid compounds. Among these, Li _1.3 Al _0.3 Ti _1.7 (PO ₄ ) ₃ is preferably used because it is widely used.
Furthermore, LATP has lower reactivity with electrodes placed in contact with the solid electrolyte than LAGP in which titanium (Ti) in LATP is replaced with germanium (Ge), so LATP can be used particularly favorably.
The mixing and dispersion are preferably accompanied by stirring with a stirrer or application of ultrasonic waves, and the temperature is preferably room temperature because of ease of handling and low cost.

Through many years of research, the inventors have found that Co is excellent as a sintering aid for LATP. That is, it has been found that when Co is interposed at the interface between LATP powders, sufficient sintering can be performed even at a low temperature, the relative density of the sintered material is increased, and the electrical conductivity is also improved.
In the study, it was also found that a large amount of sintering aid causes deterioration in the performance of LATP as a solid electrolyte, such as reduction in electrical conductivity and relative density.
Therefore, we have been earnestly studying how to uniformly coat the LATP powder with a small amount of Co.
As a result, it is possible to use a solution in which cobalt is dissolved in the form of a salt in a solvent capable of azeotroping with water. Cobalt nitrate hydrate, especially Co(NO ₃ ) _{2.6H 2 O} , can be used as the cobalt nitrate to uniformly coat the LATP powder with an even smaller amount of Co. It was derived by trial and error. This is because the solvent dissolves the nitrate hydrate well, has a low surface tension, and has a low interfacial tension with LATP. It is believed that this is due to the fact that the solution draws evenly even when the liquid film dries.

As for the amounts of the solid electrolyte base material and the cobalt salt added, the ratio B/A of the molar amount B of the cobalt salt to the molar amount A of the solid electrolyte base material is preferably 0.001 or more and 0.1 or less. A sintered body with a high relative density and high electrical conductivity can be obtained by setting the addition amount within this range.

After that, the dispersion is dried to obtain a solid (step S03). Drying methods include heat drying and vacuum drying.

Next, the aggregates of solid matter are pulverized to obtain powder, and then the powder is pressure-molded (step S04). Here, examples of the crushing method include a method using a pestle/mortar and a ball mill. For molding, for example, uniaxial pressure molding, CIP (Cold Isostatic Pressing), sheet molding, or the like can be used, and the pressure can be, for example, 20 MPa or more and 350 MPa or less. The pressurized atmosphere can be air, Ar gas, N ₂ gas, or O ₂ gas, and the air is preferred because it is easy to handle and the cost is low.

The structure of the powder 1 thus produced is shown in FIG.
The powder 1 has a structure in which a solid electrolyte base material 11 made of LTP, LATP, LAGP or the like is covered with a covering material 12 made of cobalt salt. Here, the covering material has a uniform thickness and is dense with few cuts or defects. The thickness of the covering material is preferably controlled in atomic layer order. Specifically, it is preferably 1 atomic layer or more and 10 atomic layers or less, more preferably 1 atomic layer or more and 4 atomic layers or less, and still more preferably 1 atomic layer or more and 2 atomic layers or less. This thickness control can be controlled by the charged amount of the cobalt salt, that is, the ratio B/A of the molar amount B of the cobalt salt to the molar amount A of the solid electrolyte base material. In particular, by using a solvent that can be azeotroped with cobalt nitrate and water, uneven distribution of cobalt is less likely to occur, making it possible to form an ultra-thin film controlled on the order of atomic layers with less unevenness. Become.
When the coating material is such a thin film, dense and sufficient sintering can be performed while reducing the amount of sintering aid, so even if the sintering temperature is low, high relative density and high electrical conductivity can be achieved. It is possible to obtain sufficient performance required as a solid electrolyte such as

Cobalt in the powder has not been subjected to a high temperature treatment to the extent that it diffuses into the solid electrolyte base material until the powder is formed. . As a result, the amount of cobalt can be reduced to a very small amount necessary to function as a sintering aid that increases the compactness of the solid electrolyte, making it possible to produce a solid electrolyte with high performance.

Note that the presence of cobalt means that it is included as a component, and the absence of cobalt means that it is not included as a component. Here, unintentionally mixed impurities are not included. Cobalt is preferably not included as an impurity in the solid electrolyte base material 11, but it is preferable to increase the refining purity for that purpose in consideration of cost performance.

After that, sintering is performed in an environment where oxygen exists, such as air (step S05).
The sintering temperature is preferably 600°C or higher and 800°C or lower, and more preferably 800°C. The time for which the upper limit temperature is maintained can be, for example, 1 Hr or more and 10 Hr or less, and the rate of temperature increase and temperature drop can be, for example, 100° C./Hr or more and 300° C./Hr. Under such sintering conditions, diffusion and the like hardly occur between electrodes arranged in contact with the solid electrolyte, and a secondary battery manufactured using this solid electrolyte has high performance.
Cobalt is oxidized with the involvement of oxygen and becomes a highly efficient sintering aid. A solid electrolyte is provided. It should be noted that sintering in the atmosphere is preferable because it is easy to handle and has a cost advantage.

As shown in FIG. 1, the sintered body 101 thus formed becomes a solid electrolyte composed of a sintered body in which the bulk portion 21 is made of NASICON type LTP and the neck portion 22 contains cobalt oxide. The neck portion 22 contains cobalt oxide other than NASICON LTP, but in a small amount, so that the presence of cobalt oxide causes only a slight deterioration in electrical properties. On the other hand, the bulk portions 21 are sufficiently adhered to each other at the neck portion 22 to form a sintered body 101 with a high relative density.

It should be noted that the present invention is not limited to the above-described embodiments, and the above-described embodiments are examples for explaining the present invention. Any device having the same configuration as the above and exhibiting the same effect is included in the technical scope of the present invention.
In addition, in the above description, solid electrolytes for all-solid secondary batteries have been mentioned, but the application of this solid electrolyte is not limited to all-solid secondary batteries, such as separators, _CO2 sensors, capacitors, It can also be applied to electrochemical devices, recovery of lithium ions in seawater, and the like.

EXAMPLES The present invention will be described in more detail below using examples, but the present invention is not necessarily limited to the following examples.

(Example 1)
First, cobalt nitrate hexahydrate (Wako) is prepared in order to prepare a nitrate that will be a sintering aid, and it is dissolved in a solvent made of commercially available ethanol that has not been dehydrated to produce a nitrate. A solution was prepared (step S01 in FIG. 2). Here, the dissolution was performed at room temperature under air.
Next, a commercially available LATP powder (Toyoshima Seisakusho) having a NASICON structure was prepared as a solid electrolyte base material, and dispersed and stirred in a nitrate solution under the application of ultrasonic waves to prepare a dispersion (slurry) (step S02). The environment is atmospheric pressure and room temperature. Here, the amount of LATP is such that the solid concentration becomes 15 vol% with respect to the ethanol solvent, and the amount of cobalt nitrate hexahydrate is such that the weight ratio of Co to the weight of LATP is from 0.1 to It was weighed using an electronic balance so as to be 2.0 wt % (molar ratio of Co to LATP is 0.006506 to 0.130123).

Thereafter, the resulting slurry was spread flat and uniform in a disposable container, and dried in an oven at 50° C. under atmospheric pressure for 1 hour (step S03). The dried sample was ground in an agate mortar without applying force, and the coarse solid matter generated by the drying treatment was pulverized.
Thereafter, the LATP (Co-LATP) to which Co was added, which is the obtained pulverized product, was filled in a mold and pressed to obtain a compact (step S04). The pressure at that time was set to 100 MPa, and the pressure was applied under atmospheric pressure for 3 minutes.
Finally, the obtained molded body was fired at each temperature (800° C., 1000° C.) under atmospheric pressure to obtain a sintered body (step S05). At this time, the temperature increase rate was 100° C./Hr, the maximum temperature maintenance time was 10 Hr, and the temperature decrease rate was 100° C./Hr.

FIG. 4 shows the sintering temperature dependence of the relative density of Co-LATP when the parameter is the amount of Co added and the sintering temperature is set at two levels of 800° C. and 1000° C. FIG. Here, relative density was measured as bulk density (volume/weight). The figure also shows the relative density before sintering (this data is shown at 25°C).
At a sintering temperature of 800° C., all LATP sintered bodies to which Co was added had higher relative densities than LATP to which Co was not added, indicating that the addition of Co contributed to the improvement of the relative density.

FIG. 5 shows the relative density of the sintered body (Co-LATP) produced by the above steps in the air at a sintering temperature of 800° C. and the dependence of the amount of Co added. By adding 0.1 wt% Co (molar ratio to LATP is 0.006506), the relative density is improved by about 20% from about 59% when Co is not added to about 71%, and Co is added at 0.2 wt. % to 2.0 wt% (molar ratio to LATP 0.013012 to 0.130123), the relative density exceeds 75%, and 0.3 wt% Co (molar ratio to LATP 0.019518) is added. It can be seen that the relative density is about 80% of the maximum. When 10 wt% of Co was added (0.650617 molar ratio to LATP), the relative density was 54.54% and the sintering shrinkage was -10.23%. When Co was not added, the relative density was 58.63% and the sintering shrinkage rate was -6.84%. Addition of a large amount of Co such as 10 wt% did not produce a significant effect in improving the relative density.

FIG. 6 shows the dependence of the relative density and the amount of Co added for samples fabricated under the same conditions as in FIG. 5 except that the sintering atmosphere was changed from air to Ar gas. Under sintering conditions in which oxygen does not intervene, unlike sintering in the presence of oxygen, addition of Co only slightly improves the relative density. This indicates that oxidation of Co greatly contributes to the mechanism of relative density improvement. From this result, it can be seen that the presence of oxygen is preferable as the sintering environment.

FIG. 7 is a SEM photograph of the fracture surface structure of Co-free LATP sintered at 800° C. in the atmosphere, and FIG. It is a photograph. 7A and 7B have different magnifications, with FIG. 7A being 10 times the magnification of FIG. 7B, and FIG. 7A and FIG. 8 being the same magnification.
From this result, the grain growth of Co-added LATP was not accelerated more than that of Co-unadded LATP, and formation of neck portions between grains due to the addition of Co was recognized.

FIG. 9 is a SEM photograph of the fracture surface structure of Co-LATP sintered at 1000° C. in air. Sintering progressed more than Co-LATP sintered at 800° C. shown in FIG. 8, and a densified structure was observed.

FIG. 10 shows the electrical conductivity measurement results of Co-LATP sintered at 800° C. in air.
Up to 0.5 wt % Co addition (molar ratio to LATP 0.032531), the electrical conductivity improved as the addition amount increased. Although the electrical conductivity decreases when the amount of Co added is 1.0 wt % or more (molar ratio to LATP is 0.065062), the electrical conductivity is equal to or higher than the electrical conductivity when Co is not added.
It is considered that the increase in density mainly contributes to the increase in electrical conductivity when the amount of Co added is up to 0.5 wt %. It is considered that when the amount of Co added is 1.0 wt % or more, the influence of the impurity phase becomes remarkable, and the electrical conductivity turns to decrease.

FIG. 11 shows the electrical conductivity measurement results of Co-LATP sintered at 1000° C. in air.
The electrical conductivity decreased as the amount of Co added increased. 1000° C. is the temperature at which LATP to which Co is not added is sufficiently sintered, and in all the samples, it is considered that the difference in the amount of impurity phase produced due to the addition of Co is reflected in the electrical conductivity of all the samples due to the difference in density.

According to the present invention, a NASICON-type LTP solid electrolyte with high density and excellent electrical conductivity, an easily sinterable powder suitable for its production, and a density Provided is a method for producing an easily sinterable NASICON-type LTP solid electrolyte having a high thermal conductivity and excellent electrical conductivity. By using this solid electrolyte, the powder for producing the solid electrolyte, and the method for producing the solid electrolyte, lithium-ion all-solid-state secondary batteries with excellent mechanical and electrical properties can be supplied with high productivity and low cost. Regardless, it is thought that it will contribute to the industry.

1: powder 11: solid electrolyte matrix (LATP)
12: Cobalt-containing coating material 21: Bulk part 22: Neck part 101: Sintered body

Claims (18)

The bulk part is made of NASICON type LTP,
A solid electrolyte consisting of a sintered body with cobalt oxide present in the neck. 2. The solid electrolyte according to claim 1, wherein the bulk portion comprises one or more electrolytes selected from the group consisting of NASICON-type LATP and NASICON-type LAGP. 2. The solid electrolyte of claim 1, wherein the bulk portion consists of NASICON-type LATP. A powder comprising a solid electrolyte base material and a coating material covering the surface of the solid electrolyte base material,
The solid electrolyte base material is made of NASICON type LTP,
The coating material contains cobalt (Co) ions,
A powder for producing a solid electrolyte, wherein the thickness of the coating material is on the order of an atomic layer. 5. The powder according to claim 4, wherein the solid electrolyte base material comprises one or more selected from the group consisting of NASICON-type LATP and NASICON-type LAGP. 6. The powder of claim 5, wherein the solid electrolyte matrix comprises NASICON type LATP. 7. Powder according to any one of claims 4 to 6, wherein cobalt ions are contained only in the coating material. Powder according to any one of claims 4 to 7, wherein the coating material comprises cobalt nitrate. dissolving a cobalt salt in a solvent capable of azeotroping with water to form a solution;
preparing a dispersion (slurry) by adding and dispersing a solid electrolyte base material made of NASICON type LTP into the solution;
drying the dispersion to obtain a solid;
pulverizing the solid to obtain a powder containing cobalt ions;
obtaining a molded body by molding the powder;
A method for producing a solid electrolyte, wherein the molded body is sintered in an environment in which oxygen is present. 10. The method for producing a solid electrolyte according to claim 9, wherein said solid electrolyte base material comprises one or more selected from the group consisting of NASICON-type LATP and NASICON-type LAGP. 10. The method for producing a solid electrolyte according to claim 9, wherein said solid electrolyte base material is NASICON type LATP. 12. The method for producing a solid electrolyte according to claim 9, wherein said cobalt salt is cobalt nitrate. 13. The method for producing a solid electrolyte according to claim 12, wherein the cobalt nitrate is Co _{( NO3} ) _2.6H2O . 14. The method for producing a solid electrolyte according to any one of claims 9 to 13, wherein said solvent contains one or more selected from the group consisting of methanol, ethanol and propanol. 15. The method for producing a solid electrolyte according to claim 14, wherein said solvent is ethanol. 16. The method for producing a solid electrolyte according to any one of claims 9 to 15, wherein said sintering is performed in an atmospheric environment. The method for producing a solid electrolyte according to any one of claims 9 to 16, wherein the sintering temperature is 600°C or higher and 800°C or lower. The solid electrolyte according to any one of claims 9 to 17, wherein a ratio B/A of the molar amount B of the cobalt salt to the molar amount A of the solid electrolyte base material is 0.001 or more and 0.1 or less. Production method.

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