JP6808010B2 - Electrochemical cell - Google Patents

Description

The present invention relates to an electrochemical cell.

In recent years, fuel cells, which are a type of electrochemical cell, have been attracting attention from the viewpoints of environmental problems and effective use of energy resources. A fuel cell generally has a fuel electrode, an air electrode, and a solid electrolyte layer arranged between the fuel electrode and the air electrode.

The air electrode can be composed of a perovskite-type oxide such as (La, Sr) (Co, Fe) O ₃ (lanternstrontium cobalt ferrite) (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2006-32132

However, the output of the fuel cell may decrease as the power generation is repeated. The present inventors have stated that one of the causes of the decrease in output is the deterioration of the air electrode, and this deterioration of the air electrode is alleviated by introducing (La, Sr) ₂ CoO ₄ into the air electrode. I found a new one.

The present invention is based on such new findings, and an object of the present invention is to provide an electrochemical cell capable of suppressing a decrease in output.

The electrochemical cell according to the present invention includes a fuel electrode, an air electrode, and a solid electrolyte layer arranged between the fuel electrode and the air electrode. The air electrode is represented by the general formula ABO ₃ and contains a perovskite oxide containing at least one of La and Sr at the A site (excluding (La, Sr) ₂ CoO ₄ ) and (La, Sr) ₂ CoO. Includes ₄ and. The area occupancy of (La, Sr) ₂ CoO ₄ in the cross section of the air electrode is 0.5% or more.
Electrochemical cell.

According to the present invention, it is possible to provide an electrochemical cell capable of suppressing a decrease in output.

Sectional drawing which shows the structure of the fuel cell which concerns on embodiment

(Structure of fuel cell 10)
As an example of the electrochemical cell according to the present embodiment, the configuration of the fuel cell 10 will be described with reference to the drawings. The fuel cell 10 is a so-called solid oxide fuel cell (SOFC: Solid Oxide Fuel Cell). The fuel cell 10 can take various forms such as a vertical stripe type, a horizontal stripe type, a flat plate type, and a cylindrical type.

FIG. 1 is a cross-sectional view schematically showing the configuration of the fuel cell 10. The fuel cell 10 includes a fuel electrode 20, a solid electrolyte layer 30, a barrier layer 40, and an air electrode 50.

The fuel electrode 20 functions as an anode of the fuel cell 10. As shown in FIG. 1, the fuel electrode 20 has a fuel electrode current collecting layer 21 and a fuel electrode active layer 22.

The fuel electrode current collector layer 21 is a porous body having excellent gas permeability. As the material constituting the fuel electrode current collecting layer 21, the material conventionally used for the fuel electrode current collecting layer of SOFC can be used, and for example, it is stabilized with NiO (nickel oxide) -8YSZ (8 mol% yttria). Zirconia) and NiO-Y ₂ O ₃ (yttria). When the fuel electrode current collecting layer 21 contains NiO, at least a part of NiO may be reduced to Ni during the operation of the fuel cell 10. The thickness of the fuel electrode current collector layer 21 can be, for example, 0.1 mm to 5.0 mm.

The fuel electrode active layer 22 is arranged on the fuel electrode current collector layer 21. The fuel electrode active layer 22 is a more dense porous body than the fuel electrode current collector layer 21. As a material constituting the fuel electrode active layer 22, a material conventionally used for the fuel electrode active layer of SOFC can be used, and examples thereof include NiO-8YSZ. When the fuel electrode active layer 22 contains NiO, at least a part of NiO may be reduced to Ni during the operation of the fuel cell 10. The thickness of the fuel polar active layer 22 can be, for example, 5.0 μm to 30 μm.

The solid electrolyte layer 30 is arranged between the fuel electrode 20 and the air electrode 50. In the present embodiment, the solid electrolyte layer 30 is sandwiched between the fuel electrode 20 and the barrier layer 40. The solid electrolyte layer 30 allows the oxide ions generated at the air electrode 50 to permeate to the fuel electrode 20 side. The solid electrolyte layer 30 is denser than the fuel electrode 20 and the air electrode 50.

The solid electrolyte layer 30 may contain ZrO ₂ (zirconia) as a main component. In addition to zirconia, the solid electrolyte layer 30 may contain additives such as Y ₂ O ₃ (yttria) and / or Sc ₂ O ₃ (scandium oxide). These additives function as stabilizers. In the solid electrolyte layer 30, the mol composition ratio of the stabilizer to zirconia (stabilizer: zirconia) can be about 3:97 to 20:80. Therefore, examples of the material of the solid electrolyte layer 30 include 3YSZ, 8YSZ, 10YSZ, ScSZ (scandia-stabilized zirconia) and the like. The thickness of the solid electrolyte layer 30 can be, for example, 3 μm to 30 μm.

In the present embodiment, the phrase "the composition X contains the substance Y as a main component" means that the substance Y accounts for 70% by weight or more of the entire composition X.

The barrier layer 40 is arranged between the solid electrolyte layer 30 and the air electrode 50. The barrier layer 40 suppresses the formation of a high resistance layer between the solid electrolyte layer 30 and the air electrode 50. The barrier layer 40 is denser than the fuel electrode 20 and the air electrode 50. The barrier layer 40 can be mainly composed of a ceria-based material such as GDC (gadolinium-doped ceria) or SDC (samarium-doped ceria). The thickness of the barrier layer 40 can be, for example, 3 μm to 20 μm.

The air pole 50 is arranged on the barrier layer 40. The air electrode 50 is located on the opposite side of the fuel electrode 20 with respect to the solid electrolyte layer 30. The air electrode 50 functions as a cathode of the fuel cell 10. The air electrode 50 is a porous body. The porosity of the air electrode 50 is not particularly limited, but can be 20% to 60%. The porosity of the air electrode 50 can be measured by the Archimedes method. The thickness of the air electrode 50 is not particularly limited, but can be 2 μm to 100 μm.

The air electrode 50 is represented by the general formula ABO ₃ , and contains a perovskite-type oxide containing at least one of La and Sr in the A site as a main component. Examples of such perovskite-type oxides include LSCF (lanternstrontium cobalt ferrite: (La, Sr) (Co, Fe) O ₃ ), LSF (lantern strontium ferrite: (La, Sr) FeO ₃ ), and LSC ( Lantern Strontium Cobaltite: (La, Sr) CoO ₃ ), LNF (Lantern Nickel Ferrite: La (Ni, Fe) O ₃ ), and SSC (Samarium Strontium Cobaltite: (Sm, Sr) CoO ₃ ) One type or a combination thereof can be used, but the present invention is not limited to these.

However, in the present specification, it is assumed that the perovskite-type oxide containing the air electrode 50 as a main component does not contain (La, Sr) ₂ CoO ₄ .

In the cross section of the air electrode 50, the area occupancy of the perovskite-type oxide containing at least one of La and Sr at the A site can be 84.0% or more and 99.3% or less. The method for calculating the area occupancy of the perovskite-type oxide containing at least one of La and Sr in the A site will be described later.

The air electrode 50 includes (La, Sr) ₂ CoO ₄ . (La, Sr) ₂ CoO ₄ can be expressed as La _2-x Sr _x CoO ₄ (0 ≦ x ≦ 2). Therefore, (La, Sr) ₂ CoO ₄ includes La ₂ CoO ₄ , Sr ₂ CoO ₄ , La _1.5 Sr _0.5 CoO ₄ , La _0.5 Sr _1.5 CoO _{4, and the} like. Not limited to this.

In the cross section of the air electrode 50, the area occupancy of (La, Sr) ₂ CoO ₄ is 0.5% or more. As a result, the reaction activity of the air electrode 50 can be improved, so that the deterioration of the air electrode 50 can be suppressed. (La, Sr) _{2 The} method of calculating the area occupancy of CoO ₄ will be described later.

In the cross section of the air electrode 50, the area occupancy of (La, Sr) ₂ CoO ₄ is preferably 5.5% or less. As a result, it is possible to suppress the formation of regions having different conductivity in the air electrode 50, so that it is possible to reduce the local deterioration of the air electrode 50 due to the current density distribution generated in the air electrode 50 during energization. As a result, it is possible to prevent the output of the fuel cell 10 from decreasing during energization.

In the cross section of the air electrode 50, the average circle-equivalent diameter of (La, Sr) ₂ CoO ₄ is not particularly limited, but is preferably 0.05 μm or more and 2.0 μm or less. As a result, it is possible to further prevent the output of the fuel cell 10 from decreasing during energization. The average circle equivalent diameter is an arithmetic mean value of the diameter of a circle having the same area as each of 50 (La, Sr) ₂ CoO ₄ randomly selected from an FE-SEM image (magnification 10000 times).

The air electrode 50 preferably further contains (Co, Fe) ₃ O ₄ . (Co, Fe) ₃ O ₄ has a spinel-type crystal structure. (Co, Fe) ₃ O ₄ can be expressed as Co _3-y F _y O ₄ (0 <y <3). Therefore, (Co, _Fe) in 3 _{O 4 is} etc. _{Co 2 FeO 4, Co 1.5 Fe} 1.5 O 4 and CoFe ₂ O _4, it is not limited thereto.

In the cross section of the air electrode 50, the area occupancy of (Co, Fe) ₃ O ₄ is preferably 0.2% or more. As a result, the sinterability of the air electrode 50 is improved, so that the porous skeleton structure of the air electrode 50 can be strengthened. As a result, it is possible to suppress the occurrence of cracks in the air electrode 50. The method of calculating the area occupancy of (Co, Fe) ₃ O ₄ will be described later.

In the cross section of the air electrode 50, the area occupancy of (Co, Fe) ₃ O ₄ is preferably 10.5% or less. As a result, the inactive portion of the air electrode 50 is reduced, so that it is possible to suppress a decrease in the output of the fuel cell 10 during energization.

In the cross section of the air electrode 50, the average equivalent circle diameter of (Co, Fe) ₃ O ₄ is not particularly limited, but is preferably 0.05 μm or more and 0.5 μm or less. As a result, it is possible to further prevent the output of the fuel cell 10 from decreasing during energization. The average equivalent circle diameter is the arithmetic average of the diameter circle having an 50 (Co, _Fe) 3 _{O 4} same area as each of the randomly selected from FE-SEM image (magnification 10,000 times).

(Calculation method of area occupancy)
A method for calculating the area occupancy of each of a perovskite-type oxide containing at least one of La and Sr at the A site, (La, Sr) ₂ CoO ₄ , and (Co, Fe) ₃ O _{4 in} a cross section of the air electrode 50. Will be described.

First, after the cross section of the air electrode 50 is precision mechanically polished, an ion milling process is performed by IM4000 of Hitachi High-Technologies Corporation.

Next, an SEM image obtained by magnifying the cross section of the air electrode 50 at a magnification of 10000 times is acquired by an FE-SEM (Field Emission Scanning Electron Microscope) using an in-lens secondary electron detector. ..

Next, by classifying the brightness of the SEM image into 256 gradations, the difference in brightness between the main phase, the sub-phase, and the gas phase is quantified. For example, the main phase can be displayed in light gray, the subphase can be displayed in dark gray, and the pores can be displayed in black. The main phase and the sub-phase are solid phases. Subphase is a (Co, _Fe) 3 _{O 4} phase. The main phase includes a perovskite-type oxide phase containing at least one of La and Sr at the A site and a (La, Sr) ₂ CoO ₄ phase.

Next, EDX (Energy Dispersive X-ray Spectroscopy) is used to acquire the EDX spectrum at the position of the main phase. Then, the element existing at the position of the main phase is identified by semi-quantitative analysis of the EDX spectrum. Thereby, on the SEM image, the main phase is divided into a region of perovskite-type oxide containing at least one of La and Sr at the A site and a region of (La, Sr) ₂ CoO ₄ .

Next, (La, Sr) ₂ CoO ₄ and (Co, Fe) ₃ O ₄ were highlighted by image analysis of the SEM image using the image analysis software HALCON manufactured by MVTec (Germany). Acquire the analysis image.

Next, the area occupancy of (La, Sr) ₂ CoO ₄ can be obtained by dividing the total area of (La, Sr) ₂ CoO ₄ in the analysis image by the total area of the solid phase.

Similarly, the area occupancy of (Co, Fe) ₃ O ₄ can be obtained by dividing the total area of (Co, Fe) ₃ O ₄ in the analysis image by the total area of the solid phase.

Furthermore, the A site is divided by the total area of the solid phase minus the total area of (La, Sr) ₂ CoO _{4 and} the total area of (Co, Fe) ₃ O _{4 from} the total area of the solid phase. The area occupancy of the perovskite-type oxide containing at least one of La and Sr is obtained.

(Air electrode material)
The powder material used for producing the air electrode 50 (hereinafter referred to as “air electrode material”) includes a perovskite-type oxide powder represented by the general formula ABO ₃ and (La, Sr) ₂ CoO ₄ powder. Mixed materials can be used. If desired, (Co, Fe) ₃ O ₄ powder may be mixed with the air electrode material.

The amount of (La, Sr) ₂ CoO ₄ added to the air electrode material is 0.45% by weight or more. As a result, the area occupancy of (La, Sr) ₂ CoO ₄ in the cross section of the air electrode 50 can be set to 0.5% or more, so that deterioration of the air electrode 50 can be suppressed as described above.

The amount of (La, Sr) ₂ CoO ₄ added to the air electrode material is preferably 4.95% by weight or less. As a result, the area occupancy of (La, Sr) ₂ CoO ₄ in the cross section of the air electrode 50 can be reduced to 5.5% or less. Therefore, as described above, the current density generated by the difference in conductivity during energization. Since the local deterioration of the air electrode 50 due to the distribution can be reduced, it is possible to prevent the output of the fuel cell 10 from decreasing during energization.

The amount of (Co, Fe) ₃ O ₄ added to the air electrode material is preferably 0.18% by weight or more. As a result, the area occupancy of (Co, Fe) ₃ O ₄ in the cross section of the air electrode 50 can be set to 0.2% or more, so that cracks can be suppressed from occurring in the air electrode 50 as described above.

The amount of (Co, Fe) ₃ O ₄ added to the air electrode material is preferably 9.45% by weight or less. As a result, the area occupancy of (Co, Fe) ₃ O ₄ in the cross section of the air electrode 50 can be reduced to 10.5% or less, so that the inactive portion of the air electrode 50 is reduced as described above. It is possible to prevent the output of the fuel cell 10 from decreasing during energization.

By adjusting the particle size and specific surface area of the (La, Sr) ₂ CoO ₄ powder, the area occupancy of (La, Sr) ₂ CoO ₄ in the cross section of the air electrode 50 can be adjusted.

Similarly, by adjusting the particle size and specific surface area of the (Co, Fe) ₃ O ₄ powder, the area occupancy of (Co, Fe) ₃ O ₄ in the cross section of the air electrode 50 can be adjusted.

(Manufacturing method of fuel cell 10)
Next, an example of a method for manufacturing the fuel cell 10 will be described. In the following description, "molded article" means a member before firing.

First, a binder (for example, polyvinyl alcohol) is added to a mixture of a powder for a fuel electrode current collector layer (for example, NiO powder and YSZ powder) and a pore-forming agent (for example, PMMA (polymethyl methacrylate resin)) to add a fuel electrode. Prepare a slurry for the current collector layer. Next, the fuel electrode current collector layer slurry is dried and granulated with a spray dryer to obtain a fuel electrode current collector layer powder. Next, a molded body of the fuel electrode current collecting layer 21 is formed by molding the fuel electrode powder by the die press molding method. At this time, the tape laminating method may be used instead of the die press molding method.

Next, a binder (for example, polyvinyl alcohol) is added to a mixture of a fuel polar active layer powder (for example, NiO powder and YSZ powder) and a pore-forming agent (for example, PMMA) to prepare a fuel polar active layer slurry. .. Next, the fuel electrode active layer slurry is printed on the molded body of the fuel electrode current collecting layer 21 by a printing method to form the molded body of the fuel electrode active layer 22. As a result, a molded body of the fuel electrode 20 is formed. At this time, a tape laminating method, a coating method, or the like may be used instead of the printing method.

Next, a slurry for the solid electrolyte layer is prepared by mixing a mixture of water and a binder with the powder for the solid electrolyte layer (for example, YSZ powder) with a ball mill. Next, the solid electrolyte layer slurry is applied and dried on the molded body of the fuel electrode 20 to form the molded body of the solid electrolyte layer 30. At this time, a tape laminating method, a printing method, or the like may be used instead of the coating method.

Next, a barrier layer slurry is prepared by mixing a mixture of water and a binder with a barrier layer powder (for example, GDC powder) with a ball mill. Next, the slurry for the barrier layer is applied and dried on the molded body of the solid electrolyte layer 30 to form the molded body of the barrier layer 40. At this time, a tape laminating method, a printing method, or the like may be used instead of the coating method.

Next, by co-firing (1300 to 1600 ° C., 2 to 20 hours) the laminate of the molded bodies of the fuel electrode 20, the solid electrolyte layer 30, and the barrier layer 40, the fuel electrode 20, the solid electrolyte layer 30, and the barrier are co-fired. A co-fired body of layer 40 is formed.

Next, an air electrode slurry is prepared by mixing the above-mentioned air electrode material, water, and a binder with a ball mill. Next, the air electrode slurry is applied and dried on the barrier layer 40 to form a molded body of the air electrode 50.

Next, the air electrode 50 is formed on the barrier layer 40 by firing the molded body of the air electrode 50 in an electric furnace (oxygen-containing atmosphere) (1000 ° C to 1100 ° C, 1 hour to 10 hours).

(Modification example)
Although the embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made without departing from the spirit of the present invention.

In the above embodiment, the fuel cells 10 and 11 have been described as an example of the electrochemical cell, but the present invention can be applied to an electrochemical cell such as a solid oxide fuel cell as well as a fuel cell.

In the above embodiment, the fuel cell 10 includes a fuel electrode 20, a solid electrolyte layer 30, a barrier layer 40, and an air electrode 50, but is not limited thereto. The fuel cell 10 may include at least a fuel electrode 20, a solid electrolyte layer 30, and an air electrode 50. Therefore, the fuel cell 10 may not be provided with the barrier layer 40, and may be provided between the fuel electrode 20 and the solid electrolyte layer 30, or between the solid electrolyte layer 30 and the air electrodes 50 and 51. Layers may be intercalated.

Examples of the cell according to the present invention will be described below, but the present invention is not limited to the examples described below.

(Preparation of Samples No. 1 to No. 31)
As follows, sample No. 1-No. The fuel cell according to 31 was manufactured.

First, a fuel electrode current collecting layer (NiO: 8YSZ = 50: 50 (Ni volume% conversion)) having a thickness of 500 μm is formed by a mold press molding method, and a fuel electrode active layer (NiO: 8YSZ =) having a thickness of 20 μm is formed on the fuel electrode current collecting layer (NiO: 8YSZ = 50: 50 (Ni volume% conversion)). 45:55 (Ni volume% conversion)) was formed by the printing method.

Next, molded bodies of the 8YSZ layer and the GDC layer were sequentially formed on the fuel polar active layer by a coating method and co-fired (1400 ° C., 2 hours).

Next, (La, Sr) ₂ CoO ₄ powder with respect to the main component powder for air electrode shown in Table 1 (perovskite type oxide represented by the general formula ABO ₃ and containing at least one of La and Sr in the A site). The air electrode material mixed with the above was prepared. In addition, sample No. (Co, Fe) ₃ O ₄ powder was also mixed with the air electrode materials of 4 to 15, 19 to 23, 27 to 31.

Next, the air electrode material, water, and PVA were mixed in a ball mill for 24 hours to prepare a slurry for the air electrode material.

Next, the air electrode slurry was applied and dried on the GDC layer of the co-fired body to form an air electrode molded body.

Next, the air electrode was formed by firing the molded body of the air electrode in an electric furnace (oxygen-containing atmosphere, 1000 ° C.) for 1 hour.

(Measurement of area occupancy)
First, the cross section of the air electrode was precision mechanically polished, and then ion milling was performed by IM4000 of Hitachi High-Technologies Corporation.

Next, an SEM image in which the cross section of the air electrode was magnified at a magnification of 10000 times was acquired by FE-SEM using an in-lens secondary electron detector.

Next, by classifying the brightness of the SEM image into 256 gradations, the difference in brightness between the main phase, the sub-phase, and the gas phase was quantified. Specifically, the main phase was displayed in light gray, the sub-phase was displayed in dark gray, and the pores were displayed in black.

Next, using EDX, the EDX spectrum at the position of the main phase is acquired, and the EDX spectrum is semi-quantitatively analyzed, so that the main phase is contained on the SEM image, and the A site contains at least one of La and Sr. It was divided into a type oxide region and (La, Sr) ₂ CoO ₄ .

Next, the SEM image was image-analyzed using the image analysis software HALCON to obtain an analysis image in which (La, Sr) ₂ CoO ₄ and (Co, Fe) ₃ O ₄ were highlighted.

Next, the area occupancy of (La, Sr) ₂ CoO ₄ was determined by dividing the total area of (La, Sr) ₂ CoO ₄ in the analysis image by the total area of the solid phase.

Similarly, the area occupancy of (Co, Fe) ₃ O ₄ was determined by dividing the total area of (Co, Fe) ₃ O ₄ in the analysis image by the total area of the solid phase.

Furthermore, the A site is divided by the total area of the solid phase minus the total area of (La, Sr) ₂ CoO _{4 and} the total area of (Co, Fe) ₃ O _{4 from} the total area of the solid phase. The area occupancy of the perovskite-type oxide containing at least one of La and Sr was determined.

(Output measurement and crack observation)
The temperature was raised to 750 ° C. while supplying nitrogen gas to the fuel electrode side and air to the air electrode side of each sample, and when the temperature reached 750 ° C., hydrogen gas was supplied to the fuel electrode for 3 hours for reduction treatment.

Next, the rated current density was set to 0.2 A / cm ^2, and power was generated for 1000 hours while measuring the cell voltage. Then, the voltage drop rate per 1000 hours was calculated as the deterioration rate. In Table 1, a sample having a deterioration rate of 0.75% or less is evaluated as "A", a sample having a deterioration rate of more than 0.75% and 0.85% or less is evaluated as "B", and the deterioration rate is 0. A sample with a deterioration rate of more than 85% and 1.0% or less is evaluated as "C", a sample with a deterioration rate of more than 1.0% and 1.2% or less is evaluated as "D", and a deterioration rate of more than 1.2%. The sample is rated as "E".

Further, after generating electricity for 1000 hours, the presence or absence of cracks in the air electrode near the interface with the barrier layer was observed by observing the cross section of the air electrode with an electron microscope. In Table 1, "Yes" is displayed for samples in which cracks having a length of more than 5 μm are observed, and "Yes (minor)" is displayed in samples in which cracks with a length of 5 μm or less are observed, and no cracks are observed. "None" is displayed on the sample.

As shown in Table 1, the sample Nos. (La, Sr) ₂ CoO _{4 had} an area occupancy of 0.5% or more. In 2, 3, 6 to 15, 17 to 23, 25 to 26, 28 to 31, the sample No. in which the area occupancy of (La, Sr) ₂ CoO ₄ was less than 0.5%. Compared with 1,4 to 5,16,24,27, the deterioration rate of the air electrode could be suppressed. This results were obtained is (La, Sr) by the addition of ₂ CoO _4, since is to improve the reactivity of the air electrode. In addition, sample No. The amount of (La, Sr) ₂ CoO ₄ added to the air electrode materials used in _{2, 3} , 6 to 15, 17 to 23, 25 to 26, 28 to 31 was 0.45% by weight or more.

Further, among the samples in which the area occupancy of (La, Sr) ₂ CoO ₄ was 0.5% or more, the sample No. in which the area occupancy of (La, Sr) ₂ CoO ₄ was 5.5% or less. In 2, 6 to 13, 17, 19 to 21, 25, 28 to 29, the deterioration rate of the air electrode could be further suppressed. This result may be because, (La, Sr) by a current density distribution occurring during energization is reduced by reducing the amount of ₂ CoO _4, it can suppress the local degradation of the air electrode This is because the. In addition, sample No. The amount of (La, Sr) ₂ CoO ₄ added to the air electrode materials used in 2, 6 to 13, 17, 19 to 21, 25, 28 to 29 was 4.95% by weight or less.

Further, among the samples in which the area occupancy of (La, Sr) ₂ CoO ₄ was 0.5% or more, the sample No. in which the area occupancy of (Co, Fe) ₃ O ₄ was 0.2% or more. At 7 to 15, 20 to 23, 28 to 31, it was possible to suppress the occurrence of cracks in the air electrode. Such a result was obtained because the porous skeleton structure of the air electrode could be strengthened by the addition of (Co, Fe) ₃ O ₄ . In addition, sample No. The amount of (Co, Fe) ₃ O ₄ added to the air electrode materials used in 7 to 15, 20 to 23, 28 to 31 was 0.18% by weight or more.

In addition, sample No. 11 and sample No. Comparison with 12 and 13, sample No. 14 and sample No. Comparison with 15, sample No. 18, 22 and sample No. Comparison with 23, sample No. 26, 30 and sample No. From the comparison with 31, it was found that the deterioration rate of the air electrode can be further suppressed by setting the area occupancy rate of (Co, Fe) ₃ O ₄ to 10.5% or less. This result may be because, since (Co, Fe) by suppressing the amount of ₃ O _4, it was possible to reduce the inactive portion of the air electrode. The area occupancy of (Co, Fe) ₃ O ₄ was 10.5% or less, and the amount of (Co, Fe) ₃ O ₄ added to the air electrode material used for the sample was 9.45% by weight or less. It was.

Conventionally, SrSO ₄ , Co ₃ O ₄ , CoO, SrO and the like are known as substances that may deteriorate the air electrode, but the above effect can be obtained even if the air electrode contains these substances. This has been confirmed experimentally.

10,11 Fuel cell 20 Fuel pole 21 Fuel pole current collector layer 22 Fuel pole active layer 30 Solid electrolyte layer 40 Barrier layer 50,60 Air pole 51,61 First layer 52,62 Second layer

Claims (3)

With the fuel pole,
With the air pole
A solid electrolyte layer arranged between the fuel electrode and the air electrode,
With
The air electrode is represented by the general formula ABO ₃ , and contains a perovskite-type oxide containing at least one of La and Sr at the A site, (La, Sr) ₂ CoO ₄ , and (Co, Fe) ₃ O ₄ . Including
The area occupancy of (La, Sr) ₂ CoO ₄ in the cross section of the air electrode is 0.5% or more.
The area occupancy of (Co, Fe) ₃ O ₄ in the cross section of the air electrode is 0.2% or more.
Electrochemical cell. The area occupancy of (La, Sr) ₂ CoO ₄ in the cross section of the air electrode is 5.5% or less.
The electrochemical cell according to claim 1. The area occupancy of (Co, Fe) ₃ O ₄ in the cross section of the air electrode is 10.5% or less.
The electrochemical cell according to claim 1 or 2.

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