RU2791726C1 - Solid oxide electrolyte material with proton conductivity based on neodymium barium indate - Google Patents

Abstract

FIELD: materials for electrochemical devices.

SUBSTANCE: invention relates to the production of materials for electrochemical devices, namely, solid oxide electrolyte materials with proton conductivity based on barium-neodymium indate (BaNd₂In₂O₇), which can be used as an electrolyte material in proton-conducting solid oxide fuel cells used to obtain electricity. The material is barium-neodymium indate doped with strontium and having the following composition: BaNd_1.9Sr_0.1In₂O_6.95.

EFFECT: increasing the proton conductivity of the material based on barium-neodymium indate.

1 cl, 4 dwg

Description

The invention relates to the production of materials for electrochemical devices, namely, to solid oxide electrolyte materials with proton conductivity based on barium-neodymium indate (BaNd ₂ In ₂ O ₇ ), which can be used as an electrolyte material in proton-conducting solid oxide fuel cells used for receiving electricity.

Most of the known materials, characterized by proton conductivity combined with low chemical resistance, have a perovskite structure or a derivative of it. Such materials include, for example, a proton-conducting electrolyte material based on BaCeO ₃ [Ryu KH, Haile SM Chemical stability and proton conductivity of doped BaCeO ₃ -BaZrO ₃ solid solutions // Solid State Ionics. – 1999. V. 125, P. 355–367. https://doi.org/10.1016/S0167-2738(99)00196-4]. This material has a low chemical resistance to carbon dioxide, which reduces its effectiveness when working in fuel cells.

Chemical compounds with a structure different from that of perovskite can be considered as promising new proton conductors. As such, barium-neodymium indate is known, characterized by a block-layer structure of Ruddlesden-Popper. This material is a proton conductor at temperatures below 450 ^o C and atmospheric humidity pH ₂ O = 2⋅10 ⁻² atm, however, the values of proton conductivity for it are relatively low and at 450 ^o C are 1.8⋅10 ⁻⁵ Ω ⁻¹ ⋅ cm ^-1 .

The object of the present invention is to increase the proton conductivity of a neodymium barium indate material that can be used as an electrolyte in a solid oxide fuel cell.

For this, a solid oxide electrolyte material with proton conductivity based on barium-neodymium indate is proposed, which is a barium-neodymium indate doped with strontium, having the composition: BaNd _1.9 Sr _0.1 In ₂ O _6.95 .

With the introduction of strontium cations, oxygen vacancies are formed in the neodymium sublattice, as a result of which the values of oxygen-ion and proton conductivity increase.

The resulting barium-neodymium indate doped with strontium is characterized by high values of proton conductivity with the dominance of proton transport at T < 450 ^o C and pH ₂ O = 2⋅10 ⁻² atm, which are necessary conditions for using the material as an electrolyte of a proton-conducting fuel cell.

A new technical result achieved by the claimed invention is to create a material based on barium-neodymium indate, characterized by high values of proton conductivity at T < 450 ^o C and pH ₂ O = 2⋅10 ⁻² atm.

The invention is illustrated in the drawings, where in Fig. 1 shows the diffraction pattern of a sample of BaNd _1.9 Sr _0.1 In ₂ O _6.95 material. In FIG. 2 and 3 – temperature dependences of the electrical conductivity of the BaNd _1.9 Sr _0.1 In ₂ O _6.95 material sample in comparison with the BaNd ₂ In ₂ O ₇ material in dry (pH ₂ O = 3.5⋅10 ⁻⁵ atm) and wet (pH ₂ O = 2∙ 10 ⁻² atm) atmospheres, respectively. In FIG. 4 – temperature dependences of the proton conductivity of the BaNd _1.9 Sr _0.1 In ₂ O _6.95 sample in comparison with the BaNd ₂ In ₂ O ₇ material.

The material BaNd _1.9 Sr _0.1 In ₂ O _6.95 was obtained by the solid-phase synthesis method known from [Caldes M., Michel C., Rouillon T., Hervieu M., Raveau B. Novel indates Ln ₂ BaIn ₂ O ₇ , n = 2 members of the Ruddlesden– Popper family (Ln = La, Nd) // Journal of Materials Chemistry. - V. 12. - P. 473-476]. Conducted X-ray phase analysis of a sample of the material BaLa _1.9 Ca _0.1 In ₂ O _6.95 (Figure 1) on a diffractometer Bruker Advance D8 in СuКα radiation at a tube voltage of 40 kV and a current of 40 mA. The survey was carried out in the interval 2θ = 20°–80° with a step of 0.05°θ and an exposure of 1 second per point. The analysis showed that the BaNd _1.9 Sr _0.1 In ₂ O _6.95 material is single-phase and is characterized by tetragonal symmetry.

The electrical conductivity of the obtained material BaNd _1.9 Sr _0.1 In ₂ O _6.95 was determined by impedance spectroscopy on an Impendancemeter Elins Z-1000P instrument (in the temperature range from 300 ºC to 900 ºС, in the frequency range of 1 Hz÷1 MHz and in air atmospheres (pO ₂ = 0.21 atm) and argon (pO ₂ = 10 ^-5 atm). The measurement results are shown in figures 2 and 3 in dry (pH ₂ O = 3.5⋅10 ^-5 atm) and wet (pH ₂ O = 2⋅10 ^-2 atm) atmospheres, respectively.The data demonstrate high electrical conductivity values in the studied temperature range, which are higher for the BaNd _1.9 Sr _0.1 In ₂ O _6.95 material than for the BaNd ₂ In ₂ O ₇ material.

The proton conductivity values were obtained as the difference between the electrical conductivity values in wet and dry argon atmospheres at the same temperature. The temperature dependences of the proton conductivity of the materials BaNd _1.9 Sr _0.1 In ₂ O _6.95 and BaNd ₂ In ₂ O ₇ are shown in Fig.4, from which it can be seen that at 450 ^o C the value of the proton conductivity of the material BaNd _1.9 Sr _0.1 In ₂ O _6.95 is 3.3⋅ 10 ⁻⁵ Ω ⁻¹ ⋅cm ⁻¹ , and for BaNd ₂ In ₂ O ₇ material – 1.8⋅10 ⁻⁵ Ω ⁻¹ ⋅cm ⁻¹ .

Thus, a new proton-conducting material based on barium-neodymium indate has been obtained, and which can potentially be used as an electrolyte material for a proton-conducting solid oxide cell.

Claims (1)

Solid oxide electrolyte material with proton conductivity based on barium-neodymium indate, which is barium-neodymium indate doped with strontium, having the composition: BaNd _1.9 Sr _0.1 In ₂ O _6.95 .

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