JP6253016B2 - Fuel cell - Google Patents

Description

  The present disclosure relates to fuel cells. The present disclosure particularly relates to a fuel cell comprising a proton conductor.

Among the proton-conducting solid electrolytes, a number of perovskite proton conductors represented by the composition formula AB _1-x B ′ _x O _3-δ have been reported. Here, A is an alkaline earth metal, B is a tetravalent group 4 transition metal element or a tetravalent lanthanoid element Ce, B ′ is a trivalent group 3 or group 13 element, and O is oxygen. x is the composition ratio of the B ′ element that replaces the B element, and satisfies 0 <x <1.0. δ is a value representing oxygen deficiency or oxygen excess. The basic configuration of the perovskite structure will be briefly described later with reference to the drawings.

Non-Patent Document 1 discloses an oxide having a perovskite structure. The oxide of Non-Patent Document 1 has the composition formula BaZr _1-x Y _x O _3-δ or the composition formula BaCe _1-x Y _x O _3-δ . Here, A is barium (Ba), B is Zr or Ce, and B ′ is an oxide of Y.

Patent Document 1 discloses a proton conductive membrane having a perovskite structure. The proton conductive membrane of Patent Document 1 has the chemical formula AL _1-X M _X O _3-α . A is an alkaline earth metal. L is one or more elements selected from cerium, titanium, zirconium and hafnium. M is one or more elements selected from neodymium, gallium, aluminum, yttrium, indium, ytterbium, scandium, gadolinium, samarium and praseodymium. Here, X is the composition ratio of the M element that replaces the L element, and α is the atomic ratio of oxygen deficiency. In the proton conductive membrane of Patent Document 1, 0.05 <X <0.35 and 0.15 <α <1.00.

  On the other hand, solid polymer membranes having proton conductivity are also known. Patent Document 2 discloses a fuel cell using such a solid polymer membrane. In the technique described in Patent Document 2, organic hydride (cyclohexane, decalin, etc.) is supplied as fuel.

JP 2008-23404 A JP 2003-45449 A

Nature materials Vol9 (October 2010) 846-852

  Provided is a fuel cell that can execute power generation without using hydrogen gas and has improved practicality.

One aspect of the fuel cell of the present disclosure is a fuel cell that generates power by supplying fuel to an anode and supplying a gas containing oxygen gas to a cathode, the anode including a dehydrogenation catalyst, and the gas A cathode including a catalyst for reducing oxygen therein, and a proton conductor disposed between the anode and the cathode, the proton conductor having a composition formula A _a B _1-x B ′ _x O ₃₋ having a perovskite crystal structure represented by _δ , wherein A is at least one selected from Group 2 elements, and B is at least one selected from Group 4 elements and Ce; B ′ is a group 3, element 13 or lanthanoid element, 0.5 <a ≦ 1.0, 0.0 ≦ x ≦ 0.5, and 0.0 ≦ δ <3, The charge of the composition formula has a range of −0.13 or more and less than +0.14. In deviates from electroneutrality.

  According to the embodiment of the present disclosure, a fuel cell that can execute power generation without using hydrogen gas and has improved utility is provided.

It is a diagram showing a general perovskite structure represented by the composition formula ABO _3. 3 is a graph showing proton conductivity in a temperature range of 100 ° C. to 600 ° C. in Example 1. FIG. It is a typical sectional view showing an example of a fuel cell by an embodiment of this indication.

(About organic hydride)
Hydrogenation of aromatic hydrocarbon compounds benzene, toluene, biphenyl, naphthalene, 1-methylnaphthalene and 2-ethylnaphthalene results in cyclohexane, methylcyclohexane, bicyclohexyl, decalin, 1-methyldecalin and 2-ethyldecalin, respectively. Is obtained. By using the hydride (eg, benzene) as described above, hydrogen can be stored in the form of a hydride (eg, cyclohexane). Further, when acetone is hydrogenated, 2-propanol is obtained. It is therefore possible to store hydrogen in the form of 2-propanol using acetone. In this specification, the hydride (cyclohexane, 2-propanol, etc.) obtained by hydrogenating benzene, acetone, etc. as exemplified above is referred to as organic hydride.

  By dehydrogenating the organic hydride, hydrogen can be extracted from the organic hydride. For example, hydrogen gas is obtained by dehydrogenation of cyclohexane. At this time, benzene is produced as a dehydrogenated product. The benzene produced by the dehydrogenation of cyclohexane can be converted to cyclohexane by hydrogenation and can therefore be reused for hydrogen storage.

(About power generation using organic hydride as fuel)
Conventionally, fuel cells using protons as ions moving through an electrolyte are known. As such a fuel cell, for example, a polymer electrolyte fuel cell using a proton conductive solid polymer membrane made of a perfluorocarbon material as an electrolyte is known. It is also known to use organic hydride as a fuel for a polymer electrolyte fuel cell (see, for example, Patent Document 2). By using organic hydride as a fuel, there is an advantage that power generation can be performed without using hydrogen gas which is difficult to handle. In addition, there is an advantage that the organic hydride dehydrogenated product generated by power generation can be reused for hydrogen storage.

  The aforementioned proton-conducting solid polymer membrane exhibits good proton conductivity in a temperature range of 100 ° C. or lower and in a wet state. Therefore, in the polymer electrolyte fuel cell, during operation, moisture is supplied to the polymer electrolyte membrane via, for example, the anode or the cathode.

  However, at a normal pressure and a temperature of 100 ° C. or lower, the organic hydride is hardly dehydrogenated, and thus it is difficult to obtain a high current value by power generation. Further, when the solid polymer membrane is in a wet state, water is mixed with the dehydration product of the organic hydride supplied to the anode. For this reason, the purity of the dehydrogenated product decreases due to the mixing of moisture, and it is difficult to hydrogenate the dehydrogenated product and reuse it as an organic hydride. In addition, the solid polymer membrane may be dissolved by the organic hydride and / or its dehydrogenated product, and stable power generation is difficult.

  In addition, when performing an electric power generation using an organic hydride as a fuel, in order to suppress deterioration of an organic hydride and / or the dehydrogenation thing of an organic hydride, it is preferable that operating temperature is a 300 degrees C or less temperature range. Conventional perovskite proton conductive oxides as described above are not suitable for fuel cells using organic hydride as fuel because they exhibit practical proton conductivity at temperatures of 600 ° C. or higher.

  For the above reasons, there is a need for a practical fuel cell that can generate power in a temperature range of 100 ° C. or higher and 300 ° C. or lower using organic hydride as a fuel.

  The present inventor has found a proton conductive oxide that maintains a high proton conductivity even in a temperature range of 100 ° C. or higher and 500 ° C. or lower by intensive research, and uses such a proton conductive oxide as an electrolyte. I came up with a fuel cell.

  The outline of one embodiment of the present invention is as follows.

A fuel cell which is one embodiment of the present invention is a fuel cell that generates power by supplying fuel to an anode and supplying a gas containing oxygen gas to a cathode, the anode including a dehydrogenation catalyst; A cathode including a catalyst for reducing oxygen in a gas; and a proton conductor disposed between the anode and the cathode, the proton conductor having a composition formula A _a B _1-x B ′ _x O ₃ a perovskite crystal structure represented by _-δ , wherein A is at least one selected from Group 2 elements, and B is at least one selected from Group 4 elements and Ce B ′ is a group 3 element, group 13 element or lanthanoid element, and 0.5 <a ≦ 1.0, 0.0 ≦ x ≦ 0.5, and 0.0 ≦ δ <3, The charge of the composition formula is −0.13 or more and less than +0.14 It deviates from the electrically neutral range.

  The A is at least one selected from the group consisting of Ba, Sr and Ca, the B is at least one selected from the group consisting of Zr, Ce and Ti, and the B ′ is Yb, Y , Nd and may be one selected from the group consisting of In.

  x = 0, and the charge of the composition formula may deviate from electrical neutrality in a range greater than 0 and less than 0.14.

  0.0 <x ≦ 0.50, and the charge of the composition formula may deviate from electrical neutrality in a range of −0.13 or more and less than 0.

  The dehydrogenation catalyst may be a metal or alloy containing at least one selected from the group consisting of Ni, Pt and Pd.

  The dehydrogenation catalyst may be an oxide containing at least one selected from the group consisting of Ni, Pt and Pd.

The anode may further include a support. The carrier may be composed of Al ₂ O ₃ , SiO ₂ , or ZrO ₂ . The dehydrogenation catalyst is a metal or alloy containing at least one selected from the group consisting of Ni, Pt and Pd, and may be supported on the surface of the support.

  The catalyst for reducing oxygen may be a metal or alloy containing at least one selected from the group consisting of Pt and Ru.

  The catalyst for reducing oxygen may be an oxide containing at least one selected from the group consisting of Pt and Ru.

  The catalyst for reducing oxygen may be an oxide containing at least one selected from the group consisting of Co, Fe and Mn.

The catalyst for reducing oxygen may be an oxide having a perovskite crystal structure represented by a composition formula CDO _{3 -δ} . The C may include at least one selected from the group consisting of Ba, Sr, Ca, La and Sm. The D may include at least one selected from the group consisting of Zr and Ce and Ru, or may include at least one selected from the group consisting of Ni, Fe, Co, and Mn.

The catalyst for reducing oxygen may be an oxide having a K ₂ NiF ₄ perovskite crystal structure represented by a composition formula La _2-w Sr _w NiO _4-δ . 0 ≦ w ≦ 0.5 may be satisfied.

Catalyst for reducing the oxygen may be an oxide having a perovskite crystal structure expressed by a composition formula _{EF 1-z F 'z O} 3-δ. The E may include at least one selected from the group consisting of Ba, Sr and Ca. The F may include at least one selected from the group consisting of Zr and Ce and Ru. F ′ may be Y or In or a trivalent lanthanoid element. 0.10 <z <0.80 may be satisfied.

  Before describing an embodiment of a fuel cell according to the present disclosure, a proton conductive oxide used in the fuel cell will be described. The proton conductive oxide described below is a perovskite proton conductor having a perovskite structure, and has high proton conductivity even in a temperature range of 100 ° C. or higher and 500 ° C. or lower.

(Perovskite structure)
A typical perovskite structure is composed of elements A, B, and O, as illustrated in FIG. 1, and is represented by a composition formula ABO ₃ . Here, A is an element that can be a divalent cation, B is an element that can be a tetravalent cation, and O is oxygen. A unit cell of a crystal having a perovskite structure typically has a shape close to a cube. As shown in the figure, ions of the element A are located at the eight vertices of the unit cell. On the other hand, oxygen O ions are located at the centers of the six faces of the unit cell. In addition, an element B ion is located near the center of the unit cell. The positions occupied by the elements A, B, and O may be referred to as A site, B site, and O site, respectively.

The above structure is a basic structure of the perovskite crystal, and some of the elements A, B, and O may be missing, excessive, or substituted with other elements. For example, a crystal in which an element B ′ other than the element B is located at the B site is a perovskite crystal represented by a composition formula AB _(1-x) B ′ _x O ₃ . Here, x is a composition ratio (atom ratio) of B ′, and may be called a substitution rate. When such element substitution, deficiency, or excess occurs, the structure of the unit cell can be distorted or deformed from the cube. Perovskite crystals are not limited to “cubic crystals”, but broadly include crystals that have phase transitions to “rhombic crystals” and “tetragonal crystals” with lower symmetry.

(Knowledge of the present inventors)
In a conventional proton conductor having a perovskite structure, when B, which is a tetravalent element, is substituted with B ′, which is a trivalent element, oxygen deficiency occurs in the proton conductor. In other words, if a part of the tetravalent cation is replaced with a trivalent cation, the total positive charge of the cation is reduced, so that it is a divalent anion due to charge compensation that maintains electrical neutrality. It is considered that the composition ratio of oxygen ions decreases and oxygen deficiency occurs. In the proton conductor having such a composition, it is considered that a proton conducting carrier is introduced into the proton conductor by introducing a water molecule (H ₂ O) into the oxygen deficient position (O site). Yes.

  In a conventional proton conductor, proton conductivity is considered to be expressed by hopping conduction of protons around oxygen atoms. In this case, the temperature dependence of proton conductivity is a thermal activation type having an activation energy of about 0.4 to 1.0 eV. Therefore, proton conductivity decreases exponentially with decreasing temperature.

In order for the proton conductor to maintain a high proton conductivity of 10 ⁻² S / cm (Siemens / centimeter) or more even in a temperature range of 100 ° C. or more and 500 ° C. or less, the activation energy of the proton conductivity should be increased. It is desired to suppress a decrease in proton conductivity accompanying a decrease in temperature by setting it to 0.1 eV or less.

  The inventors of the present invention have tried to increase the concentration or density of proton carriers by increasing the solid solution amount (substitution amount) of the trivalent element B ′ and to create a state in which protons can move more easily than conventional hopping. It was. However, in the conventional perovskite proton conductor, the upper limit of the composition ratio of the B ′ element is about 0.2, and the oxygen deficiency has an upper limit.

  As a method for introducing more proton carriers, the present inventor has found that an effect similar to an increase in the composition ratio of the B ′ element can be obtained by decreasing the composition ratio of the A element. As a result, as described above, a site in which more oxygen is lost than in the prior art can be provided in the proton conductor. In addition, the concentration or density of proton carriers can be obtained by introducing water molecules at the position of oxygen deficiency, introducing protons around oxygen, and shifting the charge of the composition formula constituting the perovskite structure from electrical neutrality. It was found that it can be improved. As a result, a perovskite proton conductor having high proton conductivity was obtained. The outline of one embodiment of the present invention is as follows.

The proton conductor according to one embodiment of the present invention is a proton conductor having a perovskite crystal structure represented by _a composition formula A _a B _1-x B ′ _x O _3−δ , wherein the A is a group 2 At least one selected from elements, B is at least one selected from Group 4 elements and Ce, B ′ is a Group 3, 13 or lanthanoid element; .5 <a ≦ 1.0, 0.0 ≦ x ≦ 0.5, and 0.0 ≦ δ <3, and the charge of the composition formula is in the range of −0.13 or more and less than +0.14. Deviation from target neutrality.

  The A is at least one selected from the group consisting of Ba, Sr and Ca, the B is at least one selected from the group consisting of Zr, Ce and Ti, and the B ′ is Yb, Y , Nd and may be one selected from the group consisting of In.

  x = 0, and the charge of the composition formula may deviate from electrical neutrality in a range greater than 0 and less than 0.14.

  0.0 <x ≦ 0.50, and the charge of the composition formula may deviate from electrical neutrality in a range of −0.13 or more and less than 0.

(Embodiment 1)
Hereinafter, embodiments will be described.

The proton conductor of the present disclosure has a perovskite crystal structure represented by _a composition formula A _a B _1-x B ′ _x O _3−δ . A is at least one selected from alkaline earth metals. B is at least one selected from a Group 4 transition metal and Ce. B ′ is a Group 3 or Group 13 element. A, x, and δ in the above composition formula satisfy 0.5 <a ≦ 1.0, 0.0 ≦ x ≦ 0.5, and 0.0 ≦ δ <3. Further, the charge of the above composition formula deviates from electrical neutrality in a range of −0.13 or more and less than +0.14. That is, the composition ratio a, x, and the oxygen deficiency δ are determined so that the composition formula A _a B _1-x B ′ _x O _3-δ is not electrically neutral. In order to compensate for the charge of the perovskite crystal structure represented by the composition formula A _a B _1-x B ′ _x O _{3 -δ} , the crystal structure of the proton conductor is neutral. It is considered that protons are introduced into the crystal structure or oxygen is electrically excessively present.

  In this specification, the crystal structure of the proton conductor includes a proton conductor and protons or oxygen that compensates for the charge of the perovskite crystal structure. Here, the proton or oxygen that compensates for the charge of the perovskite crystal structure is located according to the composition of the proton conductor, the charge condition, and the like, and thus the proton or oxygen is not intentionally introduced. Therefore, it is considered that the proton conductivity of the proton conductor mainly depends on the composition of the proton conductor and the charge condition.

<Element of A>
An example of the element A is a group 2 element (alkaline earth metal). When the element A is a group 2 element, the perovskite structure is stabilized. A specific example of the element of A is at least one selected from the group selected from barium (Ba), strontium (Sr), calcium (Ca), and magnesium (Mg). In particular, a proton conductor in which the element A is at least one selected from the group consisting of calcium (Ca), barium (Ba), and strontium (Sr) is desirable because it has high proton conductivity. The element A includes at least barium (Ba), and may include at least one selected from the group consisting of strontium (Sr), calcium (Ca), and magnesium (Mg). For example, elements A is _{Ba y A '1-y (} 0 <y ≦ 1).

  Since the element of A is a group 2 element and the valence is divalent, reducing the amount of element A can provide the same effect as increasing the composition ratio of the element amount of B ′, and oxygen deficiency. Is likely to occur. For this reason, it deviates from electrical neutrality, and it becomes easy to introduce proton carriers, and the effect of increasing the carrier concentration of protons can be obtained.

<B element>
An example of the element of B is at least one selected from the group 4 element and cerium (Ce). A specific example of the element of B is at least one selected from the group consisting of zirconium (Zr), cerium (Ce), titanium (Ti), and hafnium (Hf). In the case where the element of B is zirconium (Zr), the perovskite structure is stabilized, so that generation of a tissue component having no proton conductivity is reduced. As a result, a proton conductor having high proton conductivity is obtained, which is desirable.

<B 'element>
Examples of the element of B ′ are a group 3 element, a group 13 element, or a trivalent lanthanoid element. The element B 'preferably has an ionic radius greater than 0.5 and less than 1.02. Thereby, the perovskite structure can be kept stable. Therefore, oxygen vacancies are likely to occur while maintaining the crystal structure, and can exist stably even if the charge of the composition formula A _a B _1-x B ′ _x O _3−δ deviates from electrical neutrality.

  Specific examples of the element of B ′ are ytterbium (Yb), neodymium (Nd), yttrium (Y), or indium (In). The proton conductor in which the element of B ′ is ytterbium (Yb), neodymium (Nd), yttrium (Y), or indium (In) has a stable perovskite structure and has high proton conductivity. desirable.

(About a, x, and δ)
The value of a indicating the composition ratio of the element A is in the range of 0.5 <a ≦ 1.0. When the composition ratio a is 0.5 or less, it is possible to synthesize an oxide having a perovskite structure, but this is not preferable because it becomes difficult to control the charge of the above composition formula from electrical neutrality.

  When the composition ratio a is larger than 1.0, the oxide has a phase that does not exhibit proton conductivity, so that proton conductivity is greatly reduced.

  The value x indicating the composition ratio of the B ′ element is in the range of 0.0 ≦ x ≦ 0.5. When the composition ratio x is larger than 0, oxygen vacancies are generated in the perovskite structure, and proton conductive carriers are introduced into the proton conductor. On the other hand, when the composition ratio x is larger than 0.5, it is possible to synthesize an oxide having a perovskite structure, but a phase that does not exhibit proton conductivity is also generated. For this reason, the proton conductivity of the whole oxide is greatly reduced.

In the above composition formula, A is a divalent element, B is a tetravalent element, B ′ is a trivalent element, and oxygen is a divalent element. Therefore, the charge of the above composition formula is determined by the composition ratio a, x and the oxygen deficiency δ. Considering the electrical neutrality, it is considered that the sum of the value of the deficiency a of A and the half of the substitution amount of B ′ becomes the oxygen deficiency. In the proton conductor of this embodiment, the charge of the above composition formula deviates from electrical neutrality in a range of −0.13 or more and less than +0.14. That is, the composition ratio a, x, and the oxygen deficiency δ are determined so that the composition formula A _a B _1-x B ′ _x O _3-δ is not electrically neutral.

  More specifically, when the composition ratio x of B ′ is 0, the charge of the above composition formula deviates from electrical neutrality in the range of greater than 0 and less than 0.14. When the composition ratio x of B ′ is 0.0 <x ≦ 0.5, the charge of the above composition formula deviates from electrical neutrality in a range of −0.13 or more and less than 0.

Stable oxide having many oxygen vacancies and a perovskite structure when the composition ratios a and x are 0.5 <a ≦ 1.0 and 0.0 ≦ x ≦ 0.5 Is obtained. When water molecules are introduced at the position of the oxygen defect or the position of the oxygen defect remains empty, the electric charge of the above composition formula is electrically within the range of −0.13 or more and less than +0.14. Deviation from neutrality. Although the detailed reason is unknown at present, it is considered that a proton conductor that can easily conduct protons even at a relatively low temperature due to a high carrier concentration of protons or a charge distribution in the crystal structure can be realized. It is done. According to this embodiment, a proton conductor having a proton conductivity of about 10 ⁻¹ S / cm can be realized at a temperature of about 100 ° C.

  According to the present disclosure, a single crystal or polycrystal perovskite structure composed of a single phase having a substantially uniform composition and crystal structure (homogeneous) is realized. Here, “comprised of a single phase having a substantially uniform composition and crystal structure” means that the proton conductor does not contain a heterogeneous phase having a composition outside the scope of the present invention. Note that the proton conductor according to an embodiment of the present disclosure may contain a small amount of inevitable impurities. Moreover, when manufacturing the proton conductor of this indication by sintering, compounds and elements, such as a sintering aid, may be included in part. In addition, impurities may be added unintentionally in the course of the manufacturing process, or intentionally to obtain some effect. The important point is that the elements A, B, B ′, and O are within the range defined by the present disclosure, and these constitute a perovskite crystal structure. Therefore, the inclusion of impurities mixed in during the production can be allowed.

(Determination of composition formula and measurement of charge of composition formula)
The composition formula of the proton conductor of the present embodiment, and the deviation from the electric neutrality in the case of the above-described composition formula can be measured by using, for example, an electron beam probe microanalyzer (EPMA). . Specifically, the proton conductor is quantitatively measured for the element represented by the above composition formula, and the charge per composition formula is calculated from the valence and composition ratio of the constituent elements. In the evaluation using an electron beam microprobe analyzer used for measurement, it is preferable to perform measurement using a wavelength dispersion spectrometer. In this case, it is preferable to perform calibration so that quantitative evaluation can be performed using a standard sample having a known chemical composition. On the other hand, an energy dispersive spectrometer is not preferable because a large error may occur in the quantitative evaluation of light elements such as oxygen. In addition, although quantitative analysis using induction plasma spectroscopy (ICP) can measure the metal elements constituting the material, it cannot quantify oxygen elements. For this reason, it is not suitable for measuring an electrical neutral shift.

For example, JXA-8900R manufactured by JEOL Ltd. can be used for the electron probe microanalyzer (EPMA). A characteristic X-ray generated by irradiating an electron beam uses a wavelength dispersion detector (WDS). The characteristic X-ray to be measured is quantitatively measured using a standard sample having a known composition and the calibrated characteristic X-ray and spectral crystal. The constituent element ratio of the proton conductor is analyzed, and the product of the valence of each constituent element and the constituent element ratio is obtained. For example, it is assumed that A is Ba, B is Zr, and B ′ is Y in the perovskite crystal structure represented by the composition formula A _a B _1-x B ′ _x O _3−δ . In this case, Ba is calculated as +2, Zr is +4, Y is +3, and O is -2. As the valences of these elements, values that can be taken as the most valences in a stable oxide state are adopted. Next, in the analysis using EPMA, it is assumed that the ratio of A (Ba) is a, the ratio of B (Zr) is b, the ratio of B ′ (Y) is c, and the ratio of O is d. In this case, the chemical composition formula can be described as BaaZrbYcOd. The charge of the composition formula, that is, the deviation from the electrical neutrality can be calculated as ((2 × a) + (4 × b) + (3 × c) − (2 × d)) ÷ (b + c). According to this calculation, the electric charge is obtained by taking the product of the valence of each constituent element and the constituent element ratio, taking the sum of the valences of each element, and then setting the sum of the constituent element ratios of B and B ′ to 1. Standardized. B and B ′ are located in the center of the octahedron surrounded by oxygen in the perovskite structure and are not easily lost. Therefore, by normalizing with the sum of B and B ′, electricity per unit cell (unit cell) Deviation of charge from target neutrality is required.

  The surface of the ionic conductor to be analyzed is preferably flat. This is because when there are large irregularities, the electron beam is irradiated, and characteristic X-rays generated from the inside of the sample are not correctly detected, making quantitative measurement difficult. In addition, since the proton conductor has poor electrical conductivity, carbon or the like may be thinly deposited on the surface to prevent charging of the incident electron beam. The electron beam incident conditions to be observed are not particularly limited as long as sufficient signal intensity is obtained with WDS and the sample is not deteriorated by image sticking or the like due to electron beam incidence. Further, it is preferable to measure five or more measurement points and adopt the average value. When the measurement value is clearly different from other measurement values at five or more measurement points, it is preferable not to employ the value as the average value.

(Production method)
The proton conductor of this embodiment can be implemented in various forms. In the case of obtaining a film-like proton conductor, it can be produced by a film forming method such as a sputtering method, a plasma laser deposition method (PLD method), a chemical vapor deposition method (CVD method) or the like. The composition is adjusted by a general method used in these film forming methods. For example, in the case of sputtering or plasma laser deposition, the composition of the proton conductor to be generated can be controlled by adjusting the composition of the target. In the case of the chemical vapor deposition method, the composition of the produced proton conductor can be controlled by adjusting the amount of the raw material gas introduced into the reaction chamber.

  Further, when obtaining a proton conductor in a bulk state, it can be synthesized by a solid phase reaction method, a hydrothermal synthesis method, or the like.

  In the case where the proton conductor of the present embodiment is represented by the above composition formula, in order to adjust the deviation from the electric neutrality of the charge, the molar ratio of the constituent elements during the above-described production method is controlled or synthesized It can be controlled later by performing a heat treatment in a reducing atmosphere.

(Other)
The proton conductor is also called a proton conductive solid electrolyte. The proton conductor only needs to have a function of conducting protons, and may not be a continuous film or a bulk.

Moreover, when implementing a proton conductor with a film | membrane form, the surface of the base material which supports a proton conductor does not need to be flat. In order to avoid a direct reaction between a gas that is a raw material for supplying protons to the proton conductor of the present embodiment, a gas that reacts with protons that have passed through the proton conductor, and hydrogen that is a proton reductant, It is preferable that the two gas flow paths are configured so as not to leak. For this reason, for example, a thin film of the perovskite proton conductor of the present embodiment on a substrate made of magnesium oxide (MgO), strontium titanate (SrTiO ₃ ), silicon (Si) or the like having a smooth flat surface. May be formed. Thereafter, a part or the whole of the base material may be removed using etching or the like, a part of the surface of the proton conductor may be exposed on the base material side, and gas may be supplied. There is no restriction | limiting in particular in the material and shape of a base material.

The crystal structure of the proton conductor may be single crystal or polycrystalline as described above. Crystal structure oriented by controlling orientation of crystal growth on a substrate of magnesium oxide (MgO) or strontium titanate (SrTiO ₃ ) and a buffer layer with a controlled lattice constant formed A proton conductor having is preferable because it has higher proton conductivity. A proton conductor having a single crystal structure that is epitaxially grown on the substrate is more preferable because it has higher proton conductivity. Note that the proton conductor can have a single crystal structure by controlling the film formation conditions such as the plane orientation of the substrate, temperature, pressure, and atmosphere, but the conditions for obtaining the single crystal structure and the single crystal structure There are no particular restrictions on the crystal growth direction or orientation direction.

(Example)
Hereinafter, the present disclosure will be specifically described by way of examples.

Example 1
The base material (10 mm × 10 mm, thickness 0.5 mm) was set on a substrate holder having a heating mechanism inside the vacuum chamber, and the inside of the vacuum chamber was evacuated to a degree of vacuum of about 10 ⁻³ Pa. The material of the base material was magnesium oxide (MgO) single crystal.

  After evacuating the inside of the vacuum chamber, the substrate was heated to 650 ° C to 750 ° C. Oxygen gas (flow rate of 2 sccm) and argon gas (flow rate of 8 sccm) were introduced, and the pressure in the vacuum chamber was adjusted to about 1 Pa.

  A proton conductor was formed by sputtering using a sintered compact target having an element ratio of Ba: Zr = 1: 1. The formed proton conductor had a thickness of 500 nm and a size of 10 mm × 10 mm.

  The structure, composition ratio, and proton conductivity of the deposited proton conductor were evaluated. In addition, the charge deviation and the activation energy of proton conduction were determined. The results are shown in Table 1. Hereinafter, each evaluation method and the result are shown.

  X-ray diffraction of the produced proton conductor was measured using a Cu target. It was confirmed that the obtained proton conductor had a perovskite crystal structure.

The composition formula and the charge of the composition formula of the produced proton conductor were measured by the EMPA described above. As shown in Table 1, the composition formula of the proton conductor (A _a BO _3-δ ) is such that the element of A is barium (Ba), and the value of a is 1 when the element B is zirconium. It was 0.904. The oxygen amount (3-δ) was 2.876, and the charge in the composition formula was shifted 0.057 from electrical neutrality to the positive side.

An electrode was formed using a silver paste on the proton conductor. The proton conductivity was measured using an impedance method in an argon (Ar) gas mixed with 5% hydrogen (H ₂ ) and under a temperature range of 100 ° C. to 600 ° C. The temperature dependence of proton conductivity is shown in FIG.

  As shown in Table 1, the proton conductivity at 100 ° C. was 0.12 S / cm, and the proton conductivity at 500 ° C. was 0.25 S / cm. The activation energy of proton conductivity was determined to be 0.041 eV.

(Example 2)
An experiment was performed in the same manner as in Example 1 except that the film was formed using a sintered compact target having an element ratio of Ba: Zr: Ce: Nd = 10: 5: 4: 1. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element of A is barium (Ba), the value of a is 0.975, The elements were zirconium (Zr) and cerium (Ce), and the values were 0.495 and 0.412, respectively. The element of B ′ was neodymium (Nd), and the value of x was 0.93. In addition, when the oxygen amount (3-δ) is 2.975 and Ce is tetravalent, it has been found that the charge in the composition formula is shifted from the electrical neutrality by 0.099 to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.33 S / cm, and the proton conductivity at 500 ° C. was 0.48 S / cm. The activation energy of proton conductivity was determined to be 0.022 eV.

(Example 3)
The experiment was performed in the same manner as in Example 1 except that the film was formed using a sintered body target having an element ratio of Ba: Zr: Y = 2: 1: 1. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

It was confirmed that the proton conductor has a perovskite crystal structure and is polycrystalline. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element of A is barium (Ba), the value of a is 0.539, The element was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.48 (Zr: 0.52, Y: 0.48). Further, when the oxygen amount is 2.363 and Ce is tetravalent, it was found that the charge in the composition formula is shifted by 0.129 from the electrical neutral to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.39 S / cm, and the proton conductivity at 500 ° C. was 0.71 S / cm. The activation energy of proton conductivity was determined to be 0.035 eV.

Example 4
The experiment was performed in the same manner as in Example 1 except that the film was formed using a sintered body target having an element ratio of Ba: Zr: Ti: In = 6: 7: 1: 2. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element of A is barium (Ba), the value of a is 0.522, The elements were zirconium (Zr) and titanium (Ti), zirconium was 0.682, and titanium was 0.098. The amount of oxygen was 2.474, and it was found that the charge in the composition formula was shifted 0.124 from electrical neutrality to the negative side. The element of B ′ was indium (In), and the value of x was 0.22. As shown in Table 1, the proton conductivity at 100 ° C. was 0.34 S / cm, and the proton conductivity at 500 ° C. was 0.67 S / cm. The activation energy of proton conductivity was determined to be 0.037 eV.

(Example 5)
Barium carbonate (BaCO ₃ ), zirconium oxide (ZrO ₂ ), and yttrium oxide (Y ₂ O ₃ ) are weighed and mixed so as to have an element ratio of Ba: Zr: Y = 5: 4: 1, and about 1300 ° C. After calcining, a ceramic bulk sample was prepared by firing at 1700 ° C. The experiment was performed in the same manner as in Example 1 except that a ceramic bulk body was used. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element of A is barium (Ba), the value of a is 0.966, The element was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.197. The amount of oxygen was 2.932, and it was found that the charge in the composition formula was shifted 0.128 from electrical neutrality to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.37 S / cm, and the proton conductivity at 500 ° C. was 0.78 S / cm. The activation energy of proton conductivity was determined to be 0.039 eV.

(Example 6)
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Sr: Zr = 1: 1. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a BO _3-δ ), the element A was strontium (Sr), and the value of a was 0.98. The amount of oxygen was 2.969, and it was found that the charge in the composition formula was shifted 0.022 from the electrical neutrality to the positive side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.10 S / cm, and the proton conductivity at 500 ° C. was 0.21 S / cm. The activation energy of proton conductivity was determined to be 0.055 eV.

(Example 7)
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Sr: Zr: Yb = 10: 7: 3. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element A was strontium (Sr), and the value of a was 0.965. The element of B was zirconium (Zr), the element of B ′ was ytterbium (Yb), and the value of x was 0.05. The amount of oxygen was 2.955, and it was found that the charge in the composition formula was shifted 0.03 from the electrical neutrality to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.10 S / cm, and the proton conductivity at 500 ° C. was 0.22 S / cm. The activation energy of proton conductivity was determined to be 0.055 eV.

(Example 8)
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Sr: Zr: Ce: Y = 8: 4: 3: 3. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element A was strontium (Sr), and the value a was 0.736. The elements of B were zirconium (Zr) and cerium (Ce), zirconium was 0.423, and cerium was 0.307. The element of B ′ was yttrium (Y), and the value of x was 0.27. The amount of oxygen was 2.616, and it was found that the charge in the composition formula was shifted 0.03 from electrical neutrality to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.13 S / cm, and the proton conductivity at 500 ° C. was 0.25 S / cm. The activation energy of proton conductivity was determined to be 0.042 eV.

Example 9
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Sr: Zr: In = 7: 6: 4. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element A was strontium (Sr), and the value of a was 0.686. The element of B was zirconium (Zr), the element of B ′ was indium (In), and the value of x was 0.351. The oxygen amount was 2.542, and it was found that the charge in the composition formula was shifted by 0.062 from the electrical neutral to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.13 S / cm, and the proton conductivity at 500 ° C. was 0.24 S / cm. The activation energy of proton conductivity was determined to be 0.041 eV.

(Example 10)
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Sr: Zr: Y = 3: 3: 2. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element A was strontium (Sr), and the value of a was 0.563. The element of B was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.474. The amount of oxygen was 2.358, and it was found that the charge of the composition formula was shifted by 0.063 from the electrical neutrality to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.18 S / cm, and the proton conductivity at 500 ° C. was 0.30 S / cm. The activation energy of proton conductivity was determined to be 0.025 eV.

(Example 11)
The experiment was performed in the same manner as in Example 1 except that the sintered body target was used to form an element ratio of Ca: Zr = 1: 1. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a BO _3-δ ), the element of A was calcium (Ca), and the value of a was 0.987. The amount of oxygen was 2.972, and it was found that the charge in the composition formula was shifted 0.03 from the electrical neutral to the positive side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.02 S / cm, and the proton conductivity at 500 ° C. was 0.18 S / cm. The activation energy of proton conductivity was determined to be 0.055 eV.

(Example 12)
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Ca: Zr: Y = 10: 9: 1 was obtained. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element A was calcium (Ca), and the value of a was 0.95. The element of B was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.099. The oxygen amount was 2.926, and it was found that the charge in the composition formula was shifted 0.05 from the electrical neutral to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 0.030 S / cm, and the proton conductivity at 500 ° C. was 0.21 S / cm. The activation energy of proton conductivity was determined to be 0.055 eV.

(Example 13)
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Ba: Sr: Zr: Y = 5: 5: 8: 2 was obtained. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the elements of A are barium (Ba) and strontium (Sr), and the ratio of Ba is 0.39. And the ratio of Sr was 0.43, and the value of a was 0.92. The element of B was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.192. The oxygen amount was 2.876, and it was found that the charge in the composition formula was shifted from the electrical neutrality to the negative side by 0.103. As shown in Table 1, the proton conductivity at 100 ° C. was 0.290 S / cm, and the proton conductivity at 500 ° C. was 0.41 S / cm. The activation energy of proton conductivity was determined to be 0.021 eV.

(Comparative Example 1)
The experiment was performed in the same manner as in Example 1 except that the film was formed using the sintered compact target so that the element ratio of Ba: Zr: Y = 6: 7: 3. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element A was barium (Ba), and the value of a was 0.603. The element of B was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.315. The amount of oxygen was 2.445, and the charge of the composition formula was found to be electrically neutral. As shown in Table 1, the proton conductivity at 100 ° C. was 3.3 × 10 ⁻⁶ S / cm, and the proton conductivity at 500 ° C. was 8.4 × 10 ⁻³ S / cm. The activation energy of proton conductivity was determined to be 0.454 eV.

(Comparative Example 2)
An experiment was performed in the same manner as in Example 1 except that the film was formed using a sintered body target having an element ratio of Ba: Zr: Y = 7: 7: 3. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element of A was barium (Ba), and the value of a was 0.635. The element of B was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.318. The amount of oxygen was 2.55, and it was found that the charge in the composition formula was shifted by 0.148 from the electrical neutral to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 6.6 × 10 ⁻⁶ S / cm, and the proton conductivity at 500 ° C. was 9.5 × 10 ⁻³ S / cm. The activation energy of proton conductivity was determined to be 0.419 eV.

(Comparative Example 3)
An experiment was performed in the same manner as in Example 1 except that the film was formed using a sintered body target having an element ratio of Ba: Zr: Y = 10: 9: 1. Table 1 shows the structure, composition ratio, and proton conductivity of the deposited proton conductor.

The proton conductor was confirmed to have a perovskite crystal structure. As shown in Table 1, in the proton conductor (A _a B _1-x B ′ _x O _3-δ ), the element of A was barium (Ba), and the value of a was 1.00. The element of B was zirconium (Zr), the element of B ′ was yttrium (Y), and the value of x was 0.101. The oxygen content was 3.051, and it was found that the charge in the composition formula was shifted 0.202 from the electrical neutral to the negative side. As shown in Table 1, the proton conductivity at 100 ° C. was 4.2 × 10 ⁻⁶ S / cm, and the proton conductivity at 500 ° C. was 8.5 × 10 ⁻³ S / cm. The activation energy of proton conductivity was determined to be 0.436 eV.

  As shown in Table 1, in the proton conductors of Examples 1 to 13, the composition ratios a and x in the case where the sum of B and B ′ is 1 for the element A are 0.5 <a ≦ 1.0. And 0.0 ≦ x ≦ 0.5. In the proton conductors of Examples 1 to 13, the charge of the composition formula of the elements constituting the perovskite structure is deviated from electrical neutrality. Specifically, the charge shift is in the range of −0.128 to 0.057 and is not zero. When the B ′ element is not included, the charge of the composition formula is shifted to the positive side in the range of greater than 0 to 0.057 from electrical neutrality. When the B ′ element is included, the charge in the composition formula is shifted from the electric neutrality to the negative side in a range of −0.129 or more and less than 0.

  On the other hand, in the proton conductors of Comparative Examples 1 to 3, the composition ratios a and x are in the range of Examples 1 to 13 described above, but the charge of the composition formula of the elements constituting the perovskite structure is electrically medium. (Comparative Example 1) or more negative than -0.128.

As shown in Table 1, the proton conductors of Examples 1 to 13 have a proton conductivity that is four orders of magnitude higher at 100 ° C. than the proton conductors of Comparative Examples 1 to 3. In addition, the proton conductors of Examples 1 to 13 have a proton conductivity that is 10 times higher even at 500 ° C. That is, in the temperature range of 100 ° C. or more and 500 ° C. or less, the proton conductors of Examples 1 to 13 have high proton conductivity of 10 ⁻² S / cm or more.

  In particular, the proton conductors of Examples 1 to 13 have a higher proton conductivity at a low temperature of about 100 ° C. than the proton conductors of the comparative examples. For this reason, the activation energy of the proton conductivity of Examples 1 to 13 is about an order of magnitude smaller than the activation energy of the comparative example and lower than 0.1 eV. In contrast, the proton conductors of Comparative Examples 1 to 3 had activation energy higher than 0.4 eV. From this, it is considered that the proton conductors of Examples 1 to 13 have a higher proton conductivity than the conventional one without a sudden decrease in proton conductivity even at a temperature of 100 ° C. or lower. .

  Therefore, from the present example, according to the proton conductor of the present embodiment, the composition ratios a and x and the charge of the composition formula are in the above-described ranges, so that the proton conductivity is higher than the conventional one. all right. In particular, in the temperature range of about 100 ° C. to 500 ° C., it has been found that the proton conductivity is remarkably improved as compared with the conventional case.

(Embodiment of fuel cell)
Hereinafter, the configuration and operation of the fuel cell according to the embodiment of the present disclosure will be described with reference to FIG. 3.

  A fuel cell 100 shown in FIG. 3 includes an anode 102, a cathode 103, and a proton conductor 101 disposed between the anode 102 and the cathode 103. As the proton conductor 101, the above-described proton conductive oxide described with reference to the embodiment can be used. The proton conductor 101 has high proton conductivity even in a temperature range of 100 ° C. or more and 500 ° C. or less. Therefore, the fuel cell 100 can operate in a temperature range of, for example, 100 ° C. or more and 300 ° C. or less suitable for power generation using an organic hydride. Further, in the fuel cell 100 including the proton conductor 101, unlike the case where the proton conductive solid polymer membrane is used as the electrolyte, water is actively supplied from the anode 102 or the cathode 103 to the electrolyte (here, the proton conductor 101). There is no need to supply.

  In the configuration illustrated in FIG. 3, the anode 102 and the cathode 103 are arranged so as to sandwich the proton conductor 101. That is, in the illustrated example, the anode 102 is disposed on one main surface of the proton conductor 101, and the cathode 103 is disposed on the main surface of the proton conductor 101 where the anode 102 is not disposed. Has been. The arrangement of the proton conductor 101, the anode 102, and the cathode 103 is not limited to the example in FIG. 3, and various arrangements can be adopted. For example, the anode 102 and the cathode 103 may be disposed on the same main surface of the proton conductor 101.

  The anode 102 includes a dehydrogenation catalyst. That is, the anode 102 is configured such that protons can be extracted from a gas or liquid containing organic hydride. An example of the catalyst contained in the anode 102 is a metal, an alloy, or an oxide containing at least one selected from the group consisting of Ni, Pt, and Pd.

When a metal or an alloy containing at least one selected from the group consisting of Ni, Pt, and Pd is used as the catalyst contained in the anode 102, the catalyst is a support made of Al ₂ O ₃ , SiO ₂ , ZrO ₂ or the like. It may be carried on the surface. That is, the anode 102 can further include a support. There is no particular limitation on the material of the carrier. Al ₂ O ₃ , SiO ₂ , and ZrO ₂ are examples of carriers on which the anode 102 can be easily formed. Further, the shape of the carrier is not particularly limited, and it is only necessary to ensure electrical connection between the catalyst included in the anode 102 and the external load 104. By including the support in the anode 102, the catalyst can be dispersed in a wider area.

  The anode 102 can be formed by a film formation method such as sputtering, PLD, or CVD. The anode 102 may be formed by screen-printing ink in which the powder of the above material is dispersed in a solvent, and then drying and solidifying by heating, vacuum treatment, or the like. A method for forming the anode 102 is not particularly limited.

  The cathode 103 includes a catalyst capable of reducing oxygen in a gas containing oxygen gas and allowing protons and electrons to react. Examples of the catalyst contained in the cathode 103 include at least one selected from the group consisting of metals, alloys or oxides, or Co, Fe and Mn, including at least one selected from the group consisting of Pt and Ru. It is an oxide.

Another example of the catalyst contained in the cathode 103 is an oxide having a perovskite crystal structure represented by a composition formula ABO3 _-δ . Here, A includes at least one selected from the group consisting of Ba, Sr, Ca, La and Sm, and B includes at least one selected from the group consisting of Zr and Ce and Ru. Or B contains at least 1 chosen from the group which consists of Ni, Fe, Co, and Mn. O represents oxygen, and δ represents oxygen deficiency or oxygen excess. As such oxides, La _1-x Sr _x FeO _3-δ (0 ≦ x ≦ 1.0), La _1-x Sr _x Co _1-y Fe _y O _3-δ (0 ≦ x ≦ 1. 0, 0.1 ≦ y ≦ 0.8), La _1-x Sr _x MnO _3-δ (0 ≦ x ≦ 0.4), Sm _1-x Sr _x CoO _3-δ (0.2 <x < 0.8), Ba _1−x Sr _x Co _1−y Fe _y O _3−δ (0.4 ≦ x ≦ 1.0, 0.4 ≦ y ≦ 1.0), and the like. Note that an oxide having a K ₂ NiF ₄ type crystal structure represented by La _2−x Sr _x NiO _4−δ (where 0 ≦ x ≦ 0.5) can also be used.

As the catalyst contained in the cathode 103, an oxide having a perovskite crystal structure represented by a composition formula AB _1-x B ′ _x O _3−δ as shown below can be used. This oxide is an oxide having a perovskite crystal structure as described above. Here, A includes at least one selected from the group consisting of Ba, Sr and Ca. B contains at least one selected from the group consisting of Zr and Ce and Ru, and B ′ is Y or In or a trivalent lanthanoid element. The value x indicating the composition ratio of the element B ′ is in the range of 0.10 <x <0.80, and more preferably in the range of 0.25 <x <0.75. In addition, when the sum of A, B, and B ′ is 2, the atomic ratio of Ru is, for example, 0.01 or more and 0.8 or less.

  The cathode 103 can be formed by a film forming method such as sputtering, PLD, or CVD. The cathode 103 may be formed by screen-printing ink in which the above material powder is dispersed in a solvent and then drying and solidifying by heating, vacuum treatment, or the like. A method for forming the cathode 103 is not particularly limited.

  In the configuration illustrated in FIG. 3, the fuel cell 100 is provided with an anode side reaction vessel 111 provided with a first fluid inlet 105 and a first fluid outlet 106, and a second fluid inlet 107 and a second fluid outlet 108. And a cathode side reaction vessel 112. The space in the anode side reaction vessel 111 and the space in the cathode side reaction vessel 112 are separated by a partition wall. In the configuration illustrated in FIG. 3, the proton conductor 101 serves as a partition wall that separates these two spaces. Function.

  In the example shown in the figure, a first flow path 109 is provided in the anode side reaction vessel 111, and the fluid introduced from the first fluid inlet 105 passes through the first flow path 109 to the first fluid outlet 106. It flows toward. Similarly, a second flow path 110 is provided in the cathode-side reaction vessel 112, and the fluid introduced from the second fluid inlet 107 goes to the second fluid outlet 108 via the second flow path 110. Flowing.

  The first flow path 109 and the second flow path 110 are kept airtight and watertight, respectively, and are configured so that fluids flowing through the respective flow paths do not mix with each other. As shown in FIG. 3, at least a part of the surface of the anode 102 is exposed in the first flow path 109, and at least a part of the surface of the cathode 103 is exposed in the second flow path 110.

  In the illustrated configuration, a gas or liquid containing organic hydride is introduced into the first flow path 109 via the first fluid inlet 105 when the fuel cell 100 is in operation. Mixtures of two or more organic hydrides can also be used. A gas containing oxygen (typically oxygen gas or air) is introduced into the second flow path 110 via the second fluid inlet 107. Not shown in each of the first fluid inlet 105, the first fluid outlet 106, the second fluid inlet 107, and the second fluid outlet 108 in order to introduce a gas or liquid containing organic hydride and a gas containing oxygen. Are connected. In the middle of these pipes, cylinders, tanks, valves, compressors, mass flow controllers and the like can be arranged.

  The fuel cell 100 generates power by supplying a gas or liquid containing organic hydride to the anode 102 and supplying a gas containing oxygen gas to the cathode 103. By introducing, for example, organic hydride from the first fluid inlet 105 and introducing, for example, oxygen gas from the second fluid inlet 107, an external load 104 having one end connected to the anode 102 and the other end connected to the cathode 103 is connected. Current flows. That is, electric power generated in the fuel cell 100 can be taken out via the anode 102 and the cathode 103.

  For example, liquid organic hydride (here, methylcyclohexane) is introduced from the first fluid inlet 105, and the organic hydride is brought into contact with the anode 102 in the first flow path 109. The organic hydride may be atomized and sprayed on the anode 102. Alternatively, an organic hydride gas or a gas containing vapor may be supplied to the anode 102. The gas supplied to the anode 102 may include, for example, hydrocarbon gas, nitrogen gas, carbon dioxide gas, oxygen gas, argon gas, helium gas, and the like. As a result, protons are extracted from the organic hydride (here, methylcyclohexane).

In the anode 102, the reaction shown in the following formula (1) proceeds.
C ₇ H ₁₄ → C ₇ H ₈ + 6H ⁺ + 6e ⁻ (1)

  A dehydrogenated product (here, toluene) of organic hydride (here, methylcyclohexane) is discharged through the first fluid outlet 106. The dehydrogenated product discharged through the first fluid outlet 106 can be reused as an organic hydride by hydrogenation. The fuel cell 100 is operated at a temperature of, for example, about 200 ° C. during operation. Therefore, alteration of the organic hydride and / or its dehydrogenated product can be suppressed.

  Protons generated at the anode 102 are conducted through the proton conductor 101 and reach the cathode 103. The proton conductor 101 prevents a short circuit between the anode 102 and the cathode 103 and supplies protons generated at the anode 102 to the cathode 103.

For example, oxygen gas is introduced from the second fluid inlet 107, and the oxygen gas is brought into contact with the cathode 103 in the second flow path 110. The oxygen gas may not be actively humidified. By bringing oxygen gas into contact with the cathode 103, the reaction shown in the following formula (2) proceeds at the cathode 103.
4H ⁺ + O ₂ + 4e ⁻ → 2H ₂ O (2)

  Of the organic hydride introduced from the first fluid inlet 105, the organic hydride that has not been used for power generation is discharged through the first fluid outlet 106. The remaining organic hydride may be collected and reintroduced into the first flow path 109 from the first fluid inlet 105. Similarly, oxygen gas that has not been used for power generation out of oxygen gas introduced from the second fluid inlet 107 is discharged through the second fluid outlet 108. The remaining oxygen gas may be recovered and reintroduced into the second flow path 110 from the second fluid inlet 107. The water generated at the cathode 103 may be discharged through the second fluid outlet 108, or another discharge port (not shown) may be provided in the cathode side reaction vessel 112 and discharged from this discharge port. Note that the flow path for introducing the fuel (here, organic hydride) and the gas containing oxygen is not limited to the configuration illustrated in FIG. 3, and various configurations and arrangements may be employed. For example, the arrangement of the first fluid inlet 105 and the first fluid outlet 106 can be designed in consideration of the specific gravity of the organic hydride and its dehydrogenated product. In the configuration in which the anode 102, the proton conductor 101, and the cathode 103 are sequentially stacked, at least a part of the partition that separates the space on the anode side and the space on the cathode side includes the anode 102, the proton conductor 101, and the cathode 103. Any laminate may be used.

  As described above, according to the embodiment of the present disclosure, it is possible to provide a practical fuel cell that uses organic hydride as a fuel and can generate power even in a temperature range of 100 ° C. or higher and 300 ° C. or lower. According to the embodiment of the present disclosure, since the fuel cell can be operated in a temperature range of 300 ° C. or lower, it is possible to obtain a relatively high output while suppressing deterioration of the organic hydride and / or its dehydrogenated product. Further, since it is not necessary to keep the electrolyte in a moist state, mixing of moisture is suppressed, and therefore, it is easy to reuse the dehydride of organic hydride.

  The fuel cell according to the embodiment of the present disclosure is useful as a fuel cell for home use, business use, and the like. Further, according to the embodiment of the present disclosure, hydrogen stored in the form of organic hydride can be used for power generation without taking out in the form of hydrogen gas, and the dehydrated product of organic hydride can be easily reused. Can do.

DESCRIPTION OF SYMBOLS 100 Fuel cell 101 Proton conductor 102 Anode 103 Cathode 104 External load 105 1st fluid inlet 106 1st fluid outlet 107 2nd fluid inlet 108 2nd fluid outlet 109 1st flow path 110 2nd flow path 111 Anode side reaction container 112 Cathode side reaction vessel

Claims (13)

A fuel cell that generates power by supplying fuel to an anode and supplying a gas containing oxygen gas to a cathode,
An anode containing a dehydrogenation catalyst;
A cathode containing a catalyst for reducing oxygen in the gas;
A proton conductor disposed between the anode and the cathode,
The proton conductor has a perovskite crystal structure represented by _a composition formula A _a B _1-x B ′ _x O _3-δ
A is at least one selected from group 2 elements;
B is at least one selected from Group 4 elements and Ce;
B ′ is a group 3 element, group 13 element or lanthanoid element;
0.5 <a ≦ 1.0, 0.0 ≦ x ≦ 0.5, and 0.0 ≦ δ <3,
The fuel cell, wherein the charge of the composition formula deviates from electrical neutrality in a range of −0.13 or more and less than +0.14. A is at least one selected from the group consisting of Ba, Sr and Ca;
B is at least one selected from the group consisting of Zr, Ce and Ti;
2. The fuel cell according to claim 1, wherein B ′ is one selected from the group consisting of Yb, Y, Nd, and In.   3. The fuel cell according to claim 1, wherein x = 0, and the charge of the composition formula deviates from electrical neutrality in a range of greater than 0 and less than 0.14.   The fuel cell according to claim 1, wherein 0.0 <x ≦ 0.50, and the charge of the composition formula deviates from electrical neutrality in a range of −0.13 or more and less than 0. The dehydrogenation catalyst is a metal or alloy containing at least one selected from the group consisting of Ni, Pt and Pd.
The fuel cell according to any one of claims 1 to 4. The dehydrogenation catalyst is an oxide containing at least one selected from the group consisting of Ni, Pt and Pd.
The fuel cell according to any one of claims 1 to 4. The anode further includes a support,
The carrier is composed of Al ₂ O ₃ , SiO ₂ , or ZrO ₂ ,
The dehydrogenation catalyst is a metal or alloy containing at least one selected from the group consisting of Ni, Pt and Pd, and is supported on the surface of the support.
The fuel cell according to any one of claims 1 to 4. The catalyst for reducing oxygen is a metal or alloy containing at least one selected from the group consisting of Pt and Ru.
The fuel cell according to any one of claims 1 to 4. The oxygen reducing catalyst is an oxide containing at least one selected from the group consisting of Pt and Ru.
The fuel cell according to any one of claims 1 to 4. The catalyst for reducing oxygen is an oxide containing at least one selected from the group consisting of Co, Fe and Mn.
The fuel cell according to any one of claims 1 to 4. The catalyst for reducing oxygen is an oxide having a perovskite crystal structure represented by a composition formula CDO _3-δ ,
C includes at least one selected from the group consisting of Ba, Sr, Ca, La and Sm,
The D includes at least one selected from the group consisting of Zr and Ce and Ru, or includes at least one selected from the group consisting of Ni, Fe, Co, and Mn.
The fuel cell according to any one of claims 1 to 4. The catalyst for reducing oxygen is an oxide having a K ₂ NiF ₄ type crystal structure represented by a composition formula La _2-w Sr _w NiO _4-δ .
Satisfies 0 ≦ w ≦ 0.5,
The fuel cell according to any one of claims 1 to 4. The catalyst for reducing oxygen is an oxide having a perovskite crystal structure represented by a composition formula EF _1-z F ′ _z O _3−δ ,
E includes at least one selected from the group consisting of Ba, Sr and Ca,
F includes at least one selected from the group consisting of Zr and Ce and Ru.
F ′ is Y or In or a trivalent lanthanoid element;
Satisfies 0.10 <z <0.80,
The fuel cell according to any one of claims 1 to 4.

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