阅读说明：本技术 一种吡嗪基多孔共价有机框架材料、其制备方法及在燃料电池质子传导材料中的应用 (Pyrazinyl porous covalent organic framework material, preparation method thereof and application thereof in proton conducting material of fuel cell ) 是由 李培洲 栾天翔 于 2020-12-10 设计创作，主要内容包括：本发明提供一种吡嗪基多孔共价有机框架材料、其制备方法及在燃料电池质子传导材料中的应用。本发明利用芘-4,5,9,10-四酮和2,3,6,7,10,11-六氨基三苯盐酸盐为原料合成了一种具有高结晶性、多孔以及规则孔道,且结构稳定的吡嗪基COFs；对这种含有高密度的吡嗪和芘基团的COF分别进行磺化修饰、负载磷酸以及磺化修饰后再负载磷酸后得到了一系列功能化的吡嗪基COFs材料。本发明COFs材料在广泛的温度和湿度条件下均展现出良好的质子传导能力。(The invention provides a pyrazinyl porous covalent organic framework material, a preparation method thereof and application thereof in a proton conducting material of a fuel cell. The invention synthesizes the pyrazinyl COFs which have high crystallinity, porous and regular pore canals and stable structure by using pyrene-4, 5,9, 10-tetrone and 2,3,6,7,10, 11-hexaamino triphenyl hydrochloride as raw materials; the COFs containing the high-density pyrazine and pyrenyl groups are subjected to sulfonation modification, phosphoric acid loading and phosphoric acid loading after sulfonation modification respectively to obtain a series of functionalized pyrazinyl COFs materials. The COFs material of the invention shows good proton conductivity under wide temperature and humidity conditions.)

1. A pyrazinyl porous covalent organic framework material, wherein the organic framework material is pyrazinyl COFs, sulphonation-modified pyrazinyl COFs, pyrazinyl COFs loaded with proton carriers, or pyrazinyl COFs sulphonation-modified-proton carriers;

the pyrazinyl COFs are two-dimensional porous polymers having a structural unit represented by the following formula (I);

wherein R is₁、R₂、R₃、R₄、R₅、R₆Each independently selected from H or SO₃H, said R₁、R₂、R₃、R₄、R₅、R₆The same or different.

2. The pyrazinyl porous covalent organic framework material of claim 1, wherein said protic carrier is phosphoric acid or imidazole.

3. The pyrazinyl porous covalent organic framework material as claimed in claim 1, wherein the organic framework material has a specific surface area of 500-600m²Per g, the aperture is 1-5 nm; the organic framework material has good crystallinity.

4. A method for preparing pyrazinyl porous covalent organic framework materials according to any one of claims 1 to 3, wherein said pyrazinyl COFs are prepared by a method comprising the steps of: in an organic solvent A, under the catalysis of p-toluenesulfonic acid, pyrene-4, 5,9, 10-tetraone reacts with 2,3,6,7,10, 11-hexa-amino triphenyl hydrochloride, and then the pyrazinyl COFs are prepared by washing and drying.

5. The method of preparing a pyrazinyl porous covalent organic framework material according to claim 4, comprising one or more of the following conditions:

i. the organic solvent A is a mixed solvent of N-methyl pyrrolidone and mesitylene; the volume ratio of the N-methyl pyrrolidone to the mesitylene is 1-3: 1; the volume ratio of the amount of the pyrene-4, 5,9, 10-tetraone substance to the organic solvent A is 0.01-0.05 mol/L;

ii. The washing is to wash the mixture for 2 to 3 times by sequentially using DMF, water, methanol and dichloromethane, and then to perform Soxhlet extraction for 20 to 30 hours by using THF;

iii, the drying temperature is 80-120 ℃.

6. The method of preparing a pyrazinyl porous covalent organic framework material according to claim 4, comprising one or more of the following conditions:

i. the molar ratio of the pyrene-4, 5,9, 10-tetraone, p-toluenesulfonic acid and 2,3,6,7,10, 11-hexaamino triphenyl hydrochloride is (1-2): (30-40): 1; preferably, the mole ratio of the pyrene-4, 5,9, 10-tetraone to the p-toluenesulfonic acid to the 2,3,6,7,10, 11-hexaamino-triphenylhydrochloride is 1.5:35: 1;

ii. The reaction temperature of pyrene-4, 5,9, 10-tetraone and 2,3,6,7,10, 11-hexa-amino triphenyl hydrochloride is 120-240 ℃, and the reaction time is 3-15 days; preferably, the reaction temperature is 170-190 ℃, and the reaction time is 4-6 days.

7. The method for preparing pyrazinyl porous covalent organic framework materials according to any one of claims 1 to 3, wherein said sulfonated modified pyrazinyl COFs is prepared by a method comprising the steps of: dispersing the prepared pyrazinyl COFs in an organic solvent B, dropwise adding chlorosulfonic acid at the temperature of-20-10 ℃, carrying out heating reaction after dropwise adding is finished, and then washing and drying to prepare the sulfonated and modified pyrazinyl COFs.

8. The method of preparing a pyrazinyl porous covalent organic framework material according to claim 7, comprising one or more of the following conditions:

i. the organic solvent B is dichloromethane, N-methyl pyrrolidone, mesitylene or tetrahydrofuran; the volume ratio of the mass of the pyrazinyl COFs to the organic solvent B is 0.5g/L-3 g/L;

ii. The mass ratio of the pyrazinyl COFs to the chlorosulfonic acid is 1: 25-35;

iii, the dropping temperature is-5-5 ℃; the heating reaction temperature is 20-60 ℃, and the heating reaction time is 2 days to 10 days; preferably, the heating reaction temperature is 20-40 ℃, and the heating reaction time is 2 days to 4 days.

9. The method for preparing pyrazinyl porous covalent organic framework materials according to any one of claims 1 to 3, wherein said proton carrier-loaded pyrazinyl COFs or sulfonate modified proton carrier-loaded pyrazinyl COFs are prepared by a method comprising the steps of:

and soaking the prepared pyrazinyl COFs or the sulfonated modified pyrazinyl COFs in a proton carrier water solution of 2-4mol/L for 12 hours, and then washing and drying to obtain the pyrazinyl COFs or the sulfonated modified proton carrier loaded with proton carriers.

10. Use of a pyrazinyl porous covalent organic framework material according to any one of claims 1 to 3 as a proton exchange membrane in a fuel cell as a proton conducting material in a fuel cell.

Technical Field

The invention relates to a pyrazinyl porous covalent organic framework material, a preparation method thereof and application thereof in a proton conduction material of a fuel cell, belonging to the field of novel energy material in organic functional materials, namely a proton exchange membrane material of the fuel cell.

Background

In future social life of low carbon, the proton exchange membrane fuel cell has the characteristics of high conversion efficiency, environmental friendliness and the like, and is expected to become a powerful alternative scheme based on the conventional fossil fuel power technology. The proton exchange membrane is one of the core technologies of the fuel cell, and the proton conduction performance of the proton exchange membrane directly affects the final performance of the whole fuel cell. The material which has been commercialized in the technical field of proton exchange membranes at present is a perfluorosulfonic acid-based electrolyte polymer called Nafion; however, the application and popularization of the material are severely restricted by the complicated synthesis steps, the limited use temperature and humidity environment, the high cost and the like.

In recent years, porous covalent organic framework materials (COFs) have received much attention for their preparation and application development due to their ease of synthesis and often their excellent physicochemical properties; however, its application to fuel cell proton exchange membranes is also limited by structural stability and proton conductivity. For example, chinese patent document CN110305347A discloses a modified chitosan-based proton exchange membrane and a preparation method thereof; the preparation method comprises the following steps: adding the covalent organic framework material powder into deionized water, and preparing covalent organic framework material aqueous dispersion through dispersion; dissolving chitosan powder in acetic acid aqueous solution to prepare chitosan acetic acid aqueous solution; mixing the covalent organic framework material water dispersion liquid and a chitosan acetic acid aqueous solution to prepare a mixed solution, and removing the solvent to obtain a composite membrane; and (3) dipping the composite membrane by using a sulfuric acid solution to obtain a crosslinked composite membrane, cleaning to be neutral, and drying to obtain the crosslinked composite membrane. The proton exchange membrane of the invention has low volume swelling ratio, but still has the problem of poor proton conductivity. For another example, chinese patent document CN111269432A discloses a two-dimensional covalent organic framework material and its preparation and application; the two-dimensional covalent organic framework material is assembled by performing Sonogashira coupling reaction and deprotection on benzene compound 1,3, 5-tri (4-bromophenyl) benzene containing bromine atoms and finally reacting with tert-butyloxycarbonyl protecting group through Schiff base. The covalent organic framework material is cheap in raw materials, simple in synthesis process and convenient to purify; however, when used as a proton exchange membrane, the proton conductivity is still poor.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a pyrazinyl porous covalent organic framework material, a preparation method thereof and application thereof in a proton conducting material of a fuel cell. The invention synthesizes a pyrazinyl COF with high crystallinity, porous and regular pore canals and stable structure by using pyrene-4, 5,9, 10-tetrone and 2,3,6,7,10, 11-hexa-amino triphenyl hydrochloride as raw materials; the COFs containing the high-density pyrazine and pyrenyl groups are subjected to sulfonation modification, phosphoric acid loading and phosphoric acid loading after sulfonation modification respectively to obtain a series of functionalized pyrazinyl COFs materials. The COFs material of the invention shows good proton conductivity under wide temperature and humidity conditions.

The technical scheme of the invention is as follows:

a pyrazinyl porous covalent organic framework material is prepared from pyrazinyl COFs (PyHATP-1 for short) and sulfonating modified pyrazinyl COFs (PyHATP-1-SO for short)₃H) Pyrazinyl COFs loaded with proton carriers or sulphonation modified-pyrazinyl COFs loaded with proton carriers;

the pyrazinyl COFs are two-dimensional porous polymers having a structural unit represented by the following formula (I);

wherein R is₁、R₂、R₃、R₄、R₅、R₆Each independently selected from H or SO₃H, said R₁、R₂、R₃、R₄、R₅、R₆The same or different.

Preferably according to the invention, the proton carrier is phosphoric acid or imidazole.

According to the invention, the specific surface area of the organic framework material is preferably 500-600m²Per g, the aperture is 1-5 nm; the organic framework material has good crystallinity.

The preparation method of the pyrazinyl COFs comprises the following steps: in an organic solvent A, under the catalysis of p-toluenesulfonic acid, pyrene-4, 5,9, 10-tetraone reacts with 2,3,6,7,10, 11-hexa-amino triphenyl hydrochloride, and then the pyrazinyl COFs are prepared by washing and drying.

According to the invention, the organic solvent A is preferably a mixed solvent of N-methyl pyrrolidone and mesitylene; the volume ratio of the N-methyl pyrrolidone to the mesitylene is 1-3: 1; the volume ratio of the amount of the pyrene-4, 5,9, 10-tetraone substance to the organic solvent A is 0.01-0.05 mol/L.

According to the invention, the mole ratio of the pyrene-4, 5,9, 10-tetraone, the p-toluenesulfonic acid and the 2,3,6,7,10, 11-hexaamino triphenyl hydrochloride is (1-2): 1 (30-40): 1; preferably, the mole ratio of the pyrene-4, 5,9, 10-tetraone, the p-toluenesulfonic acid and the 2,3,6,7,10, 11-hexaamino-triphenylhydrochloride is 1.5:35: 1.

According to the invention, the reaction temperature of pyrene-4, 5,9, 10-tetraone and 2,3,6,7,10, 11-hexa-amino-triphenyl hydrochloride is preferably 120-240 ℃, and the reaction time is preferably 3-15 days; preferably, the reaction temperature is 170-190 ℃, and the reaction time is 4-6 days.

According to the invention, the reaction of pyrene-4, 5,9, 10-tetrone and 2,3,6,7,10, 11-hexa-amino-triphenyl-hydrochloride is preferably carried out in a thick-walled pressure-resistant tube or ampoule.

According to the invention, the washing is preferably carried out 2 to 3 times by sequentially using DMF, water, methanol and dichloromethane, and then the Soxhlet extraction is carried out for 20 to 30 hours by using THF.

Preferably, according to the invention, the drying temperature is 80 to 120 ℃.

The preparation method of the sulfonated and modified pyrazinyl COFs comprises the following steps: dispersing the prepared pyrazinyl COFs in an organic solvent B, dropwise adding chlorosulfonic acid at the temperature of-20-10 ℃, carrying out heating reaction after dropwise adding is finished, and then washing and drying to prepare the sulfonated and modified pyrazinyl COFs.

According to a preferred embodiment of the present invention, the organic solvent B is dichloromethane, N-methylpyrrolidone, mesitylene or tetrahydrofuran; the ratio of the mass of the pyrazinyl COFs to the volume of the organic solvent B is 0.5g/L to 3 g/L.

According to the invention, the mass ratio of the pyrazinyl COFs to the chlorosulfonic acid is 1: 25-35.

According to the invention, the dropping temperature is preferably-5 to 5 ℃; the heating reaction temperature is 20-60 ℃, and the heating reaction time is 2 days to 10 days; preferably, the heating reaction temperature is 20-40 ℃, and the heating reaction time is 2 days to 4 days.

Preferably according to the invention, the washing is washing with water; the drying temperature is 60-120 ℃.

The preparation method of the proton carrier loaded pyrazinyl COFs or the sulfonation modified-proton carrier loaded pyrazinyl COFs comprises the following steps:

and soaking the prepared pyrazinyl COFs or the sulfonated modified pyrazinyl COFs in a proton carrier water solution of 2-4mol/L for 12 hours, and then washing and drying to obtain the pyrazinyl COFs or the sulfonated modified proton carrier loaded with proton carriers. The proton carrier is fixed in the COFs pore channel by pyrazinyl and sulfonic acid groups through ionic bonds or hydrogen bonds.

Preferably according to the invention, the proton carrier is phosphoric acid or imidazole. When the proton carrier is phosphoric acid, the obtained pyrazine-based COFs carrying the proton carrier are abbreviated as H₃PO₄@ PyHATP-1, sulfonation-modified pyrazinyl COFs abbreviated as H₃PO₄@PyHATP-1-SO₃H. The phosphoric acid (H)₃PO₄) Has high proton concentration and low volatility (>158 deg.c), high mass mobility.

According to the invention, the soaking time is within the range of 0-12 h, the longer the soaking time is, the higher the proton conductivity is, and when the soaking time exceeds 12h, the proton conductivity is not increased any more; therefore, the soaking time was selected to be 12 hours.

The application of the pyrazinyl porous covalent organic framework material in a proton conducting material of a fuel cell, and the pyrazinyl porous covalent organic framework material is used as a proton exchange membrane in the fuel cell.

The invention has the following technical characteristics and beneficial effects:

1. the invention synthesizes novel pyrazinyl COFs containing high-density pyrazine and pyrenyl groups by using pyrene-4, 5,9, 10-tetrone and 2,3,6,7,10, 11-hexaamino triphenyl hydrochloride as raw materials, wherein the ratio of the pyrene-4, 5,9, 10-tetrone and the 2,3,6,7,10, 11-hexaamino triphenyl hydrochloride is proper, and the pyrazinyl COFs with the structure of the invention cannot be obtained if the ratio is improper; the obtained pyrazinyl COFs are sulfonated to obtain the sulfonated modified pyrazinyl COFs. The skeleton of the pyrazinyl COFs and the sulfonated and modified pyrazinyl COFs is provided with functional groups such as pyrazinyl and sulfonic acid groups, and the functional COFs have proton conductivity due to the existence of the groups. In addition, the existence of pyrazinyl and sulfonic acid groups can enhance the adsorption performance of the COFs material on proton carriers, and the pyrazinyl COFs material loaded with the proton carriers and subjected to sulfonation modification can be further prepared, so that the proton conduction capability of the material is enhanced.

2. The pyrazinyl COFs material prepared by the invention is of a porous structure, has a large specific surface area and a regular pore channel, and has high crystallinity. The pyrazinyl COFs material prepared by the method has high structural stability and excellent chemical stability, and can stably exist in various common organic solvents (acetone, dichloromethane, N-dimethylformamide and the like), concentrated hydrochloric acid (6mol/L), concentrated alkali NaOH (6mol/L) and boiling water.

3. The pyrazinyl COFs material prepared by the invention has good proton conductivity under wide temperature and humidity conditions; the proton conductivity can reach 0.88 multiplied by 10^-1S/cm, performance equivalent to that of the current commercial Nafion material (1 multiplied by 10)^-1S/cm) is a potential new material applicable to proton exchange membrane fuel cells.

Drawings

FIG. 1 is a powder X-ray diffraction pattern of PyHATP-1 synthesized in example 1 and simulated powder X-ray diffraction patterns of AA stacking and AB stacking;

FIG. 2 is a Fourier infrared spectrum of PyHATP-1 synthesized in example 1 and starting material;

FIG. 3 is a nitrogen desorption isotherm for PyHATP-1 synthesized in example 1;

FIG. 4 is a graph showing the pore size distribution of PyHATP-1 synthesized in example 1;

FIG. 5 is a comparative powder X-ray diffraction pattern of PyHATP-1 synthesized in example 1 after solvent treatment;

FIG. 6 shows PyHATP-1 and PyHATP-1-SO synthesized in example 1₃A Fourier infrared spectrum of H;

FIG. 7 is a Nyquist plot (FIG. 7a) of PyHATP-1 synthesized in example 1 at different temperatures, and H synthesized in example 4₃PO₄Nyquist plots of @ PyHATP-1 at different temperatures (FIG. 7b), PyHATP-1-SO synthesized in example 3₃Nyquist plot of H at different temperatures (FIG. 7c), H synthesized in example 5₃PO₄@PyHATP-1-SO₃Nyquist plot of H at different temperatures (fig. 7 d).

FIG. 8 shows PyHATP-1, PyHATP-1-SO synthesized in example₃H，H₃PO₄@ PyHATP-1 and H₃PO₄@PyHATP-1-SO₃Proton conduction of H is temperature dependent arrhenius.

Detailed Description

The invention will be further illustrated by means of specific embodiments in conjunction with the accompanying drawings, without limiting the scope of the invention thereto. The raw materials used in the examples are commercially available unless otherwise specified; the method is conventional unless otherwise specified, and the equipment is conventional unless otherwise specified.

Example 1

A preparation method of a pyrazinyl porous covalent organic framework material, namely PyHATP-1, comprises the following steps: pyrene-4, 5,9, 10-tetraone (0.06mmol) and 2,3,6,7,10, 11-hexa-amino-triphenyl-hydrochloride (0.04mmol) were mixed and placed in an ampoule, and then solvent N-methyl pyrrolidone (1.6mL), mesitylene (0.8mL) and catalyst 3.5mol/L p-toluenesulfonic acid aqueous solution (0.4mL) were added and mixed uniformly. After the three freezing-air extraction-unfreezing circulation processes, maintaining the negative pressure in the ampoule bottle and sealing the tube, then putting the ampoule bottle into an oven at 180 ℃ for reaction for 5 days (the temperature of the reactant is gradually increased from the low temperature after unfreezing to 180 ℃ for reaction), filtering to obtain a solid, sequentially washing the solid twice with DMF (dimethyl formamide), an aqueous solution, methanol and dichloromethane respectively, then washing the solid twice with THF (tetrahydrofuran) in a Soxhlet extractor for 24 hours, and drying the solid at 100 ℃ to obtain a black PyHATP-1 product with the molar yield of 94%.

The Fourier infrared spectra of the synthesized PyHATP-1 and the raw materials pyrene-4, 5,9, 10-tetraone (PTO) and 2,3,6,7,10, 11-hexa-amino-triphenyl Hydrochloride (HATP) are shown in FIG. 2, and it is clear that the target product is successfully prepared by the present invention.

Study of crystallinity of PyHATP-1:

the crystallinity of PyHATP-1 was examined by a powder diffractometer, and the powder X-ray diffraction pattern and the simulated powder X-ray diffraction patterns of AA deposition and AB deposition are shown in FIG. 1. PXRD shows good peak type and very high peak intensity, which indicates that PyHATP-1 has good crystallinity.

Investigation of PyHATP-1 porosity:

about 80mg of sample is weighed and activated for 12 hours at 120 ℃, and then a nitrogen 77K isothermal adsorption curve of the sample is tested by a gas adsorption instrument, wherein a nitrogen adsorption and desorption isothermal line is shown in figure 3, and a pore diameter distribution diagram is shown in figure 4. The result shows that the synthesized PyHATP-1 has higher specific surface area (559 m)²,/g) and pore size (1.76 nm).

Chemical stability test of PyHATP-1:

respectively soaking PyHATP-1 in DMF, DMSO, THF, ethanol, 6mol/L hydrochloric acid aqueous solution, 6mol/L NaOH aqueous solution, 6mol/L H₃PO₄The chemical stability of PyHATP-1 after soaking the solution in water and boiling water for 2 days was examined by a powder diffractometer, and the X-ray diffraction pattern is shown in FIG. 5. The results show that the PyHATP-1 powder peaks are well retained after treatment with these harsh conditions, which show their good stability.

Example 2

A preparation method of a pyrazinyl porous covalent organic framework material, namely PyHATP-1, comprises the following steps: pyrene-4, 5,9, 10-tetraone (0.06mmol) and 2,3,6,7,10, 11-hexa-amino-triphenyl-hydrochloride (0.04mmol) were mixed and placed in an ampoule, and then solvent N-methyl pyrrolidone (1.6mL), mesitylene (0.8mL) and catalyst 3.5mol/L p-toluenesulfonic acid aqueous solution (0.4mL) were added and mixed uniformly. Maintaining the negative pressure in the ampoule bottle, sealing the ampoule bottle, placing the ampoule bottle into an oven at 180 ℃ for reaction for 5 days (the temperature of the reactant is gradually increased from room temperature to 180 ℃ for reaction), filtering to obtain a solid, sequentially washing the solid twice with DMF (dimethyl formamide), an aqueous solution, methanol and dichloromethane, then transferring the solid into a Soxhlet extractor, washing the solid with THF (tetrahydrofuran) for 24 hours, and drying the solid at 100 ℃ to obtain a black PyHATP-1 product with the molar yield of 78%.

Example 3

A porous covalent organic skeleton material containing pyrazinyl, i.e. sulfonating modified pyrazinyl COFs (PyHATP-1-SO for short)₃H) The preparation method comprises the following steps:

60mg of PyHATP-1 powder prepared in example 1 was dispersed in 60mL of dichloro chlorideReducing the temperature to 0 deg.C in methane solution, dropwise adding 1.05ml chlorosulfonic acid, reacting at 30 deg.C for 72 hr, filtering, washing the solid with water, and vacuum drying at 100 deg.C for 24 hr to obtain dried PyHATP-1-SO₃H。

PyHATP-1-SO synthesized in this example₃The Fourier spectrum of H is shown in FIG. 6, and comparison with PyHATP-1 shows that the sulfonated modified pyrazinyl COFs were successfully prepared in this example.

Example 4

A pyrazinyl porous covalent organic framework material, namely pyrazinyl COFs (short for H) loaded with phosphoric acid₃PO₄The preparation method of @ PyHATP-1) is as follows:

60mg of PyHATP-1 prepared as described in example 1 were soaked in 3mol/L aqueous phosphoric acid for 12 hours, filtered, and the solid was washed thoroughly with distilled water until the eluate reached pH 7, and the resulting sample was dried at 120 ℃ for 24 hours to give dried, phosphate-loaded pyrazinyl COFs.

Experiments show that the soaking time is within the range of 0-12 h, the longer the soaking time is, the higher the proton conductivity is, and when the soaking time exceeds 12h, the proton conductivity is not increased any more.

Example 5

A porous pyrazinyl covalent organic framework material, namely pyrazinyl COFs (H for short) with sulfonation modification and proton carrier loading₃PO₄@PyHATP-1-SO₃H) The preparation method comprises the following steps:

60mg of PyHATP-1-SO prepared in example 3 were taken₃H was soaked in 3mol/L aqueous phosphoric acid for 12 hours, filtered, and then the solid was washed thoroughly with distilled water until the eluent reached pH 7, and then the resulting sample was dried at 120 ℃ for 24 hours to give dry sulfonated modified-phosphate loaded pyrazinyl COFs.

Experiments show that the soaking time is within the range of 0-12 h, the longer the soaking time is, the higher the proton conductivity is, and when the soaking time exceeds 12h, the proton conductivity is not increased any more.

Test examples

Testing of proton conductive properties:

the ac impedance of the pressed sheets of the materials prepared in examples 1, 3-5 was tested using an electrochemical workstation at a certain humidity and temperature, and the conductivity value was calculated using the formula σ ═ L/RA, where σ is the proton conductivity, L is the thickness of the sheet film, a is the area of the film, and R is the resistance.

Testing of proton conductivity as a function of temperature:

maintaining the humidity (98% RH) constant, changing the temperature at 30 deg.C, 40 deg.C, … deg.C, 80 deg.C, etc., and respectively measuring the AC impedance diagram, as shown in FIG. 7; the corresponding resistance values can be respectively read out through software fitting, and the proton conductivity can be calculated. From the results of fig. 7, it was found that the higher the temperature, the higher the proton conductivity.

As can be seen in FIGS. 7 and 8, H was synthesized at 80 ℃ and 98% RH₃PO₄@PyHATP-1-SO₃H has high proton conductivity up to 0.88 × 10^-1Proton conductivity of S/cm, this proton conductivity value can even be compared with that of commercial Nafion (1X 10)^-1S/cm). Meanwhile, the proton conduction activation energy of the material is lower, namely as low as 0.11eV, and is not higher than 0.4eV, which shows that the proton conduction barrier of the material is smaller.