JP2017171963A - Electrode for carbon dioxide reduction and carbon dioxide reduction device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively reduce COwith an Mn complex catalyst.SOLUTION: An electrode for carbon dioxide reduction has an electrode base material 12 comprising a metal or a semiconductor, and a catalyst layer 18 disposed on the surface of the electrode base material 12. The catalyst layer 18 comprises an Mn complex catalyst in which an electron-withdrawing substituent is introduced to a diimine ligand, and a carbon material interposed between the electrode base material 12 and the Mn complex catalyst.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a carbon dioxide reduction electrode for a carbon dioxide reduction reaction and a carbon dioxide reduction device having a carbon dioxide reduction electrode.

There have been many proposals for the reduction of carbon dioxide (CO ₂ ). Among these, Non-Patent Document 1 is cited as one using a Mn complex catalyst. In Non-Patent Document 1, the following Mn (diimine) (CO) ₃ Br is used as a Mn complex catalyst as a carbon dioxide reduction catalyst, and CO ₂ is electrochemically reduced in an organic solvent containing 5% water. Yes.

Patent Documents 1 to 3 show that carbon fibers or carbon nanotubes are used for the electrodes. Patent Document 1 discloses that a complex is applied to a carbon fiber on a semiconductor electrode and attached to form a CO ₂ reducing electrode. Patent Document 2 discloses electrochemical reduction of CO ₂ in water using a metal or metal compound and a carbon fiber electrode. Patent Document 3 describes oxygen electrochemical reduction using a metal or complex and a carbon fiber electrode, and is used as an electrode for a fuel cell. It has also been shown that carbon fibers and carbon nanotubes are used to increase the reaction surface area.

Further, Non-Patent Document 2, the introduction of strong electron-withdrawing substituent in Diimine (diimine) ligand of Re complex catalyst, the reduction potential for (lowest unoccupied molecular orbital) is too lowered, CO ₂ reduction activity Has been shown to be lost.

Japanese Patent Laying-Open No. 2015-6150 Japanese Patent Laid-Open No. 5-57131 International Publication No. WO2007 / 023964

Bourrez, Marc et al. Angew. Chem. Int. Ed. 2011, 50, 9903 K. Koike et al. Organometallics 1997, 16, 5724-5729 B. Gholamkhass et al. Inorganic Chemistry 205, 44, 2326-2336

  Here, in Patent Document 1, a Mn (dimine) complex is used in electrochemical carbon dioxide reduction. However, the reaction is carried out in an organic solvent, and a very high overvoltage (750-850 mV) is required (the Mn complex catalyst reported so far reduces carbon dioxide at an overvoltage of 400 mV or less. Can not). As an electrochemical catalyst, the lower the operating overvoltage, the better the catalyst. Furthermore, the carbon dioxide reduction reaction is ideally desired to be a reaction using water as an electron source, similar to plants.

Here, as a technique for reducing the overvoltage, it is conceivable to lower the lowest unoccupied orbit (LUMO) of the complex catalyst in which electrons are accumulated by a strong electron-withdrawing substituent. However, as reported in Non-Patent Documents 2 and 3, there is a problem that CO ₂ reduction activity is lost by lowering LUMO.

  The present invention includes an electrode base material made of a metal or a semiconductor, an Mn complex catalyst that is disposed on the surface of the electrode base material, and in which an electron-withdrawing substituent is introduced into a dimine ligand, and the electrode base material And a carbon material interposed between the Mn complex catalyst.

  The electron-withdrawing substituent introduced into the diimine ligand is preferably a carboxylic acid ester.

  Further, the structural formula of the carboxylic acid ester is —COOR, and R preferably has an alkyl group at a site chemically bonded to COO.

  Moreover, it is preferable that the carbon material includes at least one of a nanocarbon material, a carbon cloth, and carbon paper.

  The carbon dioxide reduction device according to the present invention includes a first electrode that is the above-described electrode for carbon dioxide reduction, a second electrode that is electrically connected to the first electrode and causes an oxidation reaction, and the first electrode. And a solvent containing water for immersing the second electrode.

  Moreover, the overvoltage of CO production with respect to carbon dioxide reduction in the first electrode is 400 mV.

In order to lower the overvoltage, a Mn complex catalyst into which strong electron-attracting static arousal is introduced is introduced, and a carbon material having a high hydrogen overvoltage and capable of transferring electrons is used as a carrier. By using carbon, it becomes easy to cause a CO ₂ reduction reaction in water, and it becomes an environment where CO ₂ is easy to approach due to the hydrophobicity of the carrier, and the Mn complex has almost no activity due to the effect of lowering the potential. Even a catalyst can efficiently reduce CO ₂ .

It is a schematic diagram which shows the structure of a carbon dioxide reduction apparatus. It is a figure which shows the structure of the electrode for carbon dioxide reduction. It is a figure which shows the other structure of the electrode for carbon dioxide reduction. It is a schematic diagram which shows the structure of an electrochemical analyzer.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments described herein.

Basic configuration
In FIG. 1, the schematic diagram of the electrolysis apparatus (carbon dioxide reduction apparatus) using the electrode 1 for carbon dioxide reduction which concerns on this embodiment is shown. In the reaction cell 4, an aqueous solution in which an electrolyte and carbon dioxide gas are dissolved is stored, and a pair of electrodes (electrode for reducing carbon dioxide (cathode) 1, oxidation electrode (anode) 2) is immersed in the aqueous solution. The carbon dioxide reduction electrode 1 and the oxidation electrode 2 are connected via a DC power source 3. A minus voltage is applied to the carbon dioxide reduction electrode 1, and a plus voltage is applied to the oxidation electrode 2. A carbon dioxide reducing Mn complex catalyst is disposed on the surface of the carbon dioxide reducing electrode 1. The room on the carbon dioxide reduction electrode 1 side and the room on the oxidation electrode 2 side may be partitioned by an ion exchange membrane or the like.

With such a configuration, a reduction reaction occurs in the carbon dioxide reduction electrode 1, and an oxidation reaction occurs in the oxidation electrode 2. For example, in the oxidation electrode 2, H ₂ O is oxidized to O ₂ gas, and H ⁺ is obtained. On the other hand, in the carbon dioxide reduction electrode 1, CO ₂ is reduced to obtain CO, HCOOH, CH _{4 and the} like.

"Electrode for carbon dioxide reduction"
FIG. 2 is a schematic diagram illustrating a configuration of the carbon dioxide reduction electrode 1 according to the embodiment. An electrode base material 12 made of stainless steel (SUS) is disposed on one surface side of the glass substrate 10. A Cu tape 16 having a copper wire 14 connected to an end portion (upper end portion in the figure) is pasted on the electrode substrate 12.

  A catalyst layer 18 is formed so as to cover the surface of the electrode substrate 12 (and a part of the Cu tape 16). The catalyst layer 18 is composed of a carbon material and a Mn complex catalyst. In this example, the carbon nanotube layer 18 a and the Mn complex catalyst-coated carbon paper 18 b are formed from the surface side of the electrode base 12.

  Moreover, the electrode base material 12 and the peripheral part of the catalyst layer 18 are covered with a protective layer 20 formed of silicone. The Cu tape 16 is also covered with the protective layer 20, and the copper wire 14 extends from the side wall of the protective layer 20.

  The electrode substrate 12 is preferably made of a metal such as stainless steel, but various semiconductors can also be used.

"Mn complex catalyst"
Here, as the Mn complex catalyst used in the catalyst layer 18 (Mn complex catalyst-coated carbon paper 18b), a catalyst obtained by introducing a carboxylic acid ester which is an electron-withdrawing substituent into a diimine ligand is preferable. Specifically, a Mn complex catalyst (Mn {4,4′-di (1-H-1-pyrrolypropyl carbonate) -2,2′-bypyridine} (CO) ₃ MeCN] ⁺ ) having the following chemical formula may be mentioned.

In the Mn complex catalyst, a carboxylic acid ester which is an electron-withdrawing substituent is introduced into the diimine ligand. Thereby, the overvoltage in CO ₂ reduction can be lowered. The overvoltage for CO ₂ reduction in water can be lowered to 400 mV or less.

  Note that the structural formula of the carboxylic acid ester is —COOR, and R has an alkyl group at a site chemically bonded to COO. Further, the substituent introduced into the diimine ligand may be other than the carboxylate ester as long as it is an electron-withdrawing substituent.

"Carbon material"
A carbon nanotube layer 18a is disposed between the electrode substrate 12 and the Mn complex catalyst-coated carbon paper 18b. That is, since the Mn complex catalyst is applied and formed on the Mn complex catalyst-coated carbon paper 18b, the carbon paper and the carbon nanotube layer 18a are interposed between the Mn complex catalyst and the electrode substrate 12.

The carbon material is conductive and has a high hydrogen overvoltage. By covering the surface of the electrode substrate 12 with such a carbon material, it is possible to prevent a reduction reaction from occurring on the surface of the electrode substrate 12. For this reason, electrons can be efficiently supplied from the electrode substrate 12 to the Mn complex catalyst, and the CO ₂ reduction reaction can be promoted by the Mn complex catalyst. In the present embodiment, the surface of the electrode substrate 12 is covered with the carbon nanotube layer 18a. By covering the surface of the electrode substrate 12 with a dense layer of nano-sized carbon, the CO ₂ reduction reaction as described above can be driven more effectively. The carbon material may be any one of nanocarbon materials such as carbon nanotubes, carbon cloth, and carbon paper.

Furthermore, the carbon material is hydrophobic, and is easily contacted by CO ₂ that is a nonpolar molecule, and water and protons that are polar molecules are difficult to approach. For this reason, the presence of carbon makes it difficult for water and protons to approach the Mn complex catalyst, thereby improving the CO ₂ reduction performance.

As described above, by using the carbon material, it is possible to suppress the reduction reaction in the electrode base material and facilitate the contact between CO ₂ in water and the Mn complex catalyst, thereby effectively performing the CO ₂ reduction reaction.

"Other configuration examples"
FIG. 3 shows a carbon dioxide reduction electrode 1 according to another configuration example. In this example, the carbon layer 18c coated with a Mn complex catalyst is provided. The Mn complex catalyst-coated carbon layer 18c is mixed by applying a Mn complex catalyst to the carbon nanotube layer. Also in the catalyst layer 18 of such a Mn complex catalyst, a carbon material exists between the electrode substrate 12 and the Mn complex catalyst, and the same effect as the carbon dioxide reduction electrode 1 of FIG. 2 is obtained. . If the Mn complex catalyst can be supported on the carbon material, the Mn complex catalyst may be supported on the carbon material by a method other than coating.

  For the electrochemical measurement, an electrochemical analyzer was used, and measurement was performed by a three-electrode method. FIG. 4 shows a schematic diagram of an electrochemical analyzer. Thus, in addition to the carbon dioxide reduction electrode 1 and the oxidation electrode 2, the reference electrode 5 is provided in the reaction cell 4, and the potential of the carbon dioxide reduction electrode 1 is set to the potential of the reference electrode 5 by the potentiostat 6. Sweep and measure the amount of current. A platinum electrode was used for the oxidation electrode, Ag / AgCl was used for the reference electrode 5, and a Pyrex (registered trademark) cell was used for the reaction cell. Moreover, the ion chromatograph and the gas chromatograph were used for evaluation of the product accompanying an electrochemical measurement.

○ Example 1
A copper wire was connected to a commercially available SUS foil, attached to a glass substrate, and the periphery was sealed with silicon rubber to form an electrode. Thereafter, about 4 mg of carbon nanotubes were applied and dried at 60 ° C. After applying an aqueous solution in which carbon nanotubes were diffused once again to the created electrode, and slightly blowing off water, the complex catalyst (Mn {4,4'-di (1-H-1-pyrrolyproplyl carbonate) -2,2 ' -bipyridine} (CO) ₃ MeCN] A MeCN solution containing ⁺ FeC1 ₃ pyrrole is applied to carbon paper, dried, and then placed on the carbon nanotube layer to form a carbon dioxide reduction electrode (working electrode (cathode) Electrode)).

A 0.1 M potassium borate aqueous solution (pH = 9, K ₂ B ₄ O ₇ ) was used as the electrolytic solution, and CO ₂ gas was passed through the aqueous solution. In the experiment, the current-time measurement was performed for 1 hour in the dark with the applied voltage at -1.0V.

O Comparative Example 1
The same experiment was performed by applying only the Mn complex catalyst without using carbon paper and without applying carbon nanotubes under the experimental conditions of Example 1.

O Comparative Example 2
Under the experimental conditions of Example 1, the same experiment was performed without applying the Mn complex catalyst.

O Comparative Example 3
The same experiment was conducted after dissolving the Mn complex catalyst in a 0.1 M tetrabutylammonium perchlorate MeCN solution: water mixed solvent without applying the Mn complex catalyst under the experimental conditions of Example 1.

* Comparative example 4
The same experiment was performed by applying the already reported complex catalyst Mn (diimine) (CO) ₃ Br under the experimental conditions of Example 1.

O Example 2
Mn complex catalyst [Mn {4,4′-di (1-H-1-pyrrolyproplyl carbonate) -2,2′-bipyridine} (CO) in which the monodentate ligand is changed to B under the experimental conditions of Example 1 ₃ Br] was applied to conduct the same experiment.

Example 3
The same experiment was performed under the experimental conditions of Example 1 except that the solvent was changed from a 0.1 M potassium borate aqueous solution to a 0.1 M phosphate buffer aqueous solution.

O Example 4
The same experiment was performed by changing the applied voltage from -1.0 V to -0.8 V under the experimental conditions of Example 1.

O Example 5
Under the experimental conditions of Example 1, a carbon nanotube film was formed on SUS by using about 15 mg of carbon nanotubes to be applied without using carbon paper. The same amount of Mn complex catalyst as in Example 1 was applied thereto, and the same experiment as in Example 1 was performed.

O Comparative Example 5
In Example 5, the same reaction was performed by reducing the amount of carbon nanotubes to be applied to about 1 mg.

Table 1 shows the experimental results of Examples 1 to 5 and Comparative Examples 1 to 5.

  In Examples 1 to 5, CO was generated under any conditions, but in Comparative Example 1-4, almost no CO was observed.

From Comparative Example 1, it can be seen that the combination of carbon and the Mn complex catalyst is important, and from Comparative Example 2, it can be seen that the CO ₂ reduction reaction does not occur without the Mn complex catalyst. From Comparative Example 3, even if the Mn complex catalyst according to the present embodiment is used in the same manner as the conventionally reported Mn complex catalyst, the CO ₂ reduction reaction does not proceed. This is probably because the LUMO (lowest empty level) position was lowered too much as in the conventional report. Comparative Example 4, since the overvoltage is high for CO ₂ reduction in the Mn complex catalyst has been reported so far, the catalytic reaction does not proceed even in combination with carbon. On the other hand, with the combination of the Mn complex catalyst and carbon of the present embodiment, the CO ₂ reduction reaction can be effectively performed even when the overvoltage at which the Mn complex catalyst reported so far does not operate is 400 mV or less. That is, in the present embodiment, by introducing an electron-withdrawing substituent into the diimine ligand of the Mn complex catalyst, the CO ₂ reduction overvoltage is reduced, and the Mn complex catalyst and the carbon material with reduced overvoltage are added. In combination, CO ₂ reduction in water can occur with an overvoltage of 400 mV or less.

From Example 2, the substituent introduced into the monodentate ligand is not MeCN, and there is no problem even if it is changed to another. However, since the CO ₂ reduction performance is lowered, it is ideal that it is easily detached such as MeCN.

  From Example 3, there is no problem even if the solvent is other than the aqueous potassium borate solution. From Example 4, it was proved that it can be driven even with an applied voltage of −1.0 V or less. From Example 5, it has been found that only carbon nanotubes can be operated. From Example 5 and Comparative Example 5, it was found that when the amount of carbon material (carbon nanotubes) to be applied is small, hydrogen is generated from the SUS surface, and the Faraday efficiency and the production amount are greatly reduced. Therefore, the amount of carbon nanotubes to be applied is desirably 2 mg or more.

  From Examples 1 to 5 and Comparative Examples 1 to 5, an electron-withdrawing substituent is introduced into the diimine ligand on the surface of the electrode substrate (electrode substrate 12) as in this embodiment. At this time, the carbon dioxide reduction reaction can be promoted by interposing a carbon material between the electrode substrate and the Mn complex catalyst.

  1 Carbon dioxide reduction electrode, 2 oxidation electrode, 3 DC power supply, 4 reaction cell, 5 reference electrode, 6 potentiostat, 10 glass substrate, 12 electrode base material, 14 copper wire, 16 Cu tape, 18 catalyst layer, 18a carbon Nanotube layer, 18b Mn complex catalyst coated carbon paper, 18c Mn complex catalyst coated carbon layer, 20 protective layer.

Claims (6)

An electrode substrate made of metal or semiconductor;
An Mn complex catalyst disposed on the surface of the electrode substrate and having an electron-withdrawing substituent introduced into the dimine ligand;
A carbon material interposed between the electrode substrate and the Mn complex catalyst;
including,
Carbon dioxide reduction electrode. The carbon dioxide reduction electrode according to claim 1,
The electron-withdrawing substituent introduced into the diimine ligand is a carboxylic acid ester.
Carbon dioxide reduction electrode. The carbon dioxide reduction electrode according to claim 2,
The structural formula of the carboxylic acid ester is —COOR, and R has an alkyl group at a site chemically bonded to COO.
Carbon dioxide reduction electrode. It is an electrode for carbon dioxide reduction according to any one of claims 1 to 3,
The carbon material includes at least one of nanocarbon material, carbon cloth, and carbon paper,
Carbon dioxide reduction electrode. A first electrode which is an electrode for carbon dioxide reduction according to any one of claims 1 to 4,
A second electrode electrically connected to the first electrode and causing an oxidation reaction;
A solvent containing water for immersing the first electrode and the second electrode;
A carbon dioxide reduction device. The carbon dioxide reduction device according to claim 5,
The overvoltage for carbon dioxide reduction at the first electrode is driven at 400 mV or less.
Carbon dioxide reduction device.