JP2018030093A - Catalyst of gold-cerium oxide complex carried on alkaline carrier, and method for producing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a new form of gold-cerium oxide complex that has an excellent function as a catalyst and contains a gold particle and a cerium oxide covering the surface of the gold particle, and a new production method therefor.SOLUTION: A gold-cerium oxide complex catalyst is characterized in that: a gold-cerium oxide complex, which contains a gold particle and a cerium oxide covering the surface of the gold particle, is carried on an alkaline carrier. There is also provided a selective hydrogenation method using the same.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a gold-cerium oxide-supported composite catalyst supported on an alkaline carrier and a method for producing the same.

  Hydrogenation is a standard reaction in organic chemistry, and the resulting products are commercially available as a number of products. There are many compounds with multiple types of functional groups that undergo hydrogenation or hydrogenolysis, and catalysts that selectively hydrogenate or hydrocrack only some of these functional groups are known. Of these, many use platinum or palladium.

  Gold is a particularly stable metal among precious metals and has been considered a metal with poor activity as a catalyst, but exhibits excellent catalytic activity when supported on a base metal oxide as nanoparticles having a diameter of 5 nm or less. Has been discovered by Haruta et al. (Non-patent Document 1), and various gold catalysts have been studied since then.

  However, gold catalysts are generally known as oxidation catalysts, and there are few reports as reduction catalysts. In Patent Document 1, a gold precursor stabilized by an organic ligand is subjected to oxygen plasma treatment to form a gold cluster having an appropriate size, thereby expressing selective hydrogenation activity.

  The gold catalyst used for the selective hydrogenation described above has not been able to be controlled with sufficient selectivity, and development of a catalyst capable of controlling the reaction with high selectivity is desired.

  Further, it is known that the gold cluster catalyst has a problem in durability because gold is exposed on the surface. The gold nanoparticles may be collected on the surface of the solid support while being recovered after being used in the reaction and repeatedly used, and the reactivity may be lowered.

  Therefore, in order to use a gold catalyst industrially, it is also required to have high durability that can be repeatedly used while maintaining high selectivity.

  Further, as a technique different from Patent Document 1, in Patent Document 2, selective hydrogen activation is expressed by a surface gold-immobilized catalyst obtained by immobilizing gold nanoparticles on the surface of a carrier. However, this catalyst also has problems in durability, reactivity (activity and selectivity) because the gold nanoparticles are exposed on the surface of the support. Further, since ammonia is added to the gold compound aqueous solution during the production of the catalyst, thunder gold may be generated, which causes a problem in safety.

  Furthermore, Non-Patent Document 2 reports a gold-cerium oxide composite comprising gold particles and a cerium oxide coated on the surface of the gold particles, which has an excellent function as a catalyst. However, this gold-cerium oxide complex is prepared by reversely micellar gold solution and cerium solution, and the reverse micelle solution is mixed to proceed the redox reaction, then the micelle is broken with ethanol and recovered. In addition, there is a problem that it takes time and cost because it requires the use of an organic solvent and a surfactant.

JP2013-255887A Japanese Patent No. 5577226

M. Haruta, T. Kobayashi, H. Sano, N. Yamada, Chem. Lett., P405-408 (1987). T. Mitsudime, M. Yamamoto, Z. Maeno, T. Mizugaki, K. Jitsukawa, K. Kaneda, J. Am. Chem. Soc., P13452-13455, 137 (2015).

  Therefore, an object of the present invention is to provide a new form and manufacturing method of a gold-cerium oxide composite having gold particles and cerium oxide coated on the surface of the gold particles, which has an excellent function as a catalyst. It is to be.

  As a result of intensive studies to solve the above problems, the present inventors have supported a gold-cerium oxide composite comprising gold particles and a cerium oxide coated on the surface of the gold particles on an alkaline carrier. It was found that the gold-cerium oxide-supported composite catalyst has high hydrogenation activity, selectivity, durability, and reactivity. In addition, the inventors of the present invention have provided a gold-cerium oxide-supported composite catalyst that is inexpensive and safe by a simple method in which a mixture of a gold compound and a cerium compound is dropped into a suspension of an alkaline carrier and then dried. Found that can be manufactured. Furthermore, the present inventors have found that the gold-cerium oxide-supported composite catalyst is useful for selective hydrogenation, and have completed the present invention.

  That is, the present invention provides a gold-cerium oxide characterized in that a gold-cerium oxide composite comprising gold particles and a cerium oxide coated on the surface of the gold particles is supported on an alkaline carrier. It is a supported composite catalyst.

  The present invention also provides a gold particle and a cerium oxide coated on the surface of the gold particle, wherein a mixture of a gold compound and a cerium compound is dropped into a suspension of an alkaline carrier and then dried. This is a method for producing a gold-cerium oxide-supported composite catalyst in which a gold-cerium oxide composite containing a product is supported on an alkaline carrier.

  Furthermore, the present invention is a method for selectively hydrogenating an organic compound, wherein the organic compound is selectively hydrogenated using the gold-cerium oxide-supported composite catalyst.

  The gold-cerium oxide-supported composite catalyst of the present invention can be used in, for example, selective hydrogenation in alkenylation of epoxy, alkene of alkyne, alcoholation of aldehyde, and selective hydrogenation of polar functional groups. Since it can be implemented with high efficiency, a shortcut for synthesizing a functional material that requires a multi-step synthesis process such as a pharmaceutical intermediate is possible.

  In addition, the gold-cerium oxide-supported composite catalyst of the present invention does not require an organic solvent and a surfactant during production, and thus can be produced inexpensively and safely.

  Furthermore, since the gold-cerium oxide-supported composite catalyst of the present invention does not use harmful substances such as lead contained in the Lindlar catalyst, it is easy to use industrially.

  Furthermore, since the gold-cerium oxide-supported composite catalyst of the present invention is supported on an alkaline carrier, it can be easily recovered by filtration after use, and the recovered catalyst maintains its original activity and selectivity. Therefore, it is easy to reuse expensive gold catalysts.

It is the schematic diagram which showed the manufacture example of the gold-cerium oxide carrying | support composite catalyst of this invention. It is the schematic diagram which showed the manufacture example (nonpatent literature 2) of the conventional gold-cerium oxide composite catalyst. It is a TEM image of the gold-cerium oxide-supported composite catalyst (Au @ CeO ₂ / HT) obtained in Production Example 1 (magnification of 400,000 times). It is a HAADF-STEM image of the gold-cerium oxide-supported composite catalyst (Au @ CeO ₂ / HT) obtained in Production Example 1 (magnification 1 million times). It is an element mapping image of Au of the gold-cerium oxide supported composite catalyst (Au @ CeO ₂ / HT) obtained in Production Example 1 (magnification 1 million times). Gold prepared in Preparation Example 1 - is an element mapping image of Ce in the cerium oxide supported composite catalyst _{(Au @ CeO 2 / HT)} ( magnification of 100 thousand times). Gold prepared in Preparation Example 1 - cerium oxide supported composite catalyst (Au @ _CeO 2 / HT) of Au element mapping images, and Ce element mapping images image superimposed in (magnification of 100 thousand times). It is a TEM image of the gold-cerium oxide-supported composite catalyst (Au @ CeO ₂ / MgO) obtained in Production Example 2 (magnification 250,000 times). It is a TEM image (250,000 times magnification) of the gold-cerium oxide supported composite catalyst (Au @ CeO ₂ / Laponite) obtained in Production Example 3. FIG. 4 is a TEM image of the gold-cerium oxide-supported composite catalyst (Au @ CeO ₂ / amine-modified silica) obtained in Production Example 4 (magnification of 100,000 times).

  The gold-cerium oxide-supported composite catalyst of the present invention (hereinafter referred to as “the catalyst of the present invention”) is a gold-cerium oxide composite comprising gold particles and cerium oxide coated on the surfaces of the gold particles. Is supported on an alkaline carrier. Hereinafter, the gold-cerium oxide composite and the alkaline carrier constituting the catalyst of the present invention will be described.

In the present specification, the gold-cerium oxide composite is composed of gold nanoparticles (Au Nano Particles) and / or gold oxide nanoparticles as a core (core), and cerium oxide (mainly CeO ₂ ) around the core. In other cases, such as Ce ₂ O ₃ ) is coated, which may be expressed as “Au @ CeO ₂ ”. In addition, since the gold-cerium oxide complex is supported on an alkaline carrier, the catalyst of the present invention may be expressed as “Au @ CeO ₂ / X (X is an alkaline carrier name)”.

(Gold-cerium oxide composite)
The gold-cerium oxide composite is a composite in which cerium oxide particles are supported on the surface of gold particles. A desirable form of the gold-cerium oxide composite is a structure in which gold particles are used as nuclei (cores), and cerium oxide particles are supported on the surfaces of the gold particles as the nuclei. Here, the gold particles are particles of a gold component selected from at least one of metal gold and gold oxide, and preferably metal gold particles. The cerium oxide is at least one kind of cerium dioxide (CeO ₂ ) or dicerium trioxide (Ce ₂ O ₃ ), only cerium dioxide (CeO ₂ ), only dicerium trioxide (Ce ₂ O ₃ ). Or a mixture of cerium dioxide (CeO ₂ ) and dicerium trioxide (Ce ₂ O ₃ ).

  In the gold-cerium oxide composite, the mode of “supporting” in the case where cerium oxide is supported on the surface of the gold particle is not particularly limited. For example, cerium oxide may be dispersed and supported so as to form a sea-island structure on the surface of gold particles that become the core (core), or a substantial portion of the surface of the core (core) may be cerium. Although it is covered with an oxide, it may be in a state in which the core (core) is partially exposed, or until the entire surface of the core (core) is completely covered with cerium oxide. There may be various states. Further, the gold-cerium oxide composite may form a cluster of gold-cerium oxide particles, and when gold particles are exposed on the surface of the cluster particles, the surface is further made of cerium oxide. It may be coated.

  According to such a loading mode, the state of the cerium oxide that is a component of the gold-cerium oxide composite is a particle state, a state in which adjacent particles are connected to each other, the connection is increased, and the surface of the nucleus is reticulated. And the gold particle surface is exposed in the network, and further, the cerium oxide is in a layered state and completely covers the gold particle surface.

The state of the cerium oxide is also affected by the CeO ₂ / Au molar ratio described below. In any case, it is desirable that the cerium oxide particles cover the gold particles so that the gold as the core (core) is in contact with the cerium oxide covering the surface as much as possible.

  The mode in which the core (core) made of gold particles is coated with cerium oxide is not particularly limited, but the core (core) made of gold particles is completely covered with cerium oxide, and the cerium oxide fine particles are coated. The carbon in a compound having a hydrogenation reaction site that is generally hydrogenated and a carbon-carbon triple bond that is hydrogenated in the present invention, or a polar functional group when the substrate can contact gold through the pores. The reactivity and selectivity of the carbon triple bond or polar functional group may be excellent. This is because hydrogen molecules having hydrogenation activity of carbon-carbon double bonds occur at the active sites on the surface of the gold particles, but cis from the carbon-carbon triple bonds at the active sites at the gold-cerium oxide interface. -Selectivity appears to occur because the heterogeneous cleavage of hydrogen molecules prioritizes selective hydrogenation to carbon-carbon double bonds and selective hydrogenation of polar functional groups such as epoxy groups and nitro groups. Because.

  The cerium oxide particle which coat | covers the nucleus (core) which consists of a gold particle which is a component of a gold-cerium oxide composite body is not restrict | limited, A primary particle may be sufficient and a secondary particle may be sufficient. The average particle size of the cerium oxide particles is preferably 2 to 40 nm, and more preferably 4 to 20 nm. In the present application, the “average particle diameter” refers to an average value of diameters of an arbitrary number of particles by observation with an electron micrograph. When the average particle diameter (shell particle diameter) of the cerium oxide particles is 2 nm or more, the selectivity is effective, and when it is 40 nm or less, the activity is improved.

  Here, the gold particles are not particularly limited as long as they contain gold (Au), and are preferably metal gold. The gold particles may be primary particles or secondary particles. The average particle diameter of the gold particles is preferably 1 to 30 nm, and more preferably 1 to 10 nm. In the present specification, the “average particle diameter” means an average value of the diameters of an arbitrary number of particles observed with an electron microscope.

(Molar ratio of gold-cerium oxide composite [CeO ₂ / Au])
The composition ratio of gold and cerium oxide in the gold particles of the gold-cerium oxide composite is a molar ratio [CeO in terms of the number of moles of cerium oxide (CeO ₂ ) / gold (Au) as a metal. ₂ / Au] = 10-50 is preferable, 15-40 is more preferable, and 20-30 is still more preferable. When the [CeO ₂ / Au] molar ratio is 10 or more, the selectivity of the carbon-carbon triple bond or polar functional group in a compound having a hydrogenation reaction site and a carbon-carbon triple bond or polar functional group When the [CeO ₂ / Au] molar ratio is 50 or less, the carbon-carbon triple bond in a compound having a hydrogenation reaction site and a carbon-carbon triple bond or a polar functional group Or is preferable because it is effective in improving the conversion rate of the polar functional group.

(Particle size of gold-cerium oxide composite)
When the shape of the gold-cerium oxide composite is almost spherical or “core-shell structure”, the particle diameter is not particularly limited, but the average particle diameter is 5 to 100 nm. It is preferable that it is 10-50 nm. When the average particle size is 5 nm or more, the selectivity of the carbon-carbon triple bond or polar functional group in a compound having a hydrogenation reaction site and a carbon-carbon triple bond or polar functional group (hereinafter referred to as “selectivity”). The carbon-carbon triple bond or polar functional group in a compound having a hydrogenation reaction site and a carbon-carbon triple bond or polar functional group that is 100 nm or less is effective. It is effective to improve the conversion rate (hereinafter referred to as “conversion rate”).

  Here, the “core-shell type structure” means a two-layer structure in which a shell layer made of cerium oxide particles is formed on the surface of a core particle made of gold particles, and the shell layer is not necessarily a core ( It does not mean that the core) is completely covered, but it is better that it is covered as much as possible and the shell layer is thicker.

  Moreover, in the core-shell type structure, the shell layer uniformly covers the core (core), but the substrate is affected by the interface between the gold particles whose core is the core and the cerium oxide which is the shell layer. It is preferable that the shell layer has pores that can react. Further, the gold-cerium oxide composite may form a cluster composed of particles of the gold-cerium oxide composite, and when gold particles are exposed on the surface of the cluster, the surface of the gold-cerium oxide composite Further, it may be coated with cerium oxide. Such a cluster has a shape in which two or more particles of a gold-cerium oxide composite having a core-shell structure are aggregated, and a cerium oxide in which the surface of two or more gold particles as a core serves as a shell. The state which the component has coat | covered may be sufficient.

  Such a pore size of the shell layer can be measured by a gas adsorption method or the like performed using a gas such as nitrogen, helium, or krypton on the gold-cerium oxide composite. The size of the pore is not particularly limited as long as it has a pore diameter that is large enough to allow the substrate molecule to pass therethrough. As an example, the size described above can be passed through the substrate. The average pore diameter is preferably about 0.3 to 5.0 nm, more preferably 0.3 to 1.0 nm. When the average pore diameter is smaller than 0.3 nm, when the substrate is an aromatic compound, it may not be preferable because there is a compound that cannot pass through the pores of the shell layer and the conversion rate may be lowered. On the other hand, if the average pore size is larger than 5.0 nm, it is not possible to sufficiently receive the action of both the gold particles whose core is the core and the cerium oxide constituting the shell layer, and the hydrogenation reaction sites and Since the selectivity of a carbon-carbon triple bond or a polar functional group in a compound having a carbon-carbon triple bond or a polar functional group may be lowered, it may not be preferable.

  In addition, when the gold-cerium oxide composite has a core-shell type structure, the size of the gold particles serving as the core is preferably 1 to 30 nm, and preferably 1 to 10 nm. It is more preferable. When the particle diameter of the gold particles is 1 nm or more, it is effective for improving the selectivity of the polar functional group in the compound having a hydrogenation reaction site and a carbon-carbon triple bond or a polar functional group, and is 30 nm or less. When it is, it is effective in improving the conversion of the carbon-carbon triple bond or the polar functional group in the compound having a hydrogenation reaction site and a polar functional group. And it is preferable that the cerium oxide particle used as a shell layer coat | covers the circumference | surroundings of the gold particle | grains used as a nucleus (core) as a shell layer which has a thickness of 2-40 nm as a shell layer of 4-20 nm in thickness. More preferably, it is coated. When the thickness of the shell layer is 2 nm or more, it may be effective in improving the selectivity of the polar functional group in a compound having a hydrogenation reaction site and a carbon-carbon triple bond or a polar functional group, The following may be effective in improving the conversion of the carbon-carbon triple bond or the polar functional group in the compound having a hydrogenation reaction site and a polar functional group.

  Moreover, when the cerium oxide which comprises the shell layer of a core-shell type structure is particle | grains, it is preferable that the average particle diameter of cerium oxide is 2-40 nm, and it is more preferable that it is 4-20 nm. When the average particle diameter (shell average particle diameter) of the cerium oxide particles is 2 nm or more, the carbon-carbon triple bond or the polarity in the compound having a hydrogenation reaction site and a carbon-carbon triple bond or a polar functional group It may be effective in improving the selectivity of the functional group, and if it is 40 nm or less, the carbon-carbon triple bond in a compound having a hydrogenation reaction site and a carbon-carbon triple bond, or a polar functional group, or polarity It may be effective in improving the conversion rate of the functional group.

  When the gold-cerium oxide composite has a core-shell type structure, the shape is not particularly limited, but is preferably an independent particle. Further, the shape may be substantially spherical. Thus, when the shape of the gold-cerium oxide composite particles is almost spherical, the action and effect are considered as follows.

  That is, the high selectivity of the carbon-carbon triple bond by the gold-cerium oxide complex contained in the catalyst of the present invention or the oxygen atom of the polar functional group is effective for highly polar hydrogen species due to heterogeneous cleavage of hydrogen molecules. It is thought that this is due to the fact that it generates well and generates almost no low-polarity hydrogen species due to the uniform cleavage of hydrogen molecules. The heterogeneous cleavage of hydrogen molecules occurs near the interface between the gold particles and cerium oxide, and the uniform cleavage of hydrogen molecules occurs on the surface of the gold particles.

  Further, when the gold-cerium oxide composite is a core-shell type gold-cerium oxide composite in which the surface of the gold particles in the composite is appropriately coated with cerium oxide, the substrate which is a reactive molecule This is probably because most of the active sites that can be accessed can be in the vicinity of the interface between the gold particles and the cerium oxide, and the surface of the gold particles alone is such that uniform cleavage of hydrogen molecules occurs. Since relatively large gold particles of 50 nm or more hardly exhibit a catalytic action, it is considered that the selectivity is high.

(Gold-cerium oxide composite shape)
When the shape of the gold-cerium oxide composite contained in the catalyst of the present invention is almost spherical, it is easy to uniformly coat the gold particles with the cerium oxide, and it is easy to form a catalyst that can easily obtain the above-described action. In some cases, a highly selective catalyst can be obtained.

  In addition, even when the shape of the gold-cerium oxide composite used in the present invention is a substantially spherical core-shell structure, the gold particles are completely covered with cerium oxide, It may be an incomplete coating with a gap between adjacent cerium oxide particles. In the case where the gold particles are partially exposed, the exposed state is not particularly limited, but if there is some exposure, it has a hydrogenation reaction site and a carbon-carbon triple bond, or a polar functional group. Excellent reactivity and selectivity may be excellent with respect to the carbon-carbon triple bond or polar functional group of the compound.

(Alkaline carrier)
The alkaline carrier that is the carrier (base material) of the catalyst of the present invention is not particularly limited, and examples thereof include those containing one or more metals selected from alkali metals and alkaline earth metals. Include oxides, hydroxides, carbonates, silicates and the like containing one or more metals selected from alkali metals and alkaline earth metals. More specifically, hydrotalcite, montmorillonite, Examples thereof include oxides such as magnesium oxide, calcium oxide and barium oxide, hydroxides such as magnesium hydroxide and calcium hydroxide, carbonates such as calcium carbonate, and silicates such as laponite. The alkaline carrier is not only an alkaline carrier, but also a mixture of an alkaline carrier and a neutral carrier such as alumina or silica, a neutral carrier carrying an alkaline component, a neutral carrier modified with an amine, etc. What was used as the support | carrier may be sufficient. Of these, hydrotalcite, magnesium oxide and the like are preferable in the present invention. These alkaline carriers are preferably those in which the counter anion is not a strong acid and the alkali component does not dissolve in the aqueous solution. This is because the alkaline carrier in the present invention works not only as a carrier for dispersing the gold-cerium oxide complex as the catalyst component but also as a redox reaction field for forming the gold-cerium oxide complex. This is because it is considered better to have a base point on the solid surface in the solution.

  The hydrotalcite is not particularly limited, and a naturally produced hydrotalcite may be used, or a synthetic hydrotalcite or a synthetic hydrotalcite-like compound may be used.

The hydrotalcite is, for example, the following formula (1)
M ^II _8-X M ^III _X (OH) ₁₆ A · nH ₂ O (1)
( ^Wherein M ^II is at least one selected from Mg ²⁺ , Fe ²⁺ , Zn ²⁺ , Ca ²⁺ , Li ²⁺ , Ni ²⁺ , Co ²⁺ , Cu ²⁺ , and Mn ^2+. M ^II I is at least one trivalent metal selected from Al ³⁺ , Fe ³⁺ , Mn ³⁺ and Ru ³⁺ , x is an integer of 1 to 7 A represents a divalent anion, and n represents an integer of 0 to 30)
Or the following formula (2)
[Mg ²⁺ _1-y Al _{3 + y} (OH) ₂ ] ^{y +} [(Ds−) _{y / s} · mH ₂ O] ^y− (2)
(Wherein y represents a number satisfying 0.20 ≦ y ≦ 0.33, Ds− represents an s-valent anion, and m represents an integer of 0 to 30)
It is represented by As the hydrotalcite in the present invention, in particular, M ^II is Mg ²⁺ , M ^III is Al ³⁺ , and A is CO ₃ ² in the above formula (1) in that the target compound can be obtained in an extremely high yield. ^In particular, hydrotalcite represented by Mg ₆ Al ₂ (OH) ₁₆ CO ₃ .nH ₂ O can be preferably used.

Preferably contains at least magnesium oxide Among these alkaline carriers, especially hydrotalcite _{(Mg 6 Al 2 (CO 3} ) (OH) 16 · 4H 2 O), and magnesium oxide (MgO) is preferred.

Further, the physical properties such as the adsorption capacity of the alkaline carrier are not particularly limited. For example, the adsorption capacity may be 0.1 to 300 m ² / g as a so-called BET value, May be from 0.1 to 100 μm. In the present invention, the adsorption capacity of the alkaline carrier is preferably 0.5 to 180 m ² / g.

  Furthermore, the form of the alkaline carrier is not particularly limited, and examples thereof include powder, spherical granules, irregular granules, cylindrical pellets, extruded shapes, and ring shapes.

  In the catalyst of the present invention, the aspect in which the gold-cerium oxide complex is supported on the alkaline carrier is not particularly limited, and various aspects can be taken depending on the form of the alkaline carrier, and the position where the gold-cerium oxide complex is supported. May not be simply controlled, or may be inside the pores or only on the surface. Moreover, the form carry | supported by the support | carrier which has the alkaline component modified by the neutral support | carrier may be sufficient. The amount of the gold-cerium oxide composite supported on the alkaline carrier in the catalyst of the present invention is not particularly limited, but for example, it is preferably 0.1 to 10% by weight in terms of metal.

  The catalyst of the present invention naturally has a larger particle size than the gold-cerium oxide composite, so that it can be easily separated after being used in the reaction, and it is needless to say that it is advantageous in reusing the catalyst.

(Components that can be added to the catalyst)
In the catalyst of the present invention, the above-described gold-cerium oxide composite may be supported on an alkaline carrier, and another catalyst, carrier, etc. may be used in a conventional manner as long as the effect of the gold-cerium oxide composite is not impaired. It may be included according to

(Method for producing the catalyst of the present invention)
The catalyst of the present invention can be produced by a method in which a mixed liquid of a gold compound and a cerium compound is dropped into a suspension of an alkaline carrier and then dried (hereinafter referred to as “the method of the present invention”).

  The suspension of the alkaline carrier used in the method of the present invention is not particularly limited. For example, the above-described alkaline carrier may be added to a solvent such as water, mixed, and stirred. The conditions for stirring are not particularly limited, and may be any conditions as long as a suspension is obtained. Moreover, you may add alcohol etc. to a solvent further. Moreover, the temperature of suspension is not specifically limited, For example, 0-100 degreeC, Preferably it is 10-50 degreeC.

  The gold compound used in the present invention is not particularly limited as long as it produces a gold compound constituting a gold-cerium complex structure with a cerium compound on the above alkaline carrier. For example, chloroauric acid, gold chloride, fluorine Water-soluble salts such as gold chloride, gold bromide and gold iodide can be mentioned, and chloroauric acid is particularly preferable.

  The cerium compound used in the present invention is not particularly limited as long as it produces a cerium compound constituting a gold compound and a gold-cerium complex structure on the above-described alkaline carrier. For example, cerium nitrate, cerium acetate, cerium chloride Cerium sulfate, cerium sulfite and the like, and cerium nitrate is particularly preferable.

  The mixed solution of the gold compound and the cerium compound used in the present invention may be stirred by adding the gold compound and the cerium compound to a solvent such as water. The gold compound and the cerium compound may be added at a molar ratio of 1:10 to 50, preferably 1:13 to 40, more preferably 1:15 to 30. Moreover, although the temperature of a liquid mixture is not specifically limited, For example, it is 0-100 degreeC, Preferably it is 10-50 degreeC.

  The mixed liquid of the gold compound and the cerium compound prepared above is added dropwise to the suspension of the alkaline carrier prepared as described above. The conditions for dropping are not particularly limited, but it is sufficient if there is a sufficient basic point for the reduction of the gold component. While doing. After dropping, stirring is continued for 0.5 to 12 hours, preferably 1 to 3 hours.

  After dropping as described above, the suspension may be dried. Prior to drying, the suspension may be subjected to pretreatment such as washing with water and filtration. Although the drying conditions are not particularly limited, the drying is performed under vacuum at 5 to 100 ° C., preferably at room temperature. After drying, pulverization or the like may be further performed.

  The catalyst of the present invention thus obtained can be produced by, for example, TEM (Transmission Electron Microscope), FE-SEM (Field Emission-Scanning Electron Microscope), and the like. Can be confirmed.

(Selective hydrogenation)
The catalyst of the present invention can be used for selective hydrogenation as in the case of conventional gold-cerium oxide composite catalysts, materials for exhaust gas treatment catalysts for automobiles, hydrogen sensors, etc. Selective hydrogenation.

  Although it does not specifically limit as said organic compound, For example, it has a hydrogenation reaction site | part with any of polar functional groups, such as an organic compound with a carbon-carbon triple bond and a hydrogenation reaction site | part, a nitro group, an aldehyde group, an epoxy group. An organic compound etc. are mentioned. Among these organic compounds, organic compounds having a polar functional group of either an aldehyde group or an epoxy group and a hydrogenation reaction site are preferable.

  The organic compound having a carbon-carbon triple bond and a hydrogenation reaction site may be, for example, a terminal alkyne or an internal alkyne. Specifically, phenylacetylene, bromophenylacetylene, chlorophenylacetylene, aminophenylacetylene, benzyl Examples include acetylene, ethyl phenylpropane formate, 2-hexyn-1-ol and the like. Examples of the compound having a nitro group and a hydrogenation reaction site include nitrostyrene and nitrostyrylbenzene. Examples of the compound having an aldehyde group and a hydrogenation reaction site include terpenoids such as citral. Examples of the compound having an epoxy group and a hydrogenation reaction site include epoxy compounds such as stilbene oxide, styrene oxide, methylstyrene oxide, fluorostyrene oxide, chlorostyrene oxide, and ethyl ethyl cinnamate.

  A method for selectively hydrogenating an organic compound using the catalyst of the present invention is not particularly limited, and a setting method may be appropriately selected depending on the kind of the organic compound and the hydrogenation relationship. This hydrogenation may be performed, for example, in a liquid phase containing an organic solvent. Specifically, the hydrogenation may be performed by bringing the catalyst of the present invention, an organic compound, and hydrogen gas into contact with each other in the liquid phase. The liquid phase is preferably only an organic solvent or a mixture of an organic solvent and water, more preferably only an organic solvent.

  Although the organic solvent used in the case of the said hydrogenation is not specifically limited, For example, C5-C9 aliphatic hydrocarbons, such as C5-C20 aliphatic hydrocarbons, such as dodecane and a cyclohexane, Aromatics C7-C9 aromatics, such as toluene and xylene 1 selected from hydrocarbon, oxetane, tetrahydrofuran (THF), tetrahydropyran (THP), ether having a chain structure or cyclic structure such as furan, dibenzofuran, furan, polyether such as polyethylene glycol, polypropylene glycol, etc. Among them, toluene is particularly preferable because of its high stability against hydrogenation.

  The hydrogenation is carried out in the liquid phase. The amount of the organic solvent contained in the hydrogenation is, for example, within the range where the concentration of the organic compound is about 0.5 to 2.0% by mass. It is preferable. The amount of the catalyst of the present invention used in the hydrogenation is, for example, about 0.0001 to 50 mol% with respect to the organic compound based on the amount of gold in the catalyst, and 0.01 to 20 mol. % Is preferable, and about 0.1 to 5 mol% is more preferable. This hydrogenation allows the reaction to proceed smoothly even under mild conditions. The reaction temperature can be appropriately adjusted according to the type of substrate, the type of target product, and the like, and is, for example, about 10 to 100 ° C, preferably about 10 to 50 ° C, and particularly preferably about 10 to 40 ° C. . The reaction time can be appropriately adjusted according to the reaction temperature and pressure, and is, for example, about 10 minutes to 48 hours, preferably about 1 hour to 48 hours, and particularly preferably about 4 hours to 30 hours.

  Among the selective hydrogenations described above, hydrogenation of an organic compound having a carbon-carbon triple bond and a hydrogenation reaction site is preferable. In this case, the carbon-carbon triple bond in the organic compound is selectively hydrogenated. Can be partially hydrogenated to carbon-carbon double bonds. Among the selective hydrogenations described above, it is preferable to hydrogenate an organic compound having an epoxy group and a hydrogenation reaction site. In this case, the epoxy group in the organic compound is selectively hydrogenated to form carbon-carbon. Can be reduced to a double bond.

  In addition, the catalyst of the present invention has very high selectivity for reduction from an organic compound such as an alkyne having a carbon-carbon triple bond in the molecule to an organic compound such as an alkene having a double bond, and is almost quantitative. . Further, since hydrogen is thinly added to the alkyne, it becomes a Z-type alkene selectively. This is because hydrogen molecules having hydrogenation activity of carbon-carbon double bonds occur at the active site on the surface of the gold particle, but carbon- at the active site at the gold-cerium oxide interface of the catalyst of the present invention. It is considered that there is Z-type selectivity because the heterogeneous cleavage of the hydrogen molecule favoring the selective hydrogenation from the carbon triple bond to the cis-carbon-carbon double bond is preferred. The E-type alkene is produced by isomerization of the Z-type alkene, but it is thought that as a mechanism, one hydrogen atom is added to the Z-type alkene and the molecule rotates around the carbon-carbon bond to become an E-type alkene. Since the polar hydrogen produced by the heterogeneous cleavage of hydrogen molecules does not add to the carbon-carbon double bond, it is considered that the Z-type can be selectively obtained.

  Therefore, in the catalyst of the present invention, the organic compound serving as a substrate is a carbon-carbon double bond, an aromatic ring-bonded halogen atom, an O-benzyl group, an aromatic carbonyl group, an N-benzyloxycarbonyl group, a hydroxyl group, or a trialkylsiloxy group. Even if it has an alkoxy group such as a methoxy group, these functional groups are not hydrogenated. When the catalyst of the present invention is used, the alkyl ether is not cleaved, and the alkoxy group is not hydrogenated even if it is an alkoxy group having a large number of carbon atoms such as an ethoxy group in addition to a methoxy group.

(Addition of amines)
In the selective hydrogenation method, by adding an amine to the liquid phase, the formation of by-products can be suppressed, and the hydrogenation reaction sites including carbon-carbon double bonds and the carbon-carbon triplet can be suppressed. The carbon-carbon triple bond or the polar functional group in a compound having a carbon-carbon triple bond or a polar functional group such as a bond can be selectively hydrogenated, and its conversion rate and selectivity In some cases, the reaction rate can be improved. In particular, in the case of an internal alkyne having an electron withdrawing group next to a carbon-carbon triple bond, this effect tends to be prominent. This is thought to be because an alkyne having an electron withdrawing group next to a triple bond is likely to react with polar hydrogen generated by non-uniform cleavage.

  The improvement in performance due to the addition of such amines seems to be due to the donor effect acting on the active site of the selective hydration catalyst by the lone pair of amines. As such amines, alkylamines having 2 to 8 carbon atoms in the alkyl group replacing the hydrogen atom are preferable. Such an alkylamine is considered to have a relatively crowded structure, so that the donor effect acts and the reactivity is improved. As the amines, secondary amines and tertiary amines are preferable, and tertiary amines are particularly preferable.

  Examples of the amines include dibenzylamine and dioctylamine as secondary amines, and triethylamine, tributylamine, trihexylamine, and trioctylamine as tertiary amines. Among these amines, triethylamine is preferable because it exhibits an excellent effect.

  Moreover, the usage-amount of amines in a selective hydrogenation method is although it does not specifically limit, It is preferable that it is 400-1000 mol% with respect to the organic compound which is a substrate. If it exceeds 1000 mol%, the conversion rate may decrease, which is not preferred, and if it is less than 400 mol%, selectivity may not be improved, which is not preferable.

(Reuse of catalyst)
In the catalyst of the present invention used for selective hydrogenation, the gold particles are covered with cerium oxide, so that the supported gold is difficult to become large particles even during the reaction. The catalyst of the present invention can be easily recovered from the reaction solution after hydrogenation by a physical separation method such as filtration or centrifugation. The recovered catalyst of the present invention can be reused as it is or after washing, drying, calcination and the like, if necessary. Washing, drying, calcination and the like may be performed in the same manner as in the production of the catalyst of the present invention.

  The recovered catalyst of the present invention can exhibit almost the same catalytic ability as an unused catalyst of the present invention, and remarkably suppress the reduction of the catalytic ability even after repeated use-regeneration. Can do. Therefore, according to the present invention, since the catalyst that normally occupies a large proportion of the hydrogenation cost can be recovered and reused, the cost of hydrogenating the organic compound can be greatly reduced.

Hereinafter, the gold-cerium oxide-supported composite catalyst (Au @ CeO ₂ / X) of the present invention and examples of the present invention will be described in detail, but the present invention is not limited to the following examples. The present invention can be widely applied within the scope of the present invention.

Manufacturing example 1
Preparation of Au @ CeO ₂ / HT:
Hydrotalcite (HT) 0.5 g was suspended in 50 mL of pure water. 50 mL of a mixed solution of cerium nitrate (0.8 mmol) and chloroauric acid (0.05 mmol) was added dropwise to the obtained suspension at 15 ° C. The resulting mixture was stirred at 15 ° C. for 1 hour. The resulting suspension was washed with pure water, filtered, and dried at room temperature under vacuum to obtain Au @ CeO ₂ / HT.

Example 1
Alkenation of epoxy group:
Reaction of the following formula was performed using the catalyst (Au @ CeO ₂ / HT) obtained in Production Example 1. Specifically, 0.005 mmol using Au @ CeO ₂ / HT as gold, 0.3 mmol of substrate 1, 4 mL of toluene as a solvent, hydrogen pressure 30 atm, and reduction treatment at the reaction temperature and reaction time described in Table 1. went. After the reaction, the conversion and selectivity were measured using a gas chromatograph. The results are shown in Table 1.

It was found that Au @ CeO ₂ / HT can perform alkenylation of the epoxy group with good pass-through rate and selectivity.

Example 2
Alkyne alkeneation:
The reaction of the following formula was carried out in the same manner as in Example 1 except that the substances shown in Table 2 were used as the substrate 3, reaction time, and reaction temperature. The results are shown in Table 2.

It was found that Au @ CeO ₂ / HT can alkyne alkenylation with high pass-through rate and selectivity.

Example 3
Alcoholization of aldehydes:
The reaction of the following formula was carried out in the same manner as in Example 1 except that the substances shown in Table 3 were used as the substrate 5, reaction time, and reaction temperature. The results are shown in Table 3.

It was found that Au @ CeO ₂ / HT can perform alcoholation of aldehydes with high pass-through rate and selectivity.

Example 4
Catalyst recycling:
Au @ CeO ₂ / HT used in the reaction of the following formula in Example 3 was separated by centrifugation, washed with toluene as a solvent, and recovered from the reaction system. This recovered Au @ CeO ₂ / HT was used again for the same reaction. The results are shown in Table 4.

It was found that Au @ CeO ₂ / HT can be reused without degradation of performance.

Manufacturing example 2
Preparation of Au @ CeO ₂ / MgO:
Au @ CeO ₂ / MgO was obtained in the same manner as in Production Example 1 except that the hydrotalcite was changed to magnesium oxide (MgO). A TEM image of Au @ CeO ₂ / MgO is shown in FIG.

Manufacturing example 3
Preparation of Au @ CeO ₂ / Laponite:
Au @ CeO ₂ / Laponite was obtained in the same manner as in Production Example 1, except that the hydrotalcite was changed to laponite (Laponite-RD: manufactured by BYK Co., Ltd.). A TEM image of Au @ CeO ₂ / Laponite is shown in FIG.

Manufacturing example 4
Preparation of Au @ CeO ₂ / amine modified silica:
Au @ CeO ₂ / amine-modified silica was obtained in the same manner as in Production Example 1 except that hydrotalcite was changed to amine-modified silica prepared as follows. A TEM image of Au @ CeO ₂ / amine modified silica is shown in FIG.

<Preparation of amine-modified silica>
4.0 g of silica (CARIACT Q3: manufactured by Fuji Silysia Chemical Ltd.) was suspended in 10 mL of toluene. To the obtained suspension, 4.0 g of 3- (2-aminoethylamino) propyltrimethoxysilane was added dropwise, and the resulting mixture was stirred at 120 ° C. for 10 hours. The resulting suspension was washed with ethanol, filtered, and dried under vacuum at room temperature to obtain amine-modified silica.

The catalyst of the present invention is a deoxygenation reaction of an aromatic compound having an epoxy group useful as an intermediate in various pharmaceuticals, agricultural chemicals, and other various industrial fields, production of a terpenoid containing a carbon-carbon double bond and a hydroxyl group, It is useful for use in functional materials such as automobile catalysts and sensors that utilize specific hydrogenation reaction characteristics. Further, the catalyst of the present invention can be produced inexpensively and safely.

that's all

Claims (13)

  A gold-cerium oxide-supported composite catalyst, wherein a gold-cerium oxide composite comprising gold particles and a cerium oxide coated on the surface of the gold particles is supported on an alkaline carrier.   The gold-cerium oxide-supported composite catalyst according to claim 1, wherein the alkaline carrier contains one or more metals selected from alkali metals and alkaline earth metals.   The gold-cerium oxide-supported composite catalyst according to claim 1, wherein the alkaline carrier contains at least magnesium oxide. In the gold-cerium oxide composite, the molar ratio of gold in terms of metallic gold in the gold particles and the molar ratio of the cerium oxide is 10 to 10 in terms of [cerium oxide (CeO ₂ ) / metallic gold (Au)]. The gold-cerium oxide-supported composite catalyst according to any one of claims 1 to 3, which is 50.   The gold-cerium oxide-supported composite catalyst according to any one of claims 1 to 4, wherein the gold-cerium oxide composite has a core-shell type structure.   The gold-cerium oxide-supported composite catalyst according to claim 1, wherein the alkaline support contains hydrotalcite or magnesium oxide.   The gold-cerium oxide-supported composite catalyst according to any one of claims 1 to 6, which is used for selective hydrogenation.   The gold according to claim 7, wherein the selective hydrogenation is hydrogenation of an oxygen-containing polar functional group of either an aldehyde group or an epoxy group, or hydrogenation of a carbon-carbon triple bond to a carbon-carbon double bond. -Cerium oxide-supported composite catalyst.   A mixed solution of a gold compound and a cerium compound is dropped into a suspension of an alkaline carrier, and then dried, and the gold particles comprising cerium oxide coated on the surfaces of the gold particles A method for producing a gold-cerium oxide-supported composite catalyst in which a cerium oxide composite is supported on an alkaline carrier.   The method for producing a gold-cerium oxide-supported composite catalyst according to claim 9, wherein the alkaline support contains at least magnesium oxide.   The method for producing a gold-cerium oxide-supported composite catalyst according to claim 9, wherein the alkaline carrier contains hydrotalcite or magnesium oxide.   A method for selectively hydrogenating an organic compound, wherein the organic compound is selectively hydrogenated using the gold-cerium oxide-supported composite catalyst according to any one of claims 1 to 8. The organic compound is an organic compound having an oxygen-containing polar functional group of either an aldehyde group or an epoxy group and a hydrogenation reaction site, and selectively hydrogenates the oxygen-containing polar functional group of the organic compound. Item 13. The selective hydrogenation method according to Item 12.