CN1544435A

CN1544435A - Metalloporphyrin synthesizing method

Info

Publication number: CN1544435A
Application number: CNA2003101105375A
Authority: CN
Inventors: 郭灿城; 刘强; 公衍之
Original assignee: Hunan University
Current assignee: Hunan University
Priority date: 2003-11-21
Filing date: 2003-11-21
Publication date: 2004-11-10
Anticipated expiration: 2023-11-21
Also published as: CN1238355C

Abstract

The invention provides a process for synthesizing metalloporphyrin, in particular a process for synthesizing metallic aryl porphyrin and mu-oxygen bimetallic aryl porphyrin from pyrrole and aromaticity aldehyde as raw material by using zinc salt as template center through the steps of, synthesizing aryl porphine and zinc aryl porphyrin mixture, reacting the aryl porphine and zinc aryl porphyrin mixture with other metal salt under acidity or neutrality conditions to obtain metallic aryl porphyrin, synthesizing mu-oxygen bimetallic aryl porphyrin through one-step reaction under alkaline condition.

Description

A kind of synthetic method of metalloporphyrin

Technical field

The present invention relates to a kind of metalloporphyrin synthetic method, especially a kind of is the method for the synthetic metal aryl-porphyrin of raw material and μ-oxygen bimetal aryl-porphyrin with pyrroles and aromatic aldehyde.

Background technology

Oxidation has the selectivity katalysis to metal aryl-porphyrin and μ-oxygen bimetal aryl-porphyrin to hydrocarbon-air.But metal aryl-porphyrin and μ-oxygen bimetal aryl-porphyrin does not have industrial preparative method at present.Need following two-step reaction in the laboratory from pyrroles and the synthetic metal aryl-porphyrin of aromatic aldehyde at present:

And by the reaction yield of the synthetic porphines of pyrroles and aromatic aldehyde less than 20%, the production cost height.

Need pass through following reaction from the synthetic μ of porphines-oxygen bimetal aryl-porphyrin at present:

μ-oxygen bimetallic porphyrin

Reaction also needed for two steps, metalloporphyrin also needs to separate and purify, and, generate in the reaction process of μ-oxygen bimetallic porphyrin at metalloporphyrin and NaOH, the a large amount of NaOH that add can make the metal ion in the metalloporphyrin come off, cause the yield of μ-oxygen bimetallic porphyrin not high, and the product separation difficulty.

Summary of the invention

The objective of the invention is to overcome the defective of above-mentioned prior art, a kind of yield height is provided, production cost is low, and product separates the synthetic method that is easy to metal aryl-porphyrin and μ-oxygen bimetal aryl-porphyrin.

The object of the present invention is achieved like this: adopting zinc salt in the organic solvent that refluxes is template center, is raw material with pyrroles and aromatic aldehyde, at first synthesizing aryl porphines and zinc aryl-porphyrin mixture; With aryl porphines and zinc aryl-porphyrin mixture and other metal-salt, under acidity or neutrallty condition, react synthetic metal aryl-porphyrin then; Under alkaline condition, react one-step synthesis μ-oxygen bimetal aryl-porphyrin.

Synthetic μ-oxygen bimetal aryl-porphyrin except that the mixture that can use aryl porphines and zinc aryl-porphyrin is done the raw material, can also use aryl porphines or zinc aryl-porphyrin to make raw material respectively separately.

The synthetic route of the present invention's metal aryl-porphyrin and μ-oxygen bimetal aryl-porphyrin is as follows:

The metal aryl-porphyrin

μ-oxygen bimetallic porphyrin

Method of the present invention concrete operations as follows:

(1) mixture of aryl porphines and zinc aryl-porphyrin is synthetic;

Mol ratio by 1: 1～3: 1～5 in the organic solvent that refluxes drops into pyrroles, aromatic aldehyde and zinc salt, and pyrroles's concentration is 10 in the reaction system ^-4～1mol/L, the reaction times is 0.5-3 hour; Reactant obtains the mixture of aryl porphines and zinc aryl-porphyrin through cooling, separation;

(2) metalloporphyrin is synthetic: above-mentioned aryl porphines and the zinc aryl-porphyrin mixture ratio according to 0.1～5% (weight) is dissolved in the organic solvent, add metal-salt, the molar ratio of aryl porphines and zinc aryl-porphyrin mixture and metal-salt is 1～10, reaction solution backflow 0.5-5 hour; Product is the metal aryl-porphyrin;

More than the building-up reactions of the second single metal porphyrin under at alkaline condition, carry out, promptly with the pH value of basic cpd conditioned reaction liquid greater than 7, product is μ-oxygen bimetal aryl-porphyrin.

Reactant obtains finished product through cooling, separation.

In production practice, also can replace aryl porphines and zinc aryl-porphyrin mixture to prepare μ-oxygen bimetal aryl-porphyrin with aryl porphines or zinc aryl-porphyrin separately.

The zinc salt that the present invention uses should be soluble zinc salt, for example ZnCl ₂, Zn (OAc) ₂, ZnBr ₂

The organic solvent that the present invention uses is identical with the organic solvent that existing synthetic method is used, and for example, can be propionic acid, acetate, benzene,toluene,xylene, methylene dichloride, trichloromethane, DMF, DMSO or their mixture.

The metal-salt that metal-salt that the present invention uses and existing synthetic method are used is indistinction also, can be Co (acac) ₂, Cu (OAc) ₂, NiCl ₂, Zn (OAc) ₂, Zn (OAc) ₂, FeCl ₂4H ₂O, MnCl ₂4H ₂O or CrCl ₂6H ₂O.

The basic cpd and the prior art of the pH value of the conditioned reaction liquid that the present invention uses do not have assorted petty difference yet, can be pyridines, triethylamine, NaOCH ₃, NaOC ₂H ₅, NaOH, Na ₂CO ₃Or NaHCO ₃

Synthetic method with existing metal aryl-porphyrin compares, and the present invention can make the synthetic yield of metal aryl-porphyrin improve 10～15%, reaches 20～40%; The present invention's μ-oxygen bimetal aryl-porphyrin synthetic method can make two step processes of existing synthetic method become a one-step process, and the synthesis yield of μ-oxygen bimetal aryl-porphyrin can improve 30～40%, and productive rate can reach 90～95%; The synthetic cost of metal aryl-porphyrin and μ-oxygen bimetal aryl-porphyrin can significantly reduce thus.

Embodiment

The invention will be further described by the following examples.

Embodiment 1: with 5g compound 1, R ₁=OCH ₃, R ₂=R ₃=H and 4g pyrroles, 5gZnCl ₂, adding in the 100ml propionic acid, reaction stirred is 0.5 hour under refluxing, and cooling, separation obtain mixture 2.

Gained mixture 2 is dissolved in the dimethylbenzene of backflow, adds 1g Co (acac) ₂, reacted 2 hours, obtain compound 3 (M=Co, R ₁=OCH ₃, R ₂=R ₃=H).The transformation efficiency of compound 1 is 30%, and the transformation efficiency of mixture 2 is 95%.

Embodiment 2: with 5g compound 1, R ₁=OH, R ₂=R ₃=CH ₃And 4g pyrroles, 5gZnCl ₂, adding in the 120ml acetic acid, reaction stirred is 1 hour under refluxing, and cooling, separation obtain mixture 2.

Gained mixture 2 is dissolved among the trichloromethane/DMF of backflow, adds 1g Cu (OAc) ₂, reacted 2 hours, obtain compound 3 (M=Cu, R ₁=OCH ₃, R ₂=R ₃=H).The transformation efficiency of compound 1 is 35%, and the transformation efficiency of mixture 2 is 94%.

Embodiment 3: with 5g compound 1, R ₁=N (CH ₃) ₂, R ₂=Cl, R ₃=CH ₃And 4g pyrroles, 5gZn (OAc) ₂, adding in the 120ml acetic acid, reaction stirred is 1 hour under refluxing, and cooling, separation obtain mixture 2.Gained mixture 2 is dissolved among the trichloromethane/DMF of backflow, adds 1g NiCl ₂, reacted 1.5 hours, obtain compound 3 (M=Ni, R ₁=N (CH ₃) ₂, R ₂=Cl, R ₃=H).The transformation efficiency of compound 1 is 32%, and the transformation efficiency of mixture 2 is 90%.

Embodiment 4: with 5g compound 1, R ₁=F, R ₂=NO ₂R ₃=CH ₃And 4g pyrroles, 5gZn (OAc) ₂, adding in the 120ml acetic acid, reaction stirred is 1 hour under refluxing, and cooling, separation obtain mixture 2.Gained mixture 2 is dissolved among the DMF of backflow, adds 1g Ru ₃(CO) ₁₂, reacted 3 hours, obtain compound 3 (M=Ru, R ₁=F, R ₂=NO ₂, R ₃=CH ₃).The transformation efficiency of compound 1 is 30%, and the transformation efficiency of mixture 2 is 92%.

Embodiment 5: with 5g compound 1, R ₁=CH (CH ₃) ₂, R ₂=H, R ₃=Br and 4g pyrroles, 5g ZnBr ₂, adding in the 80ml Mono Chloro Acetic Acid, reaction stirred is 0.5 hour under refluxing, and cooling, separation obtain mixture 2.Gained mixture 2 is dissolved among the DMSO of backflow, adds 1g FeCl ₂4H ₂O reacted 1 hour, obtained compound 3 (M=Fe, R ₁=CH (CH ₃) ₂, R ₂=H, R ₃=Br).The transformation efficiency of compound 1 is 38%, and the transformation efficiency of mixture 2 is 95%.

Embodiment 6:

With 1g mixture 2, R ₁=CH ₃, R ₂=Cl, R ₃=H, and 0.3gFeCl ₂4H ₂O adds in the 35ml dimethylbenzene, adds NaHCO under refluxing ₃Control pH=8, reaction stirred 1 hour gets μ-oxygen bimetal aryl-porphyrin (M ₁=M ₂=Fe, R ₁=CH ₃, R ₂=Cl, R ₃=H).The synthesis yield of μ-oxygen bimetal aryl-porphyrin is 90%.

Embodiment 7: with 1g mixture 2, R ₁=COOH, R ₂=H, R ₃=Cl, and 0.3gFeCl ₂4H ₂O adds among 35ml methylene dichloride/DMF, adds pyridine control pH=9 under refluxing, and reaction stirred 1 hour gets compound 4 (M ₁=M ₂=Fe, R ₁=COOH, R ₂=H, R ₃=Cl).The synthesis yield of μ-oxygen bimetal aryl-porphyrin is 95%.

Embodiment 8: with 1g mixture 2, R ₁=OH, R ₂=Bt, R ₃=H, and 0.3gMnCl ₂4H ₂O adds among the 35ml DSMO, adds NaOH control pH=10 under refluxing, and reaction stirred 2 hours gets compound 4 (M ₁=M ₂=Mn, R ₁=OH, R ₂=Br, R ₃=H).The synthesis yield of μ-oxygen bimetal aryl-porphyrin is 93%.

Embodiment 9: with 1g aryl porphines, R ₁=NH ₂, R ₂=F, R ₃=H, and 0.3gMnCl ₂5H ₂O adds in the 35ml benzene, adds triethylamine control pH=10 under refluxing, and reaction stirred 3 hours gets compound 4 (M ₁=M ₂=Mn, R ₁=NH ₂, R ₂=F, R ₃=H).The synthesis yield of μ-oxygen bimetal aryl-porphyrin is 91%.

Embodiment 10: with 1g zinc aryl-porphyrin, R ₁=NO ₂, R ₂=H, R ₃=CH ₃, and 0.3gCrCl ₂6H ₂O adds in the 35ml methylene dichloride, adds NaOCH under refluxing ₃Control pH=13, reaction stirred 0.5 hour gets compound 4 (M ₁=M ₂=Cr, R ₁=NO ₂, R ₂=H, R ₃=CH ₃).The synthesis yield of μ-oxygen bimetal aryl-porphyrin is 93%.

Claims

1. the synthetic method of a metalloporphyrin is characterized in that comprising the steps:

(1) aryl porphines and zinc aryl-porphyrin mixture is synthetic;

Mol ratio by 1: 1～3: 1～5 in organic solvent drops into pyrroles, aromatic aldehyde and soluble zinc salt, and pyrroles's concentration is 10 in the reaction system ^-4～1mol/L, reflux also stirred 0.5-3 hour; Reactant obtains the mixture of aryl porphines and zinc aryl-porphyrin through cooling, separation;

(2) metalloporphyrin is synthetic: above-mentioned aryl porphines and the zinc aryl-porphyrin mixture ratio according to 0.1～5% (weight) is dissolved in the organic solvent, add soluble transition metal salt, the mol ratio of aryl porphines and zinc aryl-porphyrin mixture and metal-salt is 1～10, reaction solution reflux 0.5-5 hour; Reactant obtains finished product through cooling, separation.

2. synthetic method according to claim 1, the building-up reactions that it is characterized in that the second single metal porphyrin are as carrying out under neutrality or acidic conditions, and product is the metal aryl-porphyrin.

3. synthetic method according to claim 1 is characterized in that the building-up reactions of the second single metal porphyrin is carried out under at alkaline condition, the pH value of promptly using basic cpd conditioned reaction liquid is greater than 7, and product is μ-oxygen bimetal aryl-porphyrin.

4. synthetic method according to claim 3 is characterized in that and can replace aryl porphines and zinc aryl-porphyrin mixture to prepare μ-oxygen bimetal aryl-porphyrin with aryl porphines or zinc aryl-porphyrin separately.

5. synthetic method according to claim 1 is characterized in that, described soluble zinc salt is ZnCl2, ZnBr2, Zn (OAc) 2 etc.

6. synthetic method according to claim 1 is characterized in that, described organic solvent can be propionic acid, acetate, benzene,toluene,xylene, methylene dichloride, trichloromethane, DMF, DMSO or their mixture.

7. synthetic method according to claim 1 is characterized in that, described soluble transition metal salt has: Co (acac) 2, Cu (OAc) 2, NiCl2, Zn (OAc) 2, Zn (OAc) 2, FeCl2, MnCl2, CrCl3.

8. according to claim 3 or 4 described synthetic methods, it is characterized in that described basic cpd can be inorganic or organic bases, as: pyridine, triethylamine, NaOCH3, NaOC2H5, Na2CO3, NaHCO3.