CN1680628A - Electrochemical synthesis of biphenyl - Google Patents
Electrochemical synthesis of biphenyl Download PDFInfo
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- CN1680628A CN1680628A CN200510023673.XA CN200510023673A CN1680628A CN 1680628 A CN1680628 A CN 1680628A CN 200510023673 A CN200510023673 A CN 200510023673A CN 1680628 A CN1680628 A CN 1680628A
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- ethyl acetate
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Abstract
An electrochemical method of synthesizing diphenyl. Negative pole is corrosion resistant chip. Positive pole is zinc chip. Reference electrode is saturation calomel electrode(SCE), DMF solution of cadmium oxide and NaCl is as salt bridge. Catalytic agent is NiCl2bpy. Salt electrolyte is supported by (Et)4NBF4. Electrolysis halogenated hydrocarbon at -1.3-1.8Vvs SCE in N2 at room temperature. Diphenyl is obtained from electrolyte.
Description
Technical field
The present invention relates to a kind of electrochemical method for synthesizing of biphenyl, belong to technical field of electrochemistry.
Background technology
Biphenyl is a kind of aromatic hydrocarbons, molecular formula C
12H
10, colourless tabular crystal, 71 ℃ of fusing points, 255.9 ℃ of boiling points, relative density 0.8660 (20/4 ℃), water insoluble, be dissolved in organic solvents such as ethanol, ether and benzene, chemical property is similar to benzene, is present in the coal tar.Thermostability height, its steam are difficult for decomposing, and can be used as heat transfer liquids, organic heat carrier, also are the raw materials of high quality dielectric, and as softening agent, sanitas also is used to make fuel, engineering plastics and high energy fuels.The eutectic mixture that 26.5% biphenyl and 73.5% phenyl ether are formed can be heated to 400 ℃ under 9.5 normal atmosphere.
M.Troupel makes mixed solvent with tetrahydrofuran (THF) (THF)/HMPA (HMPT) in the two chamber-type electrolyzer, nickel (NiCl is closed in chlorination two (triphenyl phosphorus)
2(PPh
3)
2) make catalyzer, excessive triphenyl phosphorus (PPh
3) used as stabilizers, mercury is made electrode, electrolysis coupling bromobenzene (PhBr) under the room temperature, and productive rate is 58%, but the mercury electrode that this method adopts has environmental pollution big, is difficult to processing, is difficult for industrialized shortcoming.Y.Rollin is in a Room type electrolyzer, and (NMP) makes solvent with N-Methyl pyrrolidone, bromination 2,2 '-bipyridine nickel (NiBr
2Bpy) make catalyzer, excessive 2,2-dipyridyl (bpy) used as stabilizers, the gold net is made negative electrode, electrolysis coupling bromobenzene under the room temperature, productive rate is 75%, but the gold electrode that this method adopts, cost is very high.M.A.Fox is in the two chamber-type electrolyzer, and with methyl-sulphoxide (DMSO), N, dinethylformamide (DMF) etc. is made solvent, lithium is made anode, carbon is made negative electrode, and 1,2-two (two-2-propyl group phosphorus) benzene nickel complex is made catalyzer, electrolysis coupling halogeno-benzene (PhX), the productive rate of 65 ℃ of following chlorobenzenes (PhCl) in DMSO is up to 80%, but this method uses as lively as a cricket alkali metal lithium to make anode, electrode preparation and operational difficulty, and in the time of 65 ℃, just can obtain yield preferably, also have the high shortcoming of energy consumption.
React the coupling that realizes halogenated aryl hydrocarbon with Ullmann in the organic synthesis, but this method need carry out at high temperature, long reaction time needs the nickel complex of chemical dose.Present industrial biphenyl is by benzene (C
6H
6) dehydrogenation makes under high temperature (750~850 ℃), this method environmental pollution is big, and to the equipment requirements height, energy consumption is big.
Summary of the invention
The object of the present invention is to provide a kind of electrochemical method for synthesizing of biphenyl, this method has that equipment requirements is simple, electrode be easy to prepare, react at normal temperatures carry out, energy consumption is little, yield is higher and the advantage of suitable suitability for industrialized production.
Technical scheme of the present invention is that stainless steel substrates is made negative electrode in a Room type electrolyzer that can feed protection gas, and zinc metal sheet is made anode; saturated calomel electrode SCE makes reference electrode, and the saturated DMF solution of Cadmium chloride fine powder and sodium-chlor is made salt bridge, chlorination 2; 2 '-bipyridine nickel, i.e. NiCl
2Bpy makes catalyzer, and DMF makes solvent, tetraethylammonium tetrafluoroborate, i.e. (Et)
4NBF
4Do to support salt electrolyte, halogenated aryl hydrocarbon is a reactant, under room temperature, nitrogen protection, constant potential-1.3~-1.8Vvs.SCE under electrolysis, after electrolysis finished, electrolytic solution was through aftertreatment, product biphenyl, productive rate is between 53.6~83.9%.
Now describe technical scheme of the present invention in detail.A kind of electrochemical method for synthesizing of biphenyl is characterized in that, the concrete operations step:
The first step equipment is prepared
Electrolyzer is for feeding the cylinder shape electrolyzer of protection gas, and negative electrode is a stainless steel substrates, and anode is a zinc metal sheet; reference electrode is a saturated calomel electrode, and promptly SCE makes salt bridge with the saturated DMF solution of Cadmium chloride fine powder, sodium-chlor; with the described electrode described electrolyzer of packing into, logical exsiccant N
2Remove the oxygen in the described electrolyzer;
The preparation of the second one-step electrolysis liquid
Electrolytic solution is mixed by (Et) 4NBF4 of 1 part of weight and the DMF of 30~50 parts of weight, and described electrolytic solution is injected described electrolyzer;
The 3rd one-step electrolysis process
At room temperature, the NiCl2bpy of 0.25~0.50 part of weight and the halogenated aryl hydrocarbon of 1.5~2.5 parts of weight are added in the described electrolyzer, feed protection gas N to described electrolyzer
2, constant potential-1.3~-1.8V vs.SCE under electrolysis, the energising amount is every mol halogenated aryl hydrocarbon 1.2F;
The 4th step aftertreatment
With traditional method, in described electrolytic solution, add dilute hydrochloric acid, use ethyl acetate extraction again, the combined ethyl acetate extraction phase washes with water then, removes DMF residual in the ethyl acetate, ethyl acetate is removed in decompression, gets product biphenyl, and productive rate is 53.6~83.9%.
Technical scheme of the present invention is further characterized in that in the 3rd step, halogenated aryl hydrocarbon is a bromobenzene.
Technical scheme of the present invention is further characterized in that in the 3rd step, halogenated aryl hydrocarbon is a chlorobenzene.
Compare with background technology, the invention has the advantages that:
1. reaction is at room temperature carried out, and energy consumption is low.
2. adopt a Room type electrolyzer, lower than two chamber-type electrolyzer required voltage.
3. make negative electrode with stainless steel, than mercury cathode pollute little, be easy to processing, than au cathode low price.
4. use NiCl
2Bpy makes catalyzer, and cost is low, is easy to preparation.
5. with methodology of organic synthesis Ullmann reacting phase ratio, the advantage that does not need high temperature, reaction times to lack, only need the nickel catalyzator of catalytic amount is arranged.
Embodiment
Now further specify technical scheme of the present invention by embodiment.All embodiment operate according to the operation steps of described synthetic method fully.
Embodiment one
In second step, electrolytic solution is made up of 0.84g (Et) 4NBF4 and 37.8g DMF; In the 3rd step, halogenated aryl hydrocarbon is a bromobenzene, and the weight of bromobenzene and concentration are respectively 1.27g and 0.2molL-1, and the weight of NiCl2bpy and concentration are respectively 0.23g and 0.02mol L-1, and electrolysis under constant potential-1.3V vs.SCE passes to protection gas N in the electrolytic process
2The 4th the step in, dilute hydrochloric acid capacity and concentration be respectively 20mL and 0.5mol L
-1, use 20mL, 10mL and 10mL ethyl acetate extraction three times successively, use 5mL water washing twice respectively, the combined ethyl acetate phase, the product biphenyl after rotary evaporation desolvates, productive rate are 53.6%.
Embodiment two
In second step, electrolytic solution is made up of 0.84g (Et) 4NBF4 and 37.8g DMF; In the 3rd step, halogenated aryl hydrocarbon is a bromobenzene, and the weight of bromobenzene and concentration are respectively 1.27g and 0.2molL-1, and the weight of NiCl2bpy and concentration are respectively 0.23g and 0.02mol L-1, and electrolysis under constant potential-1.5V vs.SCE passes to protection gas N in the electrolytic process
2The 4th the step in, dilute hydrochloric acid capacity and concentration be respectively 20mL and 0.5mol L
-1, use 20mL, 10mL and 10mL ethyl acetate extraction three times successively, use 5mL water washing twice respectively, the combined ethyl acetate phase, the product biphenyl after rotary evaporation desolvates, productive rate are 79.7%.
Embodiment three
In second step, electrolytic solution is made up of 1.26g (Et) 4NBF4 and 37.8g DMF; In the 3rd step, halogenated aryl hydrocarbon is a bromobenzene, and the weight of bromobenzene and concentration are respectively 1.27g and 0.2molL-1, and the weight of NiCl2bpy and concentration are respectively 0.23g and 0.02mol L-1, and electrolysis under constant potential-1.8V vs.SCE passes to protection gas N in the electrolytic process
2The 4th the step in, dilute hydrochloric acid capacity and concentration be respectively 20mL and 0.5mol L
-1, use 20mL, 10mL and 10mL ethyl acetate extraction three times successively, use 5mL water washing twice respectively, the combined ethyl acetate phase, the product biphenyl after rotary evaporation desolvates, productive rate are 83.9%.
Embodiment four
In second step, electrolytic solution is made up of 0.84g (Et) 4NBF4 and 37.8g DMF; In the 3rd step, halogenated aryl hydrocarbon is a chlorobenzene, and the weight of chlorobenzene and concentration are respectively 0.91g and 0.2molL-1, and the weight of NiCl2bpy and concentration are respectively 0.23g and 0.02mol L-1, and electrolysis under constant potential-1.8V vs.SCE passes to protection gas N in the electrolytic process
2The 4th the step in, dilute hydrochloric acid capacity and concentration be respectively 20mL and 0.5mol L
-1, use 20mL, 10mL and 10mL ethyl acetate extraction three times successively, use 5mL water washing twice respectively, the combined ethyl acetate phase, the product biphenyl after rotary evaporation desolvates, productive rate are 67.4%.
Embodiment five
In second step, electrolytic solution is made up of 1.26g (Et) 4NBF4 and 37.8g DMF; In the 3rd step, halogenated aryl hydrocarbon is a bromobenzene, and the weight of bromobenzene and concentration are respectively 1.88g and 0.3molL-1, and the weight of NiCl2bpy and concentration are respectively 0.23g and 0.02mol L-1, and electrolysis under constant potential-1.8V vs.SCE passes to protection gas N in the electrolytic process
2The 4th the step in, dilute hydrochloric acid capacity and concentration be respectively 20mL and 0.5mol L
-1, use 20mL, 10mL and 10mL ethyl acetate extraction three times successively, use 5mL water washing twice respectively, the combined ethyl acetate phase, the product biphenyl after rotary evaporation desolvates, productive rate are 68.0%.
Embodiment six
In second step, the solution that electrolytic solution is made up of 1.26g (Et) 4NBF4 and 37.8g DMF; In the 3rd step, halogenated aryl hydrocarbon is a bromobenzene, and the weight of bromobenzene and concentration are respectively 1.27g and 0.2mol L-1, and the weight of NiCl2bpy and concentration are respectively 0.33g and 0.03mol L-1, and electrolysis under constant potential-1.8V vs.SCE passes to protection gas N in the electrolytic process
2The 4th the step in, dilute hydrochloric acid capacity and concentration be respectively 20mL and 0.5mol L
-1, use 20mL, 10mL and 10mL ethyl acetate extraction three times successively, use 5mL water washing twice respectively, the combined ethyl acetate phase, the product biphenyl after rotary evaporation desolvates, productive rate are 83.7%.
Claims (3)
1. the electrochemical method for synthesizing of a biphenyl is characterized in that, the concrete operations step:
The first step equipment is prepared
Electrolyzer is for feeding the cylinder shape electrolyzer of protection gas, and negative electrode is a stainless steel substrates, and anode is a zinc metal sheet; reference electrode is a saturated calomel electrode, and promptly SCE makes salt bridge with the saturated DMF solution of Cadmium chloride fine powder, sodium-chlor; with the described electrode described electrolyzer of packing into, logical exsiccant N
2Remove the oxygen in the described electrolyzer;
The preparation of the second one-step electrolysis liquid
Electrolytic solution is by (Et) of 1 part of weight
4NBF
4Mix with the DMF of 30~50 parts of weight, described electrolytic solution is injected described electrolyzer;
The 3rd one-step electrolysis process
At room temperature, with the NiCl of 0.25~0.50 part of weight
2The halogenated aryl hydrocarbon of bpy and 1.5~2.5 parts of weight adds in the described electrolyzer, feeds protection gas N to described electrolyzer
2, constant potential-1.3~-1.8V vs.SCE under electrolysis, the energising amount is every mol halogenated aryl hydrocarbon 1.2F;
The 4th step aftertreatment
With traditional method, in described electrolytic solution, add dilute hydrochloric acid, use ethyl acetate extraction again, the combined ethyl acetate extraction phase washes with water then, removes DMF residual in the ethyl acetate, ethyl acetate is removed in decompression, gets product biphenyl, and productive rate is 53.6~83.9%.
2. the electrochemical method for synthesizing of biphenyl according to claim 1 is characterized in that, in the 3rd step, halogenated aryl hydrocarbon is a bromobenzene.
3. the electrochemical method for synthesizing of biphenyl according to claim 1 is characterized in that, in the 3rd step, halogenated aryl hydrocarbon is a chlorobenzene.
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CNB200510023673XA CN100436649C (en) | 2005-01-28 | 2005-01-28 | Electrochemical synthesis of biphenyl |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102459707A (en) * | 2009-06-05 | 2012-05-16 | 巴斯夫欧洲公司 | Method for preparing unsymmetrical biaryl alcohols |
CN109996905A (en) * | 2016-11-15 | 2019-07-09 | 国立大学法人横浜国立大学 | The manufacturing method of organic hydride material producing device and organic hydride |
CN112281182A (en) * | 2020-10-29 | 2021-01-29 | 武汉大学 | Method for preparing deuterated aromatic hydrocarbon under electrochemical condition |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4187156A (en) * | 1977-12-21 | 1980-02-05 | Monsanto Company | Preparation of dihydroaromatic hydrocarbons |
JPS5594486A (en) * | 1979-01-11 | 1980-07-17 | Sumitomo Chem Co Ltd | Electrochemical production of diphenyl acetates |
JPH02197589A (en) * | 1989-01-27 | 1990-08-06 | Kanto Denka Kogyo Co Ltd | Production of 3,4,3',4'-biphenyltetracarboxylic ester |
JP2001199922A (en) * | 2000-01-20 | 2001-07-24 | Matsushita Electric Ind Co Ltd | Method for forming diketone and apparatus for fixing carbon dioxide using the method |
CN1189597C (en) * | 2002-11-22 | 2005-02-16 | 中国科学院长春应用化学研究所 | Preparation of biphenylyl tetra formicdianhydride and its derivative using electrochemical method |
-
2005
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102459707A (en) * | 2009-06-05 | 2012-05-16 | 巴斯夫欧洲公司 | Method for preparing unsymmetrical biaryl alcohols |
CN109996905A (en) * | 2016-11-15 | 2019-07-09 | 国立大学法人横浜国立大学 | The manufacturing method of organic hydride material producing device and organic hydride |
CN109996905B (en) * | 2016-11-15 | 2021-05-11 | 国立大学法人横浜国立大学 | Organic hydride manufacturing device and organic hydride manufacturing method |
US11519082B2 (en) | 2016-11-15 | 2022-12-06 | National University Corporation Yokohama National University | Organic hydride production apparatus and method for producing organic hydride |
CN112281182A (en) * | 2020-10-29 | 2021-01-29 | 武汉大学 | Method for preparing deuterated aromatic hydrocarbon under electrochemical condition |
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