US3130233A

US3130233A - Aldehydes and method of preparation

Info

Publication number: US3130233A
Application number: US57886A
Authority: US
Inventors: Warren D Niederhauser
Original assignee: Rohm and Haas Co
Current assignee: Rohm and Haas Co
Priority date: 1959-03-19
Filing date: 1960-09-23
Publication date: 1964-04-21
Anticipated expiration: 1981-04-21
Also published as: GB945770A; DE1151497B; NL249503A; FR1262598A

Description

United States Patent Ofifice 3,130,233 Patented Apr. 21, 1964 Ser. No. 57,886

9 Claims.

This invention concerns a process for treating 1,2- epoxides to yield aldehydes. This invention also deals with a group of novel and useful B-hydroxyaldehydes and a d-unsaturated aldehydes.

This application is a division of Serial No. 800,402, filed March 19, 1959 and now Patent No. 3,054,813.

The process of this invention comprises treating 1,2- epoxides with carbon monoxide and hydrogen gases under pressure and elevated temperatures in the presence of a hydrofor-mylation catalyst. There results useful aldehydes.

The instant process is applicable to compounds containing one or a plurality of 1,2-epoxide groups. When there are employed as starting materials, polyepoxides, such as alkyl esters of epoxidized water-insoluble fatty acids or epoxidized glyceryl esters, there may be obtained products which are mixtures of poly-fi-hydroxyaldehydes and of poly-a,/3-unsaturated aldehydes. At the present time, however, it is preferred to use somewhat simpler starting materials which may be classified Within the following three groups:

Group A which may be represented by Formula I RCHCHR Where R and R are hydrogen atoms or alkyl groups containing from one to preferably twelve carbon atoms, R and R being alike or difierent;

Group B which may be represented by Formula II Where A is an aryl group, preferably containing from six to eight carbon atoms, such as phenyl, tolyl, and xylyl, and

R is an alkyl group containing from one to six, preferably one, carbon atoms.

The process of this invention yields valuable compounds, a number of which are new. The products resulting from said groups A, B, and C, respectively, may be represented by the following formulas, in which the alphabetical designation corresponds to that given to the starting epoxides and the even numbers designate the afiunsaturated aldehydes, Whereas the uneven numbers specify the S-hydroXyaIdehyde products,

in which R, R R R R A, and n have thedefinition assigned above. In each case illustrated above, the 11, unsaturated aldehyde products include the isomers in which the formyl group and the vicinal vinylene hydro gen atom are on either carbon of the vinylidene insaturation. Likewise, in the B-hydroxyaldehyde products there are included the isomers in which the hydroxyl and formyl groups are interchangeably bonded onto either of the vicinal carbon atoms onto which originally the epoxy oxygen was bonded. In the appended claims, the term isomer is intended to define the position interchangeability of the formyl, hydroxyl, and vinylene hydrogen on the carbon atom originally supporting the epoxide oxygen.

In accordance with the process of this invention, 1,2- epoxides of the groups A, B and C are subjected to hydrogen and carbon monoxide gases under pressure and elevated temperature in the presence of a hydroformylation catalyst. The total carbon monoxide and hydrogen gas pressure under which the reaction is carried out should preferably range from 900 to 10,000 p.s.i.; advantageously, it is maintained in the range of 1500 to 3000 psi. The reactive temperatures range from to 200 0, preferably from to C.

To achieve substantially complete reaction, the carbon monoxide and hydrogen gases are employed in a of 1 mole of each gas per epoxide equivalent in the starting material; an excess such as to 1.5 moles per epoxide equivalent of either one or both gases may be employed if desired. Once this minimum requirement of gas is satisfied, the hydrogen to carbon monoxide ratio is not critical, a one to one ratio being quite suitable. Ratios of hydrogen to carbon monoxide in the range of 3 to 1 and 1 to 3, respectively, may also be employed when desired. The gases may be fed to the reaction environment singly or mixed. To promote the reaction, the reacting vessel may be agitated. The progress and extent of the conversion of the epoxides to the aldehydes may be followed by the consumption of the carbon monoxide and hydrogen gases, the conversion being substantially complete when no more consumption of the gases is registered. Also, bromine determinations, analysis for oxirane oxygen and hydroxyl number may be used as an aid in determining the extent of formation of ,B-hydroxyaldehydes and il-unsaturated aldehydes.

If desired, the reaction is carried out in the presence of one or more inert organic volatile solvents. Suitable for this purpose are hydrocarbons, such as benzene, ethylbenzene, diethylbenzene, toluene, xylene, cumene, nhexane, propane, cyclohexane, and the like. Such an optional inert solvent generally facilitates handling of r a the starting materials and of the products, particularly of the lower molecular weight materials.

In accordance with this invention, the conversion of 1,2-epoxides to aldehydes is carried out in the presence of a hydrofor-mylation catalyst which is a compound of the metals of group VIII of the periodic table having an atomic number from 26 to 28, inclusive, and preferably capable of forming a metal carbonyl under the conditions of the reaction. Such metals include iron, cobalt, and nickel. Cobalt compounds have been found to be especially suited for the present purpose, particularly oil soluble cobalt salts such as cobalt salts of fatty acids containing two to eighteen, and especially four to eight, carbon atoms. Typical are cobalt butyrate, cobalt octanoate, cobalt oleates, and the like. Other useful cobalt compounds include cobalt formate, cobalt acetate, cobalt carbonyl, cobalt anhydride, cobalt carbonate, Raney cobait, cobalt naphthenate, and the like. Finely divided reduced metallic cobalt may also be suitable in special cases. The catalysts may be employed as such or deposited on granular carriers or in intimate mixtures with metallic, mineral, or ceramic materials like kieselghur, clay, glass powder, and the like. The hydroformylation catalyst is used in an amount in the range of 0.1 to and preferably 0.5 to 2 weight percent, calculated as nickel, cobalt or iron metal based on the starting material.

In accordance with a preferred aspect of this invention, 1 mole of a suitable epoxide and cobalt, as cobalt carbonyl in benzene, in an amount of 1% of carbonyl on the weight of epoxide are charged to a stainless steel autoclave. The autoclave is fed with a mixture of carbon monoxide and hydrogen in a 1 to 1 molar ratio till the pressure reaches 2000 p.s.i.; heating is applied to reach 130 to 140 C. while the autoclave is rocked. When the pressure stops decreasing, the conversion to aldehydes is substantially completed. Pressures and temperatures are allowed to drop and the products are isolated. This may be effectuated by suitable procedures as by fractional distillation under reduced pressure.

The aldehyde products formed are generally mixtures of B-hydroxyaldehydes, a,,6-unsaturated hydroxyaldehydes and their respective isomers. By suitable methods, the separation of saturated aldehydes from the unsaturated ones may be effectively carried out. If desired, in an optional refinement of the present method, the formation of cap-unsaturated aldehydes may be further promoted by continuing heating the product resulting for the conversion of the starting epoxides, at atmospheric pressure or higher, preferably in the presence of water and an acidic catalyst, such as formic acid, acetic acid, boric acid, or mineral acid, such as sulfuric acid. On the other hand, if it is desired to favor the yields of saturated ,8- hydroxyaldehydes, it is preferable in the isolation step, to remove residual catalyst from the products of the conversion of the epoxides. This may be elfectuated by converting the cobalt to a water-soluble salt by acid-wash thermal treatment or other suitable means.

Typical of the new fi-hydroxyaldehydes prepared in accordance with the present method there may be named:

the

4 Typical 0:,B-UI1S2lt1l12ltGd aldehydes prepared in accordance with this method include:

2methyl-4-phenyl-2-butenal, and its isomer,

2-benzyl-2-butenal,

2-ethyl-4-phenyl-2-butenal,

2-butyl-4-phenyl-2-butenal,

2-hexyl-4-phenyl-2-butenal,

2-methyl-4-xylyl-2-butenal,

2-methyl-4-tolyl-2-butenal, e

Methyl 9, l0) -formyloleate,

Ethyl 9, 19 -formyloleate,

Octyl 9, l0) -formyloleate,

Ethyl 1S, 16) -formylerucate,

Butyl 9,(l0)-formylpalmitoleate, the respective isomers and the like.

The new ,B-hydroxyaldehydes of this invention are useful in the preparation of the corresponding 0:,[3-111158111- rated aldehydes. Conversion to nap-unsaturated aldehydes may be effected by heating the aldols at high temperatures, such as above 150 C., at atmospheric pressures or under superatmospheric pressures. Advantageously, this convension may be carried out in the presence of a catalyst. The fi-hydroxyaldehydes of this invention are valuable in preparing glycols by catalytic reduction such as with platinum, nickel, Raney type catalysts, at temperatures above C. and at superatmospheric pressures. Moreover, the oxidation of selected [3- hydroxyaldehydes of this invention yields valuable hydroxydicar-boxylic acids. The oxidation may be accomplished with a mild oxidizing agent such as alkaline solutions containing silver or copper salts, or hydrogen peroxide. In this manner, methyl 8-hydroXy-9-formylstearate yields the corresponding acid ester. The new 0:,5- unsaturated aldehydes of this invention are valuable for preparing unsaturated dibasic acids by oxidation. Oxidation, such as with hydrogen peroxide, under mild conditions yields hydroxyacids. saturated aldehydes is as adjuncts in odoriferous compositions. The more pungent mil-unsaturated aldehydes may be useful in insect repellent preparations, the other aldehydes which have more pleasant fragrance may be used as bases or additives in cosmetic preparations. A typical insect repellent composition may be prepared from:

30 parts of dimethyl phthalate 5.0 parts of alkylphenoxypolyethoxyethanol of an ethylene oxide of 12, a non-ionic water-soluble surfaceactive agent 10 parts of mineral oil 55 parts of water 0.1 part of a suitable unsaturated aldehyde of this invention Portion A is heated to 55 C., portion B to 60 C.; then A and B are mixed with vigorous agitation. The ,5- unsaturated aldehyde is added at 55 C., the mixture is then homogenized. Likewise, suntan lotions may be prepared in which anhydrous lanolin and methyl salicylate may be mixed with part A.

One skilled in the art will appreciate, that in accordance with the steps and conditions of the instant process, com- Another use for the oc,[3-11I1- Example 1 To a stainless steel autoclave of 300 cc. capacity, there are charged 29 parts of propylene oxide, 40 parts of xylene, and 5 parts of a solution of cobalt carbonyl in benzene containing 3% cobalt. The vessel is closed and it is filled with a mixture of carbon monoxide and hydrogen in a 1 to 1 volume ratio until a pressure of 2100 p.s.i. is recorded. The vessel is heated to within a temperature range of 130 to 140 C. with rocking for one hour to insure mixing. The pressure drops smoothly during the reaction. When pressure dropped to 960 p.s.i. and no further drop is recorded, the autoclave is cooled to C. The product is removed; it is distilled rapidly and the distillate is separated from the lower water layer. The product is redistilled through a packed column to give 5.5 parts of methacrolein and 9 parts of crotonaldehyde.

Example 2 A hydrogenation bomb is charged with a mixture of 22 parts of ethylene oxide, 40 parts of xylene, and 3.5 parts of a benzene solution of cobalt carbonyl containing 3% cobalt. Pressure is applied to 1500 p.s.i. while heating is maintained within a range of 150 to 180 C. with rocking. When no further drop in pressure is recorded, the bomb is cooled to C. The product is removed and filtered to remove catalyst. Distillation under reduced pressure yields acrolein.

Example 3 A stainless steel autoclave of 300 cc. capacity is charged with 60 parts of 1,2-epoxyoctane, parts of xylene, and 8 parts of cobalt carbonyl in xylene containing 5% cobalt. The closed vessel is filled with a mixture of carbon monoxide and hydrogen gas to a pressure of 2700 p.s.i. The vessel is heated, with rocking, to and at a temperature of 135 C. for one hour. As the pressure stops decreasing, heating is discontinued and the vessel is allowed to Example 4 To a hydrogenation bomb of 300 cc. capacity, there are charged 87 parts of methyl 9,10-epoxystearate, parts of benzene, and 8 parts of cobalt carbonyl in benzene having a 3% cobalt content. Carbon monoxide and hydrogen are fed into the bomb to a pressure of 2600 p.s.i. and heat is applied to and maintained at 120 to 150 C. for one hour, with rocking. Upon a drop of pressure to 1420 p.s.i., and when no further uptake of gas is recorded, the bomb is cooled to room temperature. Catalyst is separated and solvent is distilled from the product. There is obtained 91 parts of an oil, which is a mixture of the isomers of methyl 9,(10)-hydroxy-10,(9)-formy1stearate and of methyl 9,(10)-formyloleate. These products are separated by fractional distillation under reduced pressure.

Example 5 The bomb is charged with 87 parts of ethyl 9,10-epoxystearate, parts of benzene and 8 parts of cobalt butyrate in benzene having a 3% cobalt content. The reaction proceeds in the manner described above. The products are ethyl 9,(10)-hydroxy-10,(9)-formylstearate and ethyl 9, l0) -formyloleate.

Example 6 The procedure of Example 4 is again followed and the resulting oily product which is formed is fractionally distilled in the presence of 1 gram of phosphoric acid under reduced pressure. The product obtained is an increased proportion of methyl 9,(10)-formyloleate. Separation is eifectuated by fractional distillation under reduced pressure.

Example 7 Following the procedure of Example 4, octyl-9,l0- epoxystearate is treated in the presence of cobalt carbonyl with a mixture of carbon monoxide and hydrogen under pressure to yield octyl-9,(10)-hydroxy-(9)-forn1ylstearate and octyl-9,(10)-formyloleate. The products are separated by fractional distillation under reduced pressure.

Methyl 13(14)-epoxybehenate is treated in a similar manner to yield methyl l3,( l4)-hydroxy-14,(13)-formyldocosanoate and methyl 15,(l6)-formylerucate. The products are separated by fractional distillation under a reduced pressure of 1 mm. of mercury.

Example 8 A mixture of 71 parts of 1-phenyl-2,3-epoxybutane, 40 parts of benzene, and 5 parts of a solution of cobalt carbonyl in benzene containing 3% cobalt are placed in a rocking autoclave. The autoclave is filled with hydrogen and carbon monoxide in a 1 to 1 volume ratio to a pressure of 3000 p.s.i. and heated for 1 /2 hours at to C. When the pressure stops decreasing, heating is discontinued and the bomb is allowed to cool to room temperature. Catalyst is filtered ofi and the product is distilled over a vacuum steam bath to give 77 parts of a mixture of 2-methyl-3-hydroxyl-4-phenylbutanal, 2-meth yl-S-phenyl-Z-butenal, and their respective isomers. The products are separated by fractional distillation at pressure reduced to 1 mm. of mercury.

In a similar manner, 1-xylyl-2,3-epoxybutane is treated yielding 2 methyl 3-hydroxy-4-xylylbutanal, 2-(2,4-di methylbenzyl) 3 hydroxybutanal, 2 methyl-4-xylyl-2- buteual, and 2-(2,4-dimethylbenzyl)-2-butenal.

By substituting cobalt carbonyl by an equivalent amount of cobalt butyrate or by cobalt acetate, comparable results are obtained.

I claim:

1. An aldehyde selected from the group consisting of at least one hydroxy aldehyde of the formula in which A represents an aryl group containing from six to eight carbon atoms, and R represents an alkyl group containing from one to six carbon atoms.

2. The hydroxy aldehyde of claim 1 in which R is an alkyl group having one carbon atom. 3. A compound having the formula CH ACH2?HCHR4 CHO with a mixture of carbon monoxide and hydrogen gases in-a minimum amount of 1 mole of each gas, under a superatmospheric pressure ranging from 900 to 10,000 p.s.i. at a temperature ranging from 100 to 200 C. and in the presence of cobalt carbonyl, until substantial conversion of said 1,2-epoxide to at least one aldehyde of the formula A--OH OH=CR- CHO the isomer thereof in which the formyl group and the vicinal vinylene hydrogen atom are bonded onto the other carbon of the vinylene unsaturation on AoH,oH-HR HO and the isomer thereof in which the hydroxyl and formyl groups are interchangeably bonded onto the vicinal carbon atoms, in which, in the above formulas, A represents an aryl group containing from six to eight carbon atoms, and R represents an alkyl' group containing from one to six carbon atoms.

7. A process which comprises reacting a 1,2-epoxide of the formula A-C1-I2CHOH-R4 with a mixture of carbon monoxide and hydrogen gases in a minimum amount of 1 mole of each gas, under a superatmospheric pressure ranging from 900 to 10,000

p.s.i. at a temperature rangingfrom to 200 C. -and in the presence of cobalt carbonyl, and isolating at least one aldehyde of the formula A-CHr-GH: 1-13 and the isomer thereof in which the formyl group and the vicinal vinylene hydrogen atom are bonded onto the other carbon of the vinylene unsaturation, in which in the above formulas A represents an aryl group containing from six to eight carbon atoms, and R represents an alkyl group containing from one to six carbon atoms.

8. A process for preparing 2-methyl-3-hydroxyl-4- phenylbutanal which comprises reacting 1-phenyl-2,3- epoxybutene with a mixture of at least one mole of carbon monoxide gas and at least one mole of hydrogen gas under superatmospheric pressure, within a temperature range from 100 to 200 C., and in the presence of cobalt carbonyl, and isolating 2-methyl-3-hydroxy-4- phenylbutanal.

9. A process for preparing 2-methy1-3-phenyl-2-butenal which comprises reacting 1-phenyl-2,3-epoxybutene with a mixture of at least one mole of carbon monoxide gas and at least one mole of hydrogen gas under superatmospheric pressure, within a temperature range from 100 to 200 C., and in the presence of cobalt carbonyl, and isolating 2-methyl-3-phenyl-2-butenal.

References Cited in the file of this patent UNITED STATES PATENTS 2,102,965 Meuly Dec. 21, 1937

Claims

1. AN ALDEHYDE SELECTED FROM THE GROUP CONSISTING OF AT LEAST ONE HYDROXY ALDEHYDE OF THE FORMULA