DE1197083B - Process for the preparation of dimers and trimers of bicyclo- [2, 2, 1] -heptadiene- (2, 5) - Google Patents

Description

Process for the preparation of dimers and trimers of bicyclo [2.2, 1] -heptadiene- (2,5) The invention relates to a process for the production of high-energy Dimers and trimers of bicycla- [2,2,1] -heptadiene- (2,5) or of their hydrogenation products.

According to Tetrahedron Letters, 1961, pp. 373 to 375, bicyclo- [2,2,1] -heptadiene- (2,5) obtained a dimer in 20- or 8- or 1% yield if one is used as a catalyst Iron, nickel or cobalt carbonyls are used.

It has now been found that bicyclo-2,2,1] -heptadiene- (2,5) in can dimerize or trimerize very high yields if you use them as catalysts an organic complex compound of iron, nickel or cobalt in a low Oxidation level, preferably zero oxidation level, and at least partially with electron donating compounds as ligands, to bicyclo- [2,2,1] -heptadiene- (2,5) clogs. In general, the oxidation level should not be higher than one.

From Belgian patent specification 598 363 it is known to convert 1,3-butadiene into oligomers, such as cyclooctadiene (1,5), 4-vinylcyclohexene (I), cyclododecatriene, using the same catalysts from metals of subgroup VIII of the Periodic Table (1,5,9) or 5-methylheptatriene- (1,3,6) to convert. In attempts to convert cyclopentadiene, cycloheptatriene (1,3,5) and cyclohexadiene (1,3) into oligomers with these catalysts, it turned out that these compounds do not react at all, although they are 1,3-diolefins. It was therefore surprising that bicyclo- [2,2,1] -heptadiene- (2,5) nevertheless di- or with such catalysts. could be trimerized, although bicyclo- [2,2,1] -heptadiene- (2,5) is rather equivalent to the less reactive 3-diolefins. Properties dimer I dimer II dimer III trimer Molar refraction calculated ............................... 54.93 - 53.17 - found .... .............. .......... 54.6 - 53.24 - Molecular weight calculated ............................... 184.3 184.3 184.3 276 found ............................... 192 188 190 290 analysis C calculated,% ......................... 91.25 91.25 91.25 91.25 found,% .... ...... .............. 91.10 91.09 91.01 91.30 H calculated,% ......................... 8.75 8.75 8.75 8.75 found,% .......................... 8.82 8.79 8.69 8.87 Melting point, ° C ......................... 67 to 68 86 to 89 - 201 (relocated) Boiling point, ° C ............................ - 75 76 - (0.2 mm Hg) (0.2 mm Hg) (Continuation) Properties dimer I dimer II dimer III trimer Refractive index nD20 ........................ | - | 1.5427 | 1,5476 | - Heat of combustion, cal / cms ............... 12 330 11 062 11 330 - Hydrogen uptake, moles .................. | 2 | 2 | 1 | 2 Melting point of the hydrogenation product, ° C 56 to 58 37 to 40 - 231 to 233 Heat of combustion of the hydrogenation product cal / cm³ ................................. | 11 609 | 11 853 | - The catalysts for the process according to the invention are the organic complex compounds of iron, nickel or cobalt, preferably of nickel and iron, in a low oxidation level, preferably oxidation level zero, as the central atom and organic groups, such as the bicyclo [2,2,1] - heptadiene (2,5) or its di- and trimers themselves, as ligands. It is possible here that other olefins as ligands or electron donating organic groups, so-called Lewis bases, such as triarylphosphines, both alone and in addition to bicycloheptadiene (2,5) or its dimers and trimers, are present in the complex compound. Carbonyl compounds, such as nickel tetracarbonyl, do not fall under the term organic complex compounds, but it is possible that the complex compounds used as catalysts according to the invention may also contain carbonyl groups in addition to the so-called organic groups. The oligomers obtained can be catalytically hydrogenated in a manner known per se, such as with Raney nickel at room temperature.

These complex compounds can, for. B. in the by L. Malatesta and A. Sacco in Rend. class Sci. f sharp. mat. nat., Vol. 81, 1951, p. 379 Way to be made. Appropriately, one proceeds in such a way that one in the presence of electron-donating compounds to the di- and trimerization of bicycloheptadiene (2.54 ver used solvents, such as benzene, xylene or tetrahydrofuran, soluble compounds of iron, nickel or cobalt, for example acetylacetonate, diacetyldioxime compounds, Alcoholates or acetoacetic ester enolates, adds, then preferably not one reducing agent which reacts with the solvent, such as aluminum trialkyl or alkoxydialkyl aluminum, clogs. The solution can now with advantage directly for the dimerization and trimerization of the bicyclo [2.2, l jheptadiene- (2.5) can be used; one can use the corresponding complex compounds but also isolate. The use of a solvent is not essential required if the metal compounds required for complex formation in Bicyclo- [2,2,1] -heptadiene- (2,5) are themselves soluble, which is mostly the case. Even the use of reducing agents can be dispensed with if the metal already in a low oxidation state, as in nickel tetracarbonyl. So you can make quite active catalysts by making compounds of the metals mentioned in a low oxidation level, preferably the oxidation level Zero, in particular nickel tetracarb onyl, with the electron donating compound, such as bicyclo- [2,2,1] -heptadiene- (2,5) and / or its dimers and trimers.

The dimerization or trimerization takes place at temperatures from 0 to 1800C, preferably 60 to 120 ° C, and low pressures, preferably at normal pressure, carried out.

The compounds obtained by the process according to the invention are distinguished by high densities and high heats of combustion. They can be isolated and separated by known methods. So were z. B. three different dimers and one trimer of bicyclo- [2,2,1] -heptadiene- (2,5) isolated and examined their properties by gas chromatography. They have the following structures: Dimer I. Dimer II Trimer where the dimer of structural formula II is very likely a stereoisomeric form of the dimer of structural formula. In the hydrogenation of the dimer of structural formula II, two products can be isolated. However, by adding the dimer of structural formula II to silver nitrate and subsequent cleavage in a high vacuum, a product can be obtained which, even in the hydrogenation, provides a uniform substance that can no longer be separated.

The dimers and trimers of bicyclo- [2,2,1] -heptadiene- (2,5) prepared according to the invention can be used as high-energy propellants, such as propellants for rockets, or as well as a starting material for the production of derivatives with special properties be used. The perchlorinated dimer is a substance with an insecticidal effect. the for example obtained via their epoxides containing hydroxyl groups Oil compounds can be used in the manufacture of plastics.

The process according to the invention is intended to be explained in the following examples are: Example 1 90 g of bicyclo- [2,2,1] -heptadiene- (2,5) are in a solution of 2g tetrakis (triphenylphosphine) nickel in 80 cm3 benzene heated to 80 ° C for 3 hours. The organic constituents are then separated off by steam distillation and worked up by fractional distillation. 10 g of unreacted material are obtained Bicyclo- [2,2,1] -heptadiene- (2,5), 50 g of a colorless liquid, bp 0.001 50 ° C, according to the IR spectrum, elemental analysis, molar refraction, molecular weight and chemical behavior is pentacyclo- (8,2,1,02 * 9,03,3,14,7) -tetradecadiene- (5,11). The gas chromatogram of this liquid shows that it is a mixture of three isomers represents, which in the following always correspond to their occurrence in the gas chromatograph may be referred to as dimer 1, dimer II or dimer III.

4 g of a crystallized one are obtained as the distillation residue Compound with a melting point of 201 ° C, according to the IR spectrum, elemental analysis, molecular weight and chemical behavior Octacyclo- (14,2,1,02,15, 03,14 14,14,13,05,13,06.11,1 7,10) -henicosadiene- (8.17) is (trimeric bicyclo- [2,2,1] -heptadiene- (2,5). The conversion is 89%, the yield of dimers 63%, the yield of trimers 50%.

Example 2 The procedure described in Example 1 is used however, instead of benzene, xylene is used as the solvent and works at 115 ° C. One achieves a conversion of 64% and a yield of dimers of 710 / o.

Example 3 1 g is dissolved in 180 g of bicyclo- [2.2.1] -heptadiene- (2.5) Nickel acetylacetonate and 2 cm3 of triethylaluminum are added to the mixture. Man if it holds it at 115 ° C. for 12 hours, it works as described in Example 1 and has a yield of dimers of 490 / o.

Example 4 The procedure is as in Example 3, but with an additional function 25 cm3 of tetrahydrofuran as solvent and achieved with a reaction time of 7 hours and a temperature of 85 ° C a conversion of 75% and a yield of dimers of 650 / o.

Example 5 1 g of iron acetylacetonate is dissolved in 50 cc of benzene 45 g of bicyclo- [2,2,1] -heptadiene- (2.5) are added, the mixture is treated with 2 cm3 of ethoxydiethylaluminum and heats it to 70 ° C for 4 hours. Then the reaction mixture becomes as in the example 1 worked up. The dimers are obtained in a 65% yield, which are as follows make up: 65% dimer I, 20% dimer II, 15 01o dimer III.

Example 6 1 g of iron acetylacetonate is dissolved in 20 cm3 of benzene and 4 g of bicyclo- [2,2,1] -heptadiene- (2,5) and add 3 cm3 to the mixture at 10 ° C Triethylaluminum.

90 g of bicyclo- [2,2,1] -heptadiene- (2,5) are now added and the Stand mixture at 25 ° C for 60 hours.

They are worked up as described in Example 1 and achieved at 70% conversion, a yield of dimers of 950/0 with 80% dimers, 15% dimers II and 5% dimer III. The dimer 1 crystallizes from this mixture and can be recrystallized from benzene, ethanol, ether or acetone. It has a Melting point from 68 to 69 ° C.

Example 7 1 g of cobalt acetylacetonate is dissolved in 50 cm3 of benzene and 45 g of bicyclo- [2,2,1] -heptadiene- (2.5), adds 2 cm3 of triethylaluminum and holds the mixture at 70 ° C for 4 hours. After working up as described in Example 1, a yield of dimers of 880 / o with 620 / o dimers is achieved at 80% conversion I, 290 / o dimer II and 9 0 / o dimer III.

Example 8 10 g of nickel acetylacetonate are dissolved in 50 cm3 of benzene, 200 cm3 of ether and an equimolecular amount of the dimer I. 30 g of a are formed pale yellow complex compound, 1 g of which is dissolved in 50 cm³ of benzene and 4 at 60 ° C Allowed to react with 45 g of bicyclo- [2.2.1] -heptadiene- (2.5) for hours. After working up, As described in Example 1, a yield of dimers is obtained at 82% conversion of 530 / o with 96 0 / o dimer 1 and 4% dimer II.

Example 9 1 g of bis (acrylonitrile) nickel is added to 50 cm 3 of benzene with 45 g of bicyclo- [2,2,1] -heptadiene- (2,5) together and heated the mixture for 4 hours to 90 ° C. The work-up is carried out as in Example 1.

The conversion is 480% with a yield of dimers of 99% 36% dimer I and 64% dimer II.

Example 10 The procedure is as in Example 9, except that bis- (acry] acid nitrile) triphenylphosphine nickel as a catalyst. Conversion 960 / o yield of dimers 35% thereof 500 / o dimers, 50% dimers II.

Example 11 Dissolve 2 g of iron acetylacetonate in 200 cm3 of benzene and 5 cm3 of bicyclo- [2,2,1] -heptadiene- (2.5) and reduced with 2 cm3 of triethylaluminum at 0 ° C. Now allowed within 30 minutes 675 g of bicyclo- [2,2,1] -heptadiene- (2.5) flow in, the temperature rising to 100 ° C. You hold them up for another 20 hours 400 C, then the solvent is removed in vacuo and the residue is distilled in High vacuum at 50 ° C. This gives 660 g (97% of theory) of dimers which are like are composed as follows: 24.3 0 / o dimer 1, 63.6 0 / o dimer II, 12.1 0 / o dimer III.

Example 12 25.5 g of nickel tetracarbonyl are heated with 27.6 g of bicyclo- [2.2.1] -heptadiene- (2.5) to 800 C, with carbon monoxide escaping. A dark-colored complex compound is obtained of nickel with the bicyclo- [2,2,1] -heptadiene- (2,5). On this complex compound leaves 675 g of bicyclo- [2,2,1] -heptadiene- (2,5) are allowed to act at 90 "C. After 4 hours the work is carried out is on and obtained after the distillation 510g of dimer II in a yield of 690 /, the theory.

Example 13 25.5 g of nickel tetracarbonyl are heated with 55.2 g of dimer 1 to 80 "C, with carbon monoxide escaping. It becomes a dark-colored complex compound formed, which contains dimer I in addition to nickel.

670 g of bicyclo- [2.2, 1] -heptadiene- (2.5) are left at 90 ° C. for 5 hours take effect and then work on as previously described. 611 g of dimer are obtained II, corresponding to a yield of 91% of theory.

Example 14 1.84 g of dimeric bicyclo- [2.2.1] -heptadiene- (2.5) I dated Melting point 64 to 65 "C were dissolved in 30 ml of methanol and in the presence of 0.1 g of Pd hydrogenated on BaSO4 at 760 Torr and 20 ° C. After 46 minutes, the hydrogen uptake was ceased ended and was 480.2 cm3 equal to 99.7% of theory for two double bonds. The hydrogenation product was precipitated with water and then recrystallized from ethanol. 1.7 g of a colorless substance which had crystallized in needles and had a melting point were obtained 64 ° C.

Example 15 1.84 g of a mixture of the isomeric dimeric bicycloheptadienes were dissolved in 30 ml of methanol and in the presence of 0.05 g of PtO2 at 750 Torr and Hydrogenated at 210 ° C. The hydrogen uptake was 465.4 cm3.

) The hydrogenation product is obtained after distillation in a high vacuum Form of a colorless liquid.

Claims (3)

Claims: 1. Process for the production of dimers and trimers des bicyclo- [2.2.1] -heptadiene- (2.5) by treating bicyclo- [2.2.1] -heptadiene- (2.5) with added complex compounds of iron, nickel or cobalt, in which these Elements are in a lower valence level, such as the valence zero, or of their hydrogenation products, characterized in that at temperatures from 0 to 1800 C, preferably from 60 to 120 "C, and in the presence of a solvent works with complex compounds which are at least partially organic, electron donating Possess compounds as ligands, and optionally the reaction products in in a known manner catalytically, as with Raney nickel at room temperature, hydrogenated. 2. The method according to claim 1, characterized in that as electron donating compound bicyclo- [2.2, l] -heptadiene- (2.5) and / or its Dimers and trimers or triarylphosphines or acrylonitrile are used. 3. The method according to claim 1, characterized in that as Solvents aliphatic, cycloaliphatic, aromatic and / or araliphatic, optionally halogenated hydrocarbons, bicyclo- [2,2,1] -heptadiene- (2,5) itself or its dimerization products are used. Documents considered: Tetrahedron Letters, 1961, p. 373 to 375.