DE1058502B - Process for the preparation of organic sulfenyl bromides - Google Patents

Description

Process for the preparation of organic sulfenyl bromides The present The invention relates to a new process for the preparation of organic sulfenyl bromides, whereby previously unknown Sulfenylbromide are available, which are suitable for various Uses, especially as active ingredients in fungicidal agents or as intermediates for the production of other valuable organic compounds suitable.

In contrast to the relatively easy production of the corresponding Chlorides, the production of sulfenyl bromides by the known processes is difficult, so that so far only a few compounds of this type are known. In many cases Certain groups of organic sulfenyl bromides could not be produced, although easily prepare the corresponding sulfenyl chlorides by the known processes let.

The known processes include the production of 2,4-Dinitrobenzenesulfenylbromids, which consists in the 2, 4-Dinitrobenzenesulfenylchlorid, dissolved in benzene, with potassium bromide or the 2,4-dinitrothiophenol with bromine in chloroform under anhydrous Conditions (see Journal of the American Chemical Society, Vol. 74 [1952], Pp. 3422 to 3423).

However, this reaction is not generally applicable and will be exclusive carried out in organic solvents.

The new process for the production of organic sulfenyl bromides starts from the corresponding sulfenyl chlorides and is characterized by that one reacts these substances with hydrobromic acid in the presence of water and then separating the corresponding sulfenyl bromide from the reaction product.

The new method is different from the known method characterized in that it has broader applicability and that the chemical reaction runs at a lower temperature and faster. It is feasible with both aliphatic such as aromatic sulfenyl chlorides as starting compounds.

In the process according to the invention, it causes the reaction with aqueous In the case of certain sulfenyl compounds, hydrobromic acid not only does the reaction from sulfenyl chloride to bromide, but also a nuclear substitution, so that z. B. in the reaction of trichloromethanesulfenyl chloride with aqueous hydrobromic acid not only trichloromethanesulfenyl bromide, but also dichloromonobromo, monochlorodibromo and Obtained tribromomethanesulfenyl bromide depending on the corresponding reaction conditions will.

The varying sizes of the process and the reaction conditions can vary considerably, with the optimal conditions for reaction rate and yield depend on the type of sulfenyl chloride used. To achieve an optimal conversion was in all cases an excess over the stoichiometric Amount of hydrobromic acid used ; the excess varies according to the species the parent compound. The one that has the greatest influence on the optimal reaction conditions The factor is probably the Br: Cl ratio in the aqueous phase of the reaction. As a result, the degree of conversion and the rate of reaction increase when the Br-: Cl - ratio shifts in favor of the bromine ions. A favorable Br: Cl ratio can be achieved by using a large excess of hydrobromic acid, the initially or in portions by temporarily removing the aqueous phase and Addition of fresh hydrobromic acid is fed to the reaction. On the other hand, supports also the removal of the chlorine ions as soon as they have formed, the maintenance a favorable Br-: Cl - equilibrium. This removal occurs in response to some extent due to greater volatility and lower solubility the hydrochloric acid in the aqueous phase.

In general, temperatures between -10 and + 130 ° C. The choice of pressure is in turn determined by the optimal br : Cl ratio conditionally set by the pressure-dependent variables of the reaction will.

The hydrobromic acid can either initiate the reaction of anhydrous HBr in an aqueous dispersion of the organic sulfenyl chloride or in shape viner aqueous solution are supplied. The concentration the hydrobromic acid is not necessary for the feasibility of the process Crucially, hole can be made with the highest concentration of hydrobromic acid achieve maximum yields and reaction rates. Is preferred Disintegration of 48% hydrobromic acid, which boils at a constant temperature.

When using the method according to the invention sourde a new one Group of sulfenyl bromides found, both as such and as starting materials for the synthesis of organic compounds that contain special functional groups, are useful. These new sulfenyl bromides are chloromethanesulfenyl bromides general formula: X1 - C - S - Br, X2 n where X is a chlorine atom and Xi as well as X2 either Can mean hydrogen, chlorine and / or bromine atoms.

These compounds can be made by reacting a methanesulfenyl chloride with hydrobromic acid under different conditions. At this Reaction: the chlorine atoms in the molecule are successively replaced by bromine atoms, first of all the sulfenyl: chlorine atom. The reaction can be done in a simple manner Determination of the specific gravity of the non-aqueous phase can be followed.

The reaction product is produced depending on the chloromethanesulfenyl chloride used generally from a mixture of chloromethanesulfenyl bromide and the various bromine-substituted chloromethanesulfenyl) romides. Leave the individual connections through known procedural measures, such as B. Fractionation, separation and isolation.

The following examples are intended to explain the process according to the invention.

Example 1 100 cc of carbon tetrachloride were placed in a reaction flask introduced, containing 20 g of 2,4-dinitrobenzenesulenyl chloride (m.p. 94 to 96 ° C). Then 100 cc of 48% aqueous hydrobromic acid were added; now. That The reaction mixture was refluxed for 4 to 6 hours. After that, the aqueous layer removed, another 100 cc of 48% aqueous hydrobromic acid were added added and the reaction mixture was refluxed again for an additional 4 to 6 hours heated.

After cooling, the mixture was filtered off, the carbon tetrachloride layer separated and concentrated; All of the solids were combined and twice recrystallized from carbon tetrachloride. The resulting?, 4-Dinitrobenzenesulfenylbromid was in the form of yellow-orange crystals with a melting point of 105 to 107 ° C and gave the following analysis values: Found Calculated C ................. 26.2 ° / 0 25.8% Cl ................. 0 ° lo O ° / o Br .............. .. 29.1 ° 1O 28, 7 ° / 0 S ................. 11, 09% 11, 45 ° 10 N ................. 9 .83% 10.03% H ................. 1.38% 1.07% Example 2 186 g of 96% trichloromethanesulfenyl chloride (0.96 mol) 972 g of 48% hydrobromic acid (6 moles) were added and over 2 hours stirred at room temperature.

At this point, the specific gravity was the non-aqueous Phase 2, 2767. The red oily phase was then separated, and 236.8 g of the reaction product were obtained, corresponding to a crude yield of 90 to 95%, based on the amount of trichloromethanesulfenyl chloride used.

The reaction product was then washed twice with water, in Dissolved ether and dried over anhydrous sodium sulfate, then filtered and up to a bulb temperature of 65 ° C at a pressure of 25 mm of mercury the foreign constituents are distilled off. 200 g of product were obtained with a specific Weight of d20 = 2.505. This product was then fractionated twice and gave pure trichloromethanesulfenyl bromide and monobromodichloromethanesulfenyl bromide.

The trichloromethanesulfenyl bromide was analyzed and showed the following Values: Found Calculated C ................. 5, 41 ° / 0 5, 22% Cl ................. 46.3 ° / 0 46.2 ° / 0 Br ................ 33.9 ° / 0 34.7% S .......... ....... 13, 6 ° / 0 13, 9 ° / 0 nD20 ............. 1, 5842 d420 ............... 2, 05 Kp.1,6 40.5 ° C The monobromodichloromethanesulfenyl bromide showed the following analytical values: Found Calculated C ................. 4, 36% 4.36% Cl ................. 25, 5% 25, g ° / o Br ................ 57, 8 ° / 0 58, 2 ° / 0 S .................. 11, 50% 11.65% nD20 .................... 1, 6297 4 ..... 2, 38 Kp. 1, 1 46, 6 ° C Example 3 To 200 g of 48% aqueous hydrobromic acid 37.2 g of 96% trichloromethanesulfenyl chloride were added and over a period of 6 hours stirred at room temperature. The oily phase was separated off and a further 200 g of aqueous Hydrobromic acid was added.

The mixture was then stirred for a further 6 hours, whereupon the specific Weight of the non-aqueous phase d420 = 2.82. The red oily phase was separated and gave a yield of process product of 80 to 85% of theory.

The reaction product was then as in the previous example washed, dried and fractionated to yield dibromomonochloromethanesulfenyl bromide and tribromomethanesulfenyl bromide.

The dibromomonochloromethanesulfenyl bromide was identified and revealed following analysis values: found calculated C ................. 3, 80% 3.75% Cl ................. 10.9 ° / o 11.1 ° / o Br ................ 74.5 ° / 0 75.2% S .......... ........ 10, 06% 10.0% nD20 .................... 1, 6714 d420 ................... . 2, 67 Kp. ,, 55.8 ° C Example 4 According to the method described by Brintzinger, Chemical Reports, Vol. 83 (1950), pp. 87 to 90, described method was monochloromethanesulfenyl chloride manufactured. It was obtained in the form of a yellow oil with a density d420 1.49 and a refractive index nII 1.5385.

58.3 g of the resulting compound were added slowly and with stirring added at 5 to 10 ° C to 162 g of 48 ° / Oiger aqueous hydrobromic acid. To Stirring for 15 minutes at 15 to 10 ° C was the resulting, with the aqueous Layer of immiscible, clear, red oily phase separated off, twice with ice water washed and dried over sodium sulfate. This was filtered off and the one obtained clear, red oil separated some crystals after 15 minutes. The mixture was in chilled in a dry ice-acetone bath for 1/2 hour and filtered cold. The resulting Crude monochloromethanesulfenyl bromide was recovered as a clear red filtrate and had a density of d420 = 1.89 and a refractive index nD 1.600.

It has been found that the compounds of the invention, viz the new chloromethanesulfenyl bromide has a remarkable fungicidal effect, especially against many soil fungi. To the Representation of the extraordinary fungicidal activity of these compounds were typical chloromethanesulfenyl bromide subjected to biological testing according to the test procedure described below.

In these experiments pieces of filter paper were thoroughly infected with the test organism by leaving them in a solution of a rapidly growing culture for 24 hours. Each stick was then placed in Petri dishes on standard Kaxtoffel-Dextrose agar bases. The dishes were then using an atomizer at 1.05 atm in a Hoskins-Calcwell chamber (Soap and Sanitary Chemicals, April 1947, pp. 1 to 7) with the test compounds in a 50:50 kersine-acetone solution The desired concentration was sprayed, large spray droplets were removed and only a fine mist was allowed to settle on the agar plates. Under these conditions, a uniform precipitation of 0.5 mg spray liquid per cm2 was achieved. The experiments were carried out in triplicate and the measurement results were obtained as average values of 4 radii mycelial growth. The results obtained are shown in the following table in comparison with the results obtained with trichloromethanesulfenyl chloride. Concentration% inhibition tration Fusarium Compound Rhizotonia Sclerotinia Alternaria Weight- solani oxysporum screrotiorum brassicae percent f. phaseoli ci Trichloromethane 0.25 8 5 28 2 Cl-CS-Cl sulfenyl chloride 0.125 5 2 11 2 Ci Cl Trichloromcthan 0.25 100 100 100 100 Cl-CS-Br sulfenyl bromide 0.125 100 100 100 100 Cl Ci Dichloroboromomethane 0.25 100 100 100 100 Br-CS-Br sulfenyl bromide 0.125 100 100 100 100 Cl Br Chlorodibromomethane 0.25 100 100 100 100 Cl-CS-Br sulfenyl bromide 0.125 100 100 100 100 Br A comparison of these results shows that the corresponding sulfenyl chloride did not produce any significant inhibition, while the sulfenyl bromides showed complete inhibition of the pests at both concentrations. The effectiveness of the sulfenyl bromides against two of the fungi was significantly greater than the effectiveness of an excellent commercial fungicide at the concentrations used. In addition, it has been found through experiments with fungal cultures that these compounds are fungicidal even at a concentration of 0.125 percent by weight, while a commercially available fungicidal agent was only fungistatic.

PATENT APPLICATION: 1. Process for the production of organic sulfenyl bromides, characterized in that an organic sulfenyl chloride in the presence of Reacts water with hydrobromic acid and the resulting organic sulfenyl bromide isolated from the reaction mixture by methods known per se.

2. The method according spoke 1, characterized in that one aqueous solution of concentrated hydrobromic acid is used.

Claims (1)

3. The method according to claim 1 or 2, characterized in that min used an excess of the stoichiometric amount of hydrobromic acid. 4. The method according to claim 1 to 3, characterized in that one reacting a halomethanesulfenyl chloride with concentrated hydrobromic acid. 5. The method according to claim 4, characterized in that trichloromethanesulfenyl chloride with an excess of the stoichiometric amount of hydrobromic acid. Papers considered: Journal of the American Chemical Society, 74: 3422-3423 (1952).