STEP 1: Purify commercial undecylenic acid by distillation of, say, 250 g under diminished pressure and collect the fraction, b.p. 152-154 °C/6 mmHg; this has a freezing point of 23 °C. Dissolve 108 g (0.58 mol) of the purified undecylenic acid in 285 ml of dry carbon tetrachloride (CAUTION, shown below Note 2) in a 1-litre three-necked flask provided with a sealed stirrer unit, a dropping funnel and a reflux condenser.
STEP 2: Cool the flask in a freezing mixture of ice and salt, stir the solution and add 96 g (31 ml, 0.6 mol) of dry bromine during a period of 1 hour: allow the mixture to warm up gradually to the temperature of the laboratory.
STEP 3: Remove the carbon tetrachloride with a rotary evaporator and pour the residue into a large evaporating dish (fume cupboard).
STEP 4: Upon standing 1-2 days (more rapidly when left in a vacuum desiccator over silica gel), the dibromo acid crystallises completely.
STEP 5: The yield is quantitative.
STEP 6: Transfer the solid dibromo acid to a 2-litre round-bottomed flask attached to a reflux condenser, add a solution of 263 g of potassium hydroxide in 158 ml of water, and heat in an oil bath at 150-160 °C for 8 hours.
STEP 7: Considerable frothing occurs, but this is reduced by the addition of small quantities (about 0.1 g) of a suitable detergent, e.g. sodium dodecyl benzenesulphonate, from time to time.
STEP 8: Allow the mixture to stand overnight, add 1500 ml of water, shake until all the solid dissolves and acidify with dilute sulphuric acid to Congo red.
STEP 9: A solid cake of acid separates on the surface of the liquid after standing for several hours.
STEP 10: Extract with four 250 ml portions of ether, dry with anhydrous sodium or magnesium sulphate and remove the ether by distillation on a water bath.
STEP 11: Transfer the residue to a 250-ml flask fitted with a Claisen still-head and distil cautiously under diminished pressure using a free flame.
STEP 12: A little ether and water pass over first and the temperature rises rapidly to 175 °C/15 mmHg.
STEP 13: Collect separately the fractions (a) b.p. 177-182 °C/ 15 mmHg (52 g) and (b) 182-200 °C/15 mmHg (15 g).
STEP 14: The flask contains a large residue, which is discarded. Fraction (a) solidifies completely on cooling and has m.p. 37-41 °C; upon recrystallisation from light petroleum, b.p. 6080 °C, 34 g (32%) of pure undec-10-ynoic acid, m.p. 41-42 °C, are obtained.
STEP 15: A further quantity of product is obtained from fraction (b), which solidifies to a slightly sticky solid: upon recrystallisation from light petroleum, b.p. 6080 °C, a sticky solid separates, which, after spreading upon a porous tile, becomes colourless and has m.p. 41-52 °C (3 g).
Cognate preparations. Phenylpropynoic acid:
STEP 1: Place a solution of
88 g (84 ml, 0.5 mol) of ethyl cinnamate (Expt 6.137) in 50
ml of carbon tetrachloride in a 500-m1 round-bottomed flask.
STEP 2: Immerse the flask
in ice and add 80 g (25.5 ml, 0.5 mol) of bromine from a separatory funnel
slowly with frequent shaking.
STEP 3: The halogen
will disappear rapidly at first, but more slowly towards the end of the
reaction; no hydrogen bromide is evolved and the time of the addition is about 20-25 minutes.
STEP 4: Allow the mixture to
stand for 1 hour, pour the solution into a large evaporating dish and
permit the excess of bromine and the carbon tetrachloride to evaporate
spontaneously in the fume cupboard.
STEP 5: The crude ethyl
2,3-dibromo-3-phenylpropanoate will remain as a solid cake; this can be dried by pressing between large filter
papers.
STEP 6: The yield of crude ester, m.p. 66-71 °C, is 140
g (83%) (1).
STEP 7: Dissolve 85 g of potassium hydroxide in 400 ml of rectified spirit by heating in a 1500-ml round-bottomed flask, provided with a reflux condenser, on a water bath.
STEP 8: Cool to 40-50 °C, and add 112 g (0.33 mol) of the crude dibromo ester; when the initial exothermic reaction has subsided, heat the mixture on a water bath for 5-6 hours.
STEP 9: Pour the contents of the flask into a large beaker and, when cold, add concentrated hydrochloric acid with stirring until neutral to litmus.
STEP 10: Cool, filter the precipitated solids at the pump and wash with a little alcohol.
STEP 11: Set the solids (A) aside. Transfer the filtrate to the original flask and distil the liquid until the temperature of the vapour reaches 95 °C.
STEP 12: Combine the residue in the flask with the precipitated solids (A), dissolve in 270 ml of water, add about 300 g of crushed ice and cool the flask in an ice bath.
STEP 13: Stir the mixture mechanically, and add 20 per cent sulphuric acid slowly until the solution is strongly acid to Congo red.
STEP 14: Allow to stand for 20 minutes, filter off the dark-coloured crude phenylpropynoic acid at the pump and wash it with three 15 ml portions of 2 per cent sulphuric acid.
STEP 15: Dissolve the solid in about 300 ml of 5 per cent sodium carbonate solution, add 6 g of decolourising charcoal and heat on a water bath for 30 minutes with occasional shaking.
STEP 16: Filter through a fluted filter paper, cool the filtrate in ice and then add 70 g of crushed ice.
STEP 17: Stir the solution mechanically and add 20 per cent sulphuric acid slowly until acid to Congo red.
STEP 18: After 20 minutes, filter the precipitated acid by suction, wash with 15 ml of 2 per cent sulphuric acid, then with a little water, and dry in the air.
STEP 19: The yield of pure phenylpropynoic acid, m.p. 134-135 °C, is 23 g (47%).
Notes to keep in mind:
1. To obtain the pure dibromo ester, recrystallise from light petroleum, b.p. 60-80 °C; the recovery of the pure ester, m.p. 75 °C, is 85 per cent.2. Carbon tetrachloride is a suspect carcinogen; avoid breathing vapour and contact with the skin and eyes.
No comments:
Post a Comment
We specialize in producing high value chemicals. Besides our regular products, we strive to develop new products based on customer’s requirements. Our R&D center plays crucial role in handling complex chemistries and developing newer technologies. We respect intellectual property rights and have confidentiality agreement with various multi national companies. We undertake contract manufacturing of fine chemicals and advance intermediates of API’s.