Acetylsalicylic acid experiment

Introduction: Commonly used as Aspirin, acetylsalicylic acid is an analgesic (pain reliever), which is one of the products of the esterification reaction between salicylic acid and acetic anhydride. This esterification occurs since the hydroxyl group from the salicylic acid reacts with acetic anhydride to form an ester. In this experiment, we will be able to recreate this acid catalyzed reaction, using sulfuric acid as our catalyst in order to produce acetylsalicylic acid and acetic acid. The final product of this reaction will be some crystals, which will be mainly composed of acetylsalicylic acid.

In order to purify our products, we will have to add water to our crystals so that the acetylsalicylic acid can be dissociated from impurities. Using a technique called vacuum filtration, crystals will be held on a filtration paper while the liquid portion of reagents will drained into an Erlenmeyer flask. To purify our crystals even more, we will have to perform a procedure called re-crystallization, using ethyl acetate as our solvent instead of water in order to prevent decomposition of our products, and then once again we will use vacuum filtration to separate the crystals from the solvent.

After we have finished with the experiment, we will be testing for the presence of salicylic acids in our crystals. Salicylic acid is a phenol and it will react with a mixture of Ferric Chloride by changing the color of the solution into a dark purple. If our crystals change color, it will mean that we still have some impurities and the melting point of the acetylsalicylic acid may be affected by the presence of these impurities. Mechanism: Results: Table 1. 1: Acetylation of Salicylic Acid Weight of Salicylic Acid | 2. 00 g| Mass of Watch glass + filter paper| 32.

43g| Mass of Watch glass + filter paper and product of re- crystallization| 35. 55 g| Mass of product of re-crystallization| 35. 55 g – 32. 43g = 3. 12 g| Melting point recorded of Acetylsalicylic Acid | 128- 130 ° C| Literature melting point of Acetylsalicylic Acid | 135-136 ° C| Actual yield of Acetylsalicylic Acid | 1. 56 g| Theoretical yield of acetylsalicylic Acid | 2. 61 g| Percent yield of acetylsalicylic acid | 60 %| Table 1. 2: Observations during phenol test Sample| Color| Salicylic acid | Purple | Crude crystals | Light Purple |.

Recrystallization wet products | Orange| Solvent (distilled water)| Clear yellow | *Polymerization may have occurred as a possible side product because of too much heat applied. Calculations for Acetylation of Salicylic Acid: 1. Catalyst: Sulfuric Acid 5 drops 2. Limiting Reagent: Salicylic Acid 2. 00g (1 mol salicylic acid) (1 mol acetylsalicylic acid) = 0. 0145mol Acetylsalicylic Acid (138. 10g) (1 mol Salicylic Acid) 3.

Excess Reagent: Acetic Anhydride Acetylsalicylic Acid 5. 00 mL (1. 082g) (1 mol Acetic Anhydride) (I mol Acetylsalicilyc Acid) = 0. 0530 mol (1 mL) (102.10 g) (1 mol Acetic Anhydride) 4. Theoretical Yield: 0. 0145 mol Acetylsalicylic Acid (180. 2g Acetylsalicylic acid) = 2. 61 g Acetylsalicylic Acid (1 mol Acetylsalicylic acid) 5. Actual yield: Actual yield = (1/2) x (3. 12 g crude product) = 1. 56g Acetylsalicylic acid 6. Percent Yield: (1. 56 g) x 100% = 59. 77 % ? 60% (2. 61 g) Discussion: Through our calculations we were able to determine salicylic acid as our limiting reagent, which means that the amount of acetylsalicylic acid produced will be determined by the amount of salicylic acid available.

Through this experiment, we were able to learn procedures such as esterification, which involves the production of aspirin, as well as techniques such as crystallization and re-crystallization that can help us achieve a pure end product. Impurities, as we were able to observe, play a significant role in this experiment because they affect the quality of our results. The more impurities present in our end product then, the lower the melting points of the crystals might be, and the possibility of a positive ferric chloride test may be higher.

Overall, the percentage yield for this reaction was 60 % which could have been due to errors in the process of crystallization, re-crystallization or due to insufficient time needed to dry the compound after re-crystallization. Experimental Procedure: Preparation and Crystallization of Acetylsalicylic Acid In a 125 mL Erlenmeyer flask add salicylic acid (2 g, 0. 0145 mol), acetic anhydride (5 mL, 0. 053) and 5 drops of sulfuric acid. Swirl mixture until fully dissolved, and proceed to heat flask in a water bath at 50° C for 10 minutes.

Allow the mixture to cool down at room temperature and then place the solution on an ice bath until the formation of crystals cease, if no crystals are formed scratch the side walls of the flask with a glass rod. Proceed to add 50 mL of distilled water into the solution and observe the further process of crystallization. At this point you should see crystals in the mixture. Then, set up the filtration apparatus, which should include a flask, Buchner funnel, filter adapter, filtration paper and a rubber hose that will connect the flask to the vacuum device.

Test the filtration device with water, before placing the crystals in the solution. Filter the crystalinization product for 5-10 min and finally rinse the crystals with some distilled water. Re-crystallization of Crude Acetylsalicylic Acid Dissolve crude product of previous crystalinization in a clean 125 mL Erlenmeyer flask with ethyl acetate (2-3 mL). Gently heat the solution on a hot plate to dissolve the reagents and then allow the solution to cool down at room temperature. At this point crystals should form, if not add petroleum ether to the solution.

Place the flask with the solution on an ice bath until crystallization is complete. Once again, set up the vacuum filtration that was used to collect crude crystal product and vacuum dry the crystals for 10 minutes. Perform the ferric chloride test by setting up four test tubes with salicylic acid, products of crystalinization, products of re-crystalinization and distilled water respectively in order to detect the presence of phenol. Finally, after placing the products of re-crystalinization in the oven for 5-10 min record its mass and its melting point.

Conclusion: Our results lead us to think that the possible reason for this low percentage, as well as for the differences between melting point range obtained and the actual melting point (128- 130 ° C 0 ° C instead of 135- 136 ° C) might have been due errors in the time that the re-crystallized sample spent in the oven. This theory is reinforced by the fact that within the ferric chloride test the sample tested negative for phenol, meaning that there was no salicylic acid was present.

Questions: 1. What is the purpose of the concentrated sulfuric acid used in the first step? The sulfuric acid is used as an acid catalyst in the acetylation reaction. A catalyst is used to lower the level of the activation energy, hence speeding up the reaction. 2. What would happen if the sulfuric acid were left out It would have taken the reaction much longer to reach the activation energy, and the reaction would have not occurred as fast as it did. 3. If you used 5.

0 g of sulfuric acid and excess acetic anhydride in the preceding synthesis of Aspirin, what would be the theoretical yield of acetyl salicylic acid in moles? In grams? 5. 00g (1 mol Sulfuric Acid) (1 mol Acetylsalicylic Acid) = 0. 0510 mol Acetylsalicylic (98. 079 g) (1 mol Sulfuric Acid) 0. 0510 mol Acetylsalicylic (180. 2 g acetylsalicylic acid) = 9. 19 g Acetylsalicylic Acid (1 mol Acetylsalicylic Acid) 4. What is the equation for the decomposition reaction that can occur with aspirin? Water + acetylsalicylic acid acetic acid + salicylic acid.

5. Most aspirin tablets contain 5 grains of acetylsalicylic acid. How many milligrams is this? Since one grain = 65 mg, then an aspirin tablet will contain 65 mg * 5 =324 mg 6. A student performed the reaction in this experiment using a water bath at 90°C instead of 50°C. The final product was tested for the presence of phenols with ferric chloride. This test was negative. (no color was observed); however, the melting point of the dry product was 122-125°C. Explain these results as completely as possible.

Within the salicylic acid portion of the mechanism, a polymerization reaction occurred because there was such a high temperature. The polymer that was created was an impurity and due to this impurity the melting point of the product was lower than expected. 7. If the aspirin crystals were not completely dried before the melting point was determined, what effect would this have on the observed melting point? If the solvent is present after the crystalinization, then this will lower the melting point of the product.

Cited Work Pavia, Donald L.A Small-scale Approach to Organic Laboratory Techniques. Belmont, CA: Brooks/Cole ; Cengage Learning, 2011. Print. “Acetylsalicylic acid (50-78 2). ” Chemical Book. 2008. Web. 23 Jan. 20003. <http://www. chemicalbook. com/ProductMSDSDetailCB5114818_EN. htm> Literature Article: The melting process of Acetylsalicylic Acid single crystals The process of crystallization was studied by G. L. Perlovich and A. Bauer-Brandl in comparison to crystal growth of Acetylsalicylic Acid. The present work postulates an analogy to melting processes, looking at melting as nucleation.