ChemCollective-Virtual-Labs/C4/Determination-of-pKa-of-Acetic-acid/English-timed
From Script | Spoken-Tutorial
| Time | Narration |
| 00:01 | Welcome to the spoken tutorial on Determination of pKa of Acetic Acid using ChemCollective Vlabs. |
| 00:09 | In this tutorial, we will,
Titrate 0.1 molar acetic acid with 0.1 molar sodium hydroxide. |
| 00:18 | Estimate the equivalence point for the titration using an indicator |
| 00:23 | Find the equivalence point by the pH titration method. |
| 00:28 | Draw the titration curve to determine the pH at the half-equivalence point. |
| 00:34 | This tutorial is recorded using,
Ubuntu Linux OS version 18.04 |
| 00:41 | ChemCollective Vlabs version 2.1.0 |
| 00:46 | Java version 11.0.8 |
| 00:51 | To follow this tutorial you should be familiar with ChemCollective Vlabs interface. |
| 00:57 | For the prerequisite tutorials please visit this website. |
| 01:01 | Let us begin with the dissociation of a weak acid. |
| 01:05 | The dissociation of a weak acid is mathematically described by the Henderson-Hasselbalch equation. |
| 01:12 | It relates pH and pKa to the equilibrium concentrations of acid and its conjugate base. |
| 01:20 | At the half-equivalence point, the concentration of acid and its conjugate base are equal. |
| 01:27 | Hence pH at this point is equivalent to pKa. |
| 01:32 | Here I have opened the Vlabs interface in the Default Lab Setup. |
| 01:37 | Workbench 1 opens by default. |
| 01:41 | Stockroom Explorer on the left contains required chemicals. |
| 01:46 | Let us titrate 0.1 molar acetic acid with 0.1 molar sodium hydroxide. |
| 01:53 | We will estimate the equivalence point for this titration. |
| 01:57 | First, let us place all the required chemicals and glassware on the workbench. |
| 02:03 | From the Stockroom Explorer double-click to select Distilled water. |
| 02:08 | From the Strong-bases cabinet select 0.1 molar sodium hydroxide. |
| 02:14 | Close the Strong-bases cabinet. |
| 02:17 | Open the Weak-acids cabinet. |
| 02:21 | The Weak acids cabinet has acetic acid and dichloroacetic acid. |
| 02:26 | We will choose 1 molar acetic acid. |
| 02:29 | Close the Weak-acids cabinet. |
| 02:33 | For the titration, we need 0.1 molar acetic acid. |
| 02:38 | So we will dilute 1 molar acetic acid by 10 times. |
| 02:43 | From the glassware menu select 250 ml Erlenmeyer flask. |
| 02:49 | Let us rename the flask as 0.1 M Acetic acid using the context menu. |
| 02:57 | Let us add 90 mL of water to the Erlenmeyer flask. |
| 03:02 | Drag the distilled water tank over the Erlenmeyer flask. |
| 03:07 | In the Transfer amount input bar type 90 and then click on Pour button. |
| 03:14 | Drag the distilled water tank back to its place. |
| 03:18 | Now let us add 10 mL of 1 molar acetic acid to the Erlenmeyer flask. |
| 03:25 | For this, we will pipet out 10 mL of 1 molar acetic acid. |
| 03:31 | From the glassware menu, select 10 mL pipet. |
| 03:36 | Place the pipet in 1 molar acetic acid flask and withdraw 10 mL. |
| 03:44 | Then place the filled pipet in the Erlenmeyer flask. |
| 03:48 | Type 10 in the input bar and click on Pour. |
| 03:52 | Drag and place the 1 molar acetic acid flask and pipet aside. |
| 03:58 | Let us delete the used pipet, Distilled water and 1M Acetic acid flask from the workbench. |
| 04:06 | Let us arrange the apparatus. |
| 04:09 | Select 0.1 M Acetic acid flask if not already selected. |
| 04:15 | Note the concentrations of: acetic acid, acetate ion and hydronium ions from the Solution Info panel. |
| 04:24 | Using these values we can calculate the Ka and pKa values of acetic acid. |
| 04:31 | Acetic acid is a weak acid. |
| 04:34 | In water, acetic acid dissociates into acetate ions and protons. |
| 04:40 | All these ions will be in equilibrium with each other. |
| 04:45 | Substitute the concentrations of acetic acid, acetate ion and hydronium ions in the equation. |
| 04:54 | The values of Ka and pKa of acetic acid are shown here. |
| 05:00 | The calculated value of pKa for acetic acid is 4.757. |
| 05:07 | Back to the workbench. |
| 05:10 | Let’s estimate the amount of sodium hydroxide needed to neutralize 20 ml of 0.1 molar acetic acid. |
| 05:19 | For this titration, we will use Phenolphthalein as an indicator. |
| 05:24 | Select Phenolphthalein from the Indicators cabinet. |
| 05:28 | Close the cabinet. |
| 05:30 | In the Solution Info panel, check the radio button for Spectrometer. |
| 05:35 | Phenolphthalein has an absorption around 465 to 610 nano metres. |
| 05:43 | This will allow us to accurately detect the endpoint. |
| 05:48 | From the glassware menu let us retrieve a 250 mL Erlenmeyer flask. |
| 05:54 | In the same manner, retrieve 50 mL buret and 10 mL pipet. |
| 06:02 | Rename the Erlenmeyer flask as Flask A |
| 06:07 | Here we will use precise transfer mode to transfer the chemicals. |
| 06:12 | Let’s pipet out 20 mL of 0.1 molar acetic acid into Flask A. |
| 06:19 | Since we are using a 10 mL pipet , we will pipet out twice. |
| 06:24 | Place the 10 mL pipet on the 0.1 molar Acetic acid flask. |
| 06:30 | In the Transfer amount input bar type 10 and click on Withdraw. |
| 06:37 | Place the pipet on Flask A, type 10 and click on Pour. |
| 06:43 | Similarly, we will withdraw 10 more mL of 0.1 molar acetic acid. |
| 06:50 | Then pour it into Flask A. |
| 06:54 | Let us delete the used pipet from the workbench. |
| 06:58 | Let’s add 0.2 mL of phenolphthalein to the flask using precise transfer. |
| 07:06 | In the Solution Info panel click on Aqueous radio button. |
| 07:11 | Then click on Flask A. |
| 07:14 | Let’s fill the buret with 50 mL of 0.1 molar sodium hydroxide. |
| 07:20 | Place the 0.1 molar sodium hydroxide flask on the buret. |
| 07:25 | Type 50 in the Transfer amount input bar and click on Pour. |
| 07:31 | Now let’s start the titration. |
| 07:35 | Place the buret on the flask containing acetic acid and indicator. |
| 07:40 | Initially let’s add sodium hydroxide in the increments of 0.5 mL. |
| 07:47 | In the Transfer amount input bar type 0.5. |
| 07:52 | Click on Pour button continuously to add 0.5 mL increments of sodium hydroxide. |
| 08:00 | Now we have added 12 mL of sodium hydroxide. |
| 08:05 | Click on the buret. |
| 08:07 | Solution Info panel shows 38 mL. |
| 08:11 | Let’s now add sodium hydroxide in 0.1 mL increments. |
| 08:17 | Let’s click on the Spectrometer radio button in the right panel. |
| 08:22 | Let us continue to add sodium hydroxide in 0.1 mL increments. |
| 08:28 | Observe the spectrometer in the right panel to note the neutralization point. |
| 08:34 | The neutralization point is also called the endpoint or equivalence point. |
| 08:40 | You will see some absorbance values in the Spectrometer at the endpoint. |
| 08:45 | You will also see a faint pink colour in flask A. |
| 08:50 | This indicates the endpoint of the titration. |
| 08:54 | Click on the buret and note the final volume of sodium hydroxide added. |
| 08:59 | Solution Info panel shows 30 mL. |
| 09:03 | The volume of sodium hydroxide rundown is 20 mL. |
| 09:08 | This is the amount of sodium hydroxide required to neutralize 20 mL of acetic acid. |
| 09:15 | Let’s perform a pH titration to determine the pH at the half-equivalence point. |
| 09:22 | For this, let's record the pH changes on every addition of sodium hydroxide to acetic acid. |
| 09:29 | Let us delete the used buret and Erlenmeyer flask from the workbench. |
| 09:35 | From the glassware menu let us retrieve a 250 mL Erlenmeyer flask. |
| 09:41 | In the same manner, retrieve 50 mL buret and 10 mL pipet. |
| 09:49 | Let’s rename the Erlenmeyer flask as Flask B. |
| 09:54 | Let us also delete the used 0.1 molar sodium hydroxide flask. |
| 10:00 | Let us again retrieve 0.1 molar sodium hydroxide from the Strong-bases cabinet. |
| 10:07 | Close the cabinet. |
| 10:09 | Click on the flask containing 0.1 molar acetic acid and note the pH. |
| 10:15 | The pH Meter shows the value as 2.88. |
| 10:20 | Let us transfer 20 mL of 0.1 molar acetic acid to Flask B. |
| 10:27 | First, let us withdraw 10 mL using the pipet. |
| 10:31 | Then pour it into Flask B. |
| 10:35 | Similarly, we will withdraw and pour 10 more mL of 0.1 molar acetic acid. |
| 10:47 | Let’s add 0.2 mL of phenolphthalein to Flask B using precise transfer. |
| 10:55 | Fill the buret with 50 mL of 0.1 molar sodium hydroxide. |
| 11:03 | Place the buret on Flask B. |
| 11:05 | Initially let us add sodium hydroxide in 0.5 mL increments to acetic acid. |
| 11:14 | Note the change in pH after every addition. |
| 11:18 | We continue to add sodium hydroxide, till 9 mL in the increments of 0.5 mL. |
| 11:26 | Note the change in pH after every addition. |
| 11:30 | At 9 mL we will change the transfer amount to 0.2 mL. |
| 11:35 | Then continue to add sodium hydroxide, in increments of 0.2 mL up to 18 mL. |
| 11:43 | Note the change in pH values |
| 11:46 | At 18 mL let's change the transfer amount to 0.1 mL. |
| 11:52 | Continue the titration till the endpoint is detected. |
| 11:56 | Again note the changes in pH values |
| 12:00 | At exactly 20 mL we see the equivalence point with a pH change. |
| 12:06 | Now again change the transfer amount to 0.2 mL. |
| 12:11 | Continue to add sodium hydroxide till 22 mL. |
| 12:15 | Here we see a very rapid rise in the pH values. |
| 12:19 | Note the pH changes again after each addition. |
| 12:23 | Note the final volume of sodium hydroxide in the buret. |
| 12:28 | Here I have noted the values and tabulated them. |
| 12:32 | The volume of sodium hydroxide added and the corresponding change in pH. |
| 12:41 | Now let’s plot a graph. |
| 12:43 | This is for the volume of sodium hydroxide added versus the change in pH. |
| 12:49 | Here is the plot. |
| 12:51 | It shows an equivalence point at pH 7. |
| 12:55 | At this point there is a sharp increase in pH. |
| 12:59 | The volume of NaOH at this point is 19.9 mL. |
| 13:05 | At exactly half volume is the half-equivalence point. |
| 13:10 | The pH at this point is 4.75. |
| 13:14 | According to the Henderson-Hasselbalch equation, at this point pH is equal to pKa. |
| 13:21 | Hence the value of pKa of acetic acid is 4.75. |
| 13:26 | Here we have used Grace software to plot the graph. |
| 13:30 | You can use any software that is convenient for you to plot the graph. |
| 13:35 | Let us summarize. |
| 13:37 | In this tutorial we have,
Titrated 0.1 Molar acetic acid with 0.1 Molar sodium hydroxide. |
| 13:46 | Estimated the equivalence point for the titration using an indicator |
| 13:51 | Found the equivalence point by the pH titration method. |
| 13:56 | Drawn the titration curve to determine the pH at the half-equivalence point. |
| 14:02 | As an Assignment,
Titrate 0.1 molar sodium hydroxide against 0.1 molar dichloroacetic acid |
| 14:11 | Estimate the pH at the endpoint. |
| 14:14 | Find Ka and pKa values. |
| 14:17 | Draw the graph to find the half-equivalence and equivalence points |
| 14:23 | The video at the following link summarizes the Spoken Tutorial project.
Please download and watch it. |
| 14:29 | The spoken tutorial project team, Conducts workshops and gives certificates.
For more details, please write to us |
| 14:37 | Please post your timed queries in this forum. |
| 14:41 | Spoken Tutorial Project is funded by the Ministry of Education, Government of India. |
| 14:46 | This tutorial is contributed by Madhuri Ganapathi and Snehalatha Kaliappan from IIT-Bombay.
Thank you for watching. |
