ࡱ> RTQ7 bjbjUU %D7|7|dl8&,R,-$OOO}+ #$' *~#O|OOO#I#O@R}O}a"a~ 6 aa#0-$a**aTutorial 12 - Solutions Determining the Concentration of a Specific Ion Using Precipitation Titrations. Answer to Question 1 on page 12 of Tutorial 12. 1. In order to find the concentration of chloride ion in a sample of pool water, a 50.0 mL sample of the pool water was titrated with 0.500 M AgNO3 solution, using sodium chromate solution (Na2CrO4 (aq)) as an indicator. At the equivalence point, it was found that 53.4 mL of AgNO3 solution had been added. a) Calculate the moles of Ag+ used. moles = M x Litres = 0.500 M x 0.0534 L = 0.0267 moles of Ag+ b) Write the balanced net-ionic equation for the titration. Ag+(aq) + Cl-(aq) ( AgCl(s) c) Determine the moles of Cl- ions in the sample. From the ratio of coefficients in the balanced net-ionic equation:  moles of Cl- = moles of Ag+ x 1 mol Cl-  1 mol Ag+ = 0.0267 moles of Cl- d) Calculate the [Cl-] in the sample of pool water. M = moles = 0.0267 moles = 0.534 M L 0.05 L Since the lowest number of significant digits in the question is 3, the answer would have three significant digits. so [Cl-] = 0.534 M Answer to Question 2 on page 13 of Tutorial 12. 2. A solution containing silver ions (Ag+) is titrated with 0.200 M KSCN solution to find the [Ag+] in the sample. The indicator Fe(NO3)3 (aq) is used to signal when the equivalence point is reached. It is found that 15.6 mL of 0.200 M KSCN is needed to titrate a 25.0 mL sample of Ag+ solution. Determine the [Ag+] in the sample. Show all steps in a clear concise manner. (Use question 1 as a guide.) moles of SCN- used: moles = M x L = 0.200 M x 0.0156 L = 0.00312 moles of SCN- Balanced Net-Ionic Equation: Ag+(aq) + SCN-(aq) ( AgSCN(s) moles of Ag+ in sample: Since the ratio of coefficients is 1:1,  moles of Ag+ = moles of SCN- x 1 mol Ag+  1 mol SCN- = 0.00312 moles of Ag+ Molar concentration of Ag+ ( [Ag+] ) M = moles = 0.00312 moles = 0.1248 M L 0.025 L The answer would be rounded to 3 significant digits, as this was the lowest number of significant digits in the data. [Ag+] = 0. 125 M Answer to Question 3 on page 13 of Tutorial 12. 3. Explain how the indicator Na2CrO4 works in titrations for chloride (Cl-) ion concentration using Ag+ as a standard solution. The Ag+ ions will keep bonding with the Cl- ions forming the white precipitate AgCl as long as there are Cl- ions present. As soon as all the Cl- ions are used up, the Ag+ will then start precipitating with the CrO42- ions, forming the precipitate Ag2CrO4. But recall from the last page that the colour of Ag2CrO4 is brick red. Thus, as you can see, as soon as all the Cl- ions are used up, the next drop of Ag+ solution will turn the solution red.  So, as soon as all the Cl- is consumed, and a small amount of Ag2CrO4 forms, a faint brick red colour will be noticed. At this point, we would STOP the titration. ************************************************************************* Answer to Question 4 on Page 13 of Tutorial 12. 4. Explain how the indicator Fe(NO3)3 works in titrations for silver (Ag+) ion concentration using SCN- as a standard solution. The main reaction for the titration is a precipitation of Ag+ and SCN- ions to form a precipitate of AgSCN (s): Ag+(aq) + SCN-(aq) ( AgSCN(s) colourless colourless white precipitate Once just enough SCN- solution has been added to react with all the Ag+ ions, (the equivalence point), any excess SCN- ions added will react with the indicator, Fe3+ ions and form a complex ion (a larger ion made up of smaller ones) called FeSCN2+. This ion, called the ferrothiocyanate ion, is NOT a precipitate, BUT is IS a very intense red colour. You may recall seeing it when you did Experiment 19-A on equilibrium. The reaction is: Fe3+(aq) + SCN-(aq) ( FeSCN2+(aq) pale rust colourless dark red A slight permanent red would appear at the endpoint of the titration. This would indicate that the equivalence point (the point where there is just enough SCN- to react with all the Ag+ in the sample) has been reached. 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