ࡱ> bdaU@ Lbjbj -DOFFFZ,,,8V,t,ZE-:$.(L.L.L.111;;;;D <@3E$FRHdWEF1 1|111WEL.L.lE8881 RL.FL.;81;889$"F9L.- HZ,,6r999E0E9RI8FRI9ZZRIF9 11811111WEWEZZ(,_8(ZZ,Titration of Sodium Carbonate with Hydrochloric Acid NAME:________________________________________ PERIOD:___________ Prelab 1. Write an equation, which correctly represents solid sodium carbonate dissolving in water. 2. During the titration of sodium carbonate with HCl, the dissolved carbonate ion will exist in three different forms; CO3-2, HCO3-1, and H2CO3. During which part of the titration (initial, first equivalence point, or second equivalence point) will each form predominate. Explain your answer. 3. Why are two different indicators being used in this experiment? 4. Explain the difference between the terms endpoint and equivalence point? 5. Calculate the molarity (M) of HCl used in the titration of a 0.2239-g sample of sodium carbonate that required 39.01 mL of the titrant (HCl) to reach the second equivalence point. Titration of Sodium Carbonate with Hydrochloric Acid Objectives: In this experiment, a solution of Na2CO3 will be titrated with a solution of HCl. The pH of the solution will be monitored as the HCl is added with a pH probe attached to a CBL. The shape of the pH titration curve will be observed and the Kb values for the base will be determined. How closely the indicator color changes coincide with the equivalence points will be observed. Introduction: Carbonate ion, CO3-2, is a diprotic base, and shows the following ionization reactions in aqueous solution: CO3-2 (aq) + H2O (l) ( HCO3-1 (aq) + OH-1 (aq)  EMBED Equation.2  HCO3-1 (aq) + H2O (l) ( H2CO3 (aq) + OH-1 (aq)  EMBED Equation.2  The designation Kb1 refers to this being the first base ionization constant for CO3-2. CO3-2 should be recognized as the conjugate base of HCO3-1 and Kb1 equals Kw/Ka2 where Ka2 is the Ka for HCO3-1, which is also the second ionization constant for H2CO3. Likewise, Kb2 refers to the second base ionization constant for CO3-2. HCO3-1 should be recognized as the conjugate base of H2CO3 and Kb2 equals Kw/Ka1 where Ka1 is the first ionization constant for H2CO3. CO3-2 requires two hydrogen ions for complete neutralization to carbonic acid. The neutralization occurs in two consecutive steps represented by the equations: CO3-2(aq) + H+1(aq) ( HCO3-1(aq) HCO3 -1 (aq) + H+1 (aq) ( H2CO3(aq) Two equivalence points can be detected, one when all of the CO3-2 has been converted to the amphiprotic HCO3-1, and second when all of the HCO3-1 has subsequently been converted to H2CO3. In this experiment an accurately massed sample of solid sodium carbonate is dissolved in water and titrated using approximately 0.1 M HCl. Phenolphthalein and then bromocresol green indicators will be added to verify that the endpoints located visually, using indicators, are close to the equivalence points. Phenolphthalein, which changes from pink at pH 9.8 to colorless at pH 8.1 is a fair indicator for locating the first equivalence point, which occurs at about pH 8.35. Beyond the first equivalence point phenolphthalein is colorless and therefore does not interfere with observation of the subsequently added bromocresol green, which changes from blue at pH 5.4 to yellow at pH 3.8. The pH at the second equivalence point lies within this color transition interval. The pH at the second equivalence point is not known exactly because of the partial loss of CO2 during the second stage of the titration. The H2CO3 being formed breaks down to CO2 and H2O, and part of the CO2 escapes, depending on how vigorously the solution is stirred. Nevertheless, a reasonably distinct change in pH is observed. A diprotic base will show significant decreases in pH at the equivalence points. These will only be clearly visible if each successive Kb is significantly smaller than the previous one by a factor of 103 to 104. If Kb1 and Kb2 are too close in value, only one break in pH may be seen at the position of the second equivalence point. If the initial moles of the diprotic base, either by its mass or by using a volume of known molarity, and the initial concentration of HCl are known, the equivalence points and Kb values can be calculated from the titration curve. Alternatively, if the Kb values are known, the concentration of the HCl can be determined from the volume of HCl required to reach the equivalence point. Kb1 can be calculated using the initial concentration of the base and the initial pH of the solution. If Kb1 is significantly greater than the other ionization constant by a factor of at least 103, the [OH-1] can be assumed to come essentially from only the first ionization and can be calculated from the initial pH using Kw = [H3O+1][OH-1] = 1.0x10-14. The [HCO3-1] approximately equals [OH-1] in the initial solution. Assuming the CO3-2 is only slightly ionized, the [CO3-2] is approximately equal to its initial concentration. Kb1 can be calculated from the pH at the first half-equivalence point. At this point in the titration, half of the moles of CO3-2 have been converted to HCO3-1. The [HCO3-1] = [CO3-2], the ratio [HCO3-1]/[CO3-2] equals one, the [OH-1] equals Kb1, and the pOH of the solution equals pKb1. Remember that in aqueous solutions pH + pOH = 14. Kb2 can be calculated from the pH at the first equivalence point (assuming Kb1 has been calculated). All the moles of CO3-2 have been converted to HCO3-1. The HCO3-1 can hydrolyze by the reaction: HCO3-1 (aq) + H2O (l) ( H2CO3 (aq) + OH-1 (aq) It can ionize by the reaction: HCO3-1 (aq + H2O (l) ( H3O+1(aq) + CO3-2(aq) This point in the titration curve is equivalent to the first equivalence point in the titration of H2CO3 with NaOH since they result in a solution of HCO3-1 ion. Since Ka1 and Ka2 are significantly different, the pH at the first equivalence point of the titration of H2CO3 with NaOH will be approximately equal to the average of pKa1 and pKa2.  EMBED Equation.2  Two values of Kb1 have already been determined. These values can be averaged. Since Kb1 = Kw/Ka2, a value of Ka2 can be calculated. The value of pKa2 can be calculated. Using the pH at the first equivalence point, pKa2, and the expression above, a value of pKa1 can be calculated. This is used to obtain a value of Ka1. Since Kb2 = Kw/Ka1, Kb2 can be calculated. Kb2 can be approximated from the pH at the second half-equivalence point. At this point in the titration, half of the moles of HCO3-1 have been converted to H2CO3. The [HCO3-1] = [H2CO3], the ratio [H2CO3]/[HCO3-1] equals one, the [OH-1] equals Kb2, and the pOH of the solution equals pKb2. Kb2 is not calculated from the second equivalence point because by this point in time, a significant amount of the H2CO3 has probably decomposed to form CO2 and H2O and the CO2 has escaped from the solution. The exact concentration of H2CO3 would be difficult to determine. Two indicators are used in this experiment to correspond to the two equivalence points. Phenolphthalein changes from pink pH 10 to colorless at pH 8 for the first equivalence point. Bromcresol green changes from blue at pH 5.2 to yellow at pH 3.8 for the second equivalence point. Procedure: Using the initial mass of the Na2CO3 and molarity of the HCl, calculate the first and second equivalence point and half-equivalence point volumes of HCl and make sure that these points are part of the titration data taken. Check your equivalence point and half-equivalence point volumes with your instructor before you start the titrations. 1. Mass accurately (to within 0.1 mg) a 0.20 to 0.22-g sample of Na2CO3 into a plastic weighing dish. [Note: if the sample is too large it may require more than 50 mL of HCl titrant, making it necessary to refill the buret and thereby introducing two more buret reading errors.] Transfer the solid to a 250mL beaker. 2.Pipet 50.00 mL of distilled water into the beaker. Use the water from the pipet to carefully rinse any solid remaining in the weighing dish into the beaker. Add a small magnetic stirring bar and stir to dissolve the compound. Add 4-5 drops of phenolphthalein. 3. Rinse a 50-mL buret with a few mL of approximately 0.100 M HCl solution. Repeat rinsing once more with a few more mL of HCl solution. Allow the HCl solution to drain into a waste beaker. Fill the buret a little above the 0.00mL level with the 0.100 M HCl solution. Drain a small amount of HCl solution so it fills the buret tip and leaves the HCl at the 0.00mL level of the buret. Make sure that no air bubbles are in the buret tip. 4. Record the actual concentration of the HCl solution. Set up the calculator and CBL for pH measurement: 1. Connect the CBL unit to the TI-83/83+ calculator with the unit-to-unit link cable using the I/O ports located on the bottom edge of each unit. Press the cable ends in firmly. 2. Connect the CBL DIN adapter to the end of the Vernier pH probe and plug the adapter into channel 1, CH 1, on the CBL unit. Plug the CBL voltage adapter into the bottom of the CBL 3. Turn on the CBL unit and calculator. The CBL system is now ready to receive commands from the calculator. Calibration Procedure: Make sure the CBL unit and the calculator are turned on. 1. Press [PRGM] on the TI-82/83. Using the arrow keys, highlight the program CHEMBIO. Press [ENTER]. CHEMBIO may be under the [APPS] menu on the 83+. 2. (Display should read prgmCHEMBIO) Press [ENTER]. 3. (Display should read VERNIER SOFTWARE...) Press [ENTER]. 4. Select SET UP PROBES by using the arrow keys to highlight this choice. Press [ENTER]. (If you get the ***Link Error*** message check all link connection and make sure CBL is turned on. Press [ENTER] and continue) 5. The display should read Enter number of probes. You are using only one probe, therefore press [1] and [ENTER]. The CBL display should show three dashes. 6. You are using the pH probe, therefore, select pH. Press [ENTER]. 7. You should have your probe connected in channel one, CH 1, therefore, press 1 and [ENTER]. 8. The display should now show a Calibration Menu. You want to select Perform New by using the arrow keys to highlight this choice then press [ENTER]. The message Use [CH View] Button on CBL to Monitor Voltage When Stable Press CBL Trigger will appear. 9. Remove the pH probe from the storage bottle. Rinse the pH probe with distilled water and carefully shake off the water. Place the probe in the standard solution pH 4. When the voltage reading on the CBL is stable, press [TRIGGER] on the CBL. The probe is in the standard solution pH 4, enter [4] as the reference value in the calculator and press [ENTER]. 10. Rinse the pH probe with distilled water and carefully shake off the water. Place the probe in the standard solution pH 10. When the voltage reading on the CBL is stable, press [TRIGGER] on the CBL. The probe is in the standard solution pH 10, enter [10] as the reference value in the calculator and press [ENTER]. 11. The calculator should show the intercept and slope values of the calibration line. Press [ENTER]. 12. You should now be back at the Main Menu display on the calculator. 13. Place the pH back in the storage bottle until you are ready to take measurements. Collection of pH Data: 1. Place the beaker with the Na2CO3 solution under the tip of the buret. Remove the pH electrode from the storage bottle and rinse it with distilled water into the waste beaker. Clamp the pH electrode in the 250mL beaker so the tip of the electrode is below the surface of the solution. Adjust the position of the electrode so the stir bar will not hit the electrode. 2. Turn on the magnetic stirrer and stir the solution at a moderate rate but not so fast that it vortexes or splatters solution on the side of the beaker. 3. Select Collect Data. Press [ENTER]. 4. Select Trigger/Prompt. Press [ENTER]. (The calculator display should read Allow 30 sec. for CBL to warm up. The CBL should display Ready and three numbers.) 5. Press [ENTER]. 6. Monitor the CBL display and when the numbers on the CBL display have stabilized, press [TRIGGER] on the CBL. 7. [ENTER] volume (mL) should appear on the calculators display. This display is prompting you to enter the amount, in mL, of HCl you have added to the acid in the beaker. You have NOT yet added any NaOH from the buret to the acid, therefore, type 0 for volume of HCl added. Press [ENTER]. 8. The calculator now displays a Data Collection menu. Select MORE DATA. Press [ENTER]. 9. Add as close to 1.00 mL of HCl as possible from the buret to the acid in the beaker. 10. When the CBL display is stabilized, press [TRIGGER]. 11. Enter into the calculator the cumulative volume of HCl that was added to the beaker (1.00mL) which should be the buret reading. If you accidently add more than 1.00 ml of HCl, enter the actual buret reading (ie. 1.10mL). 12. You should now be back to the Data Collection menu. Select MORE DATA. Press [ENTER]. 13. Repeat Steps 9-12 until 50.00 mL of HCl has been added to the beaker. Record the volume when the phenolphthalein turns colorless. Add 4-5 drops of bromocresol green, continue the titration, and record the volume when the indicator turns yellow. 14. Select: Stop and Graph (a graph should appear). Sketch the graph below. Press [ENTER].     15. Select [NO] for repeating the experiment. Press [ENTER]. This should return you to the Main Menu. 16. Select Quit to exit the program. Press [ENTER]. 17. Rinse the pH probe with distilled water and return it to the storage bottle. Turn off the CBL. 18. Check your lists by pressing [STAT]. EDIT should be highlighted. Press [ENTER]. The volume of HCl added should be in L1 and the pH data should be in L2. Record these values in the Data Table. 19. Take your calculator to a computer and down load your data. 20. Label and units for the X-axis: Volume of HCl and ml. 21. Label and units for the Y-axis: pH with the no units. 22. Set the number of decimal places to two. 23. Add Connecting Lines under the Graph Menu. 24. Select Scaling under the Graph menu and scale both axes from zero. 25. Name the graph as Na2CO3-HCl Titration. 26. Click on the ZOOM box at the upper right corner of the graph window to enlarge the graph. 27. Select Page Setup under the File menu and select the option to print the graph so that it goes down the page. Print the graph. 28. Click on the data table. Name the data table as Na2CO3-HCl Titration. 20. Print Data Table under the File Menu. Calculations: 1. Plot the titration curve and submit a set of data for the titration. 2. Use the initial pH the solution to calculate Kb1. Remember that 50.00 ml of water was added to prepare the solution. 3. Once the equivalence point has been calculated from the known concentration acid and the moles of Na2CO3, estimate graphically the pH at the first half equivalence point, the first equivalence point, and the second half equivalence point. 4. Calculate Kb1 from the initial pH and the pH at the first half equivalence point. Average these values. 5. Use the average value of Kb1 to calculate values Ka2 and pKa2. Using the pH at the first equivalence point and pKa2, calculate a value of pKa1. Calculate a value of Ka1. Calculate a value of Kb2 at the first equivalence point. 6. Use the pH at the second half equivalence point to calculate a second value of Kb2. 4. Average the value for each ionization constant and calculate the percent error based on the accepted values: Kb1 = 2.1x10-4 p Kb1 = 3.68 Kb2 = 2.2x10-8 p Kb2 = 7.66 These are based on the values of H2CO3 of Ka1 = 4.5x10-7 and Ka2 = 4.7x10-11 This experiment was adapted from Experiment 24- Acid-Base Titration- from Chemistry with CBL by Holmquist, Randall, and Volz from Vernier Software 1995 Titration of Sodium Carbonate with Hydrochloric Acid NAME:_____________________________________________ PERIOD:__________ LAB PARTNER:_____________________________________ COURSE:_________ Data Table Plot your data using Graphical Analysis. Submit the graph and data table for the titration, being sure to label both axes. Mass of Na2CO3Molar mass of Na2CO3Moles of Na2CO3Initial Molarity of the Na2CO3 solutionMolarity of HClVolume of HCl where phenolphthalein indicator changedVolume of HCl where bromocresol green indicator changedVolume of HCl required to reach first half-equivalence pointVolume of HCl required to reach first equivalence pointVolume of HCl required to reach second half-equivalence pointVolume of HCl required to reach second equivalence pointpH at initial pointpH at first half-equivalence pointpH at first equivalence pointpH at second half-equivalence pointKb1 based on initial pointKb1 based on first half-equivalence pointKb2 based on first equivalence pointKb2 based on second half-equivalence pointAverage value of Kb1Average value of Kb2Accepted value of Kb1Accepted value of Kb2% Error in Kb1% Error in Kb2Compare the endpoint volumes where the indicators changed with the calculated equivalence point volumes. Show your calculations for Kb1 and Kb2 at the half-equivalence and equivalence points listed in the Data Table on the back of this page. The calculations should show the specific equilibrium setups complete with the initial, change, and equilibrium concentrations. 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currentpoint translate 64 45 translate /thick 0 def /th { dup setlinewidth /thick exch def } def 16 th 994 560 moveto 2401 0 rlineto stroke /cat { dup length 2 index length add string dup dup 5 -1 roll exch copy length 4 -1 roll putinterval } def /ff { dup FontDirectory exch known not { dup dup length string cvs (|______) exch cat dup FontDirectory exch known {exch} if pop } if findfont } def /fs 0 def /cf 0 def /sf {exch dup /fs exch def dup neg matrix scale makefont setfont} def /f1 {ff dup /cf exch def sf} def /ns {cf sf} def /sh {moveto show} def 384 /Times-Italic f1 (K) 5 659 sh (H) 1146 355 sh (CO) 1549 355 sh (OH) 2418 355 sh (HCO) 1624 960 sh 224 ns (b) 268 755 sh 224 /Times-Roman f1 (2) 398 755 sh (2) 1423 451 sh (3) 2053 451 sh (1) 3131 183 sh (3) 2405 1056 sh (1) 2653 794 sh 384 /Symbol f1 (=) 660 659 sh /f3 {ff 3 -1 roll .001 mul 3 -1 roll .001 mul matrix scale makefont dup /cf exch def sf} def 384 1000 1450 /Symbol f3 ([) 993 401 sh (]) 2199 401 sh 384 1000 1619 /Symbol f3 ([) 2290 417 sh (]) 3269 417 sh 384 1000 1583 /Symbol f3 ([) 1471 1019 sh (]) 2791 1019 sh 224 /Symbol f1 (-) 3009 183 sh (-) 2531 794 sh end MTsave restore dMATH K b2 =H 2 CO 3 []OH -1 []HCO 3  -1 []ttFMicrosoft Equation Editor 2.0DNQE Equation.2CompObjeYObjInfogEquation Native h_949051826Fp2GZ,p2GZ, K b2 =H 2 CO 3 []OH -1 []HCO 3  -1 []T X0     ^ .Ole lPIC mTMETA oPICT   & Times JwSwgw  -!pHPSymbol JwSwgw  -!=Times JwSwgw  -!pK !Times JwSwgw  -!a 0Times JwSwgw  -!1 3PSymbol JwSwgw  -!+ :Times JwSwgw  -!pK DTimes JwSwgw  -!a RTimes JwSwgw  -!2 WTimes JwSwgw  -!2;-  [ & '^dxpr  ^"^ currentpoint ",Times .+pH, Symbol)=( !pK +a)1 ( :+) pK +a)2 (;2" ;/MTsave save def 40 dict begin currentpoint 3 -1 roll sub neg 3 1 roll sub 3008 div 896 3 -1 roll exch div scale currentpoint translate 64 34 translate /thick 0 def /th { dup setlinewidth /thick exch def } def 16 th 962 411 moveto 1929 0 rlineto stroke /cat { dup length 2 index length add string dup dup 5 -1 roll exch copy length 4 -1 roll putinterval } def /ff { dup FontDirectory exch known not { dup dup length string cvs (|______) exch cat dup FontDirectory exch known {exch} if pop } if findfont } def /fs 0 def /cf 0 def /sf {exch dup /fs exch def dup neg matrix scale makefont setfont} def /f1 {ff dup /cf exch def sf} def /ns {cf sf} def /sh {moveto show} def 384 /Times-Italic f1 (pH) 28 510 sh (pK) 1022 261 sh (pK) 2134 261 sh 224 ns (a) 1479 357 sh (a) 2591 357 sh 384 /Symbol f1 (=) 628 510 sh (+) 1804 261 sh 224 /Times-Roman f1 (1) 1591 357 sh (2) 2721 357 sh 384 ns (2) 1830 811 sh end MTsave restore dYMATHM  pH=pK a1 +pK a2 2FMicrosoft Equation Editor 2.0DNQE Equation.2M pH=pK aCompObjYObjInfoEquation Native i1TableRI1 +pK a2 2Oh+'0x   ( 4 @ LX`hpAcid-Base Titrationcidncssmascss Normal.dotiroser.d2seMicrosoft Word 10.0@F#@C}@Z,@Z,, :SummaryInformation(DocumentSummaryInformation80CompObjj՜.+,0 hp  NCSSMs{" D{ Acid-Base Titration Title  FMicrosoft Word Document MSWordDocWord.Document.89q<@< NormalCJ_HmH sH tH J@J 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