Determining the Concentration of a Solution: Beer s Law Vernier Spectrometer 1 The primary objective of this experiment is to determine the concentration of an unknown copper (II) sulfate solution. You will use a Vernier Spectrometer (V-SPEC) to measure the concentration of each solution. You will first measure the absorbance of a standard solution over the visible light spectrum (380 950 nm) and select the wavelength of maximum absorbance. A higher concentration of the colored solution absorbs more light (and transmits less) than a solution of lower concentration. The Vernier Spectrometer monitors the light passing through the sample as percent transmittance. You will prepare five copper (II) sulfate solutions of known concentration (standard solutions). Each solution is transferred to a small, rectangular cuvette that is placed into the V-SPEC. The amount of light that passes through the solution is used to compute the absorbance of each solution. When you graph absorbance vs. concentration for the standard solutions, a direct relationship should result. The direct relationship between absorbance and concentration for a solution is known as Beer s law. You will determine the concentration of an unknown CuSO 4 solution by measuring its absorbance with the V-SPEC and using the slope of the Beer s law curve. OBJECTIVES In this experiment, you will Measure and analyze the visible light absorbance spectrum of a standard copper (II) sulfate solution to determine the maximum wavelength of absorbance. Prepare and test the absorbance of five standard copper (II) sulfate solutions. Calculate a standard curve from the test results of the standard solutions. Test the absorbance of a copper (II) sulfate solution of unknown molar concentration. MATERIALS Vernier Spectrometer computer pipet pump or pipet bulb one cuvette five 20 150 mm test tubes two 10 ml pipets or graduated cylinders two 100 ml beakers 0.10 M copper (II) sulfate, CuSO 4, solution copper (II) sulfate, CuSO 4, unknown solution distilled water test tube rack stirring rod tissues (preferably lint-free) Spectroscopy with Vernier 2006 Vernier Software & Technology 1-1
Vernier Spectrometer Lab 1 PROCEDURE 1. Obtain and wear goggles. 2. Use a USB cable to connect a Vernier Spectrometer to a computer. 3. Start the Logger Pro 3.4.6 program on your computer. 4. Obtain small volumes of 0.10 M CuSO 4 solution and distilled water in separate beakers. 5. Label five clean, dry, test tubes 1 5. Use pipets to prepare four standard solutions according to the chart below (the fifth standard is the stock 0.10 M CuSO 4 solution). Thoroughly mix each solution with a stirring rod. Clean and dry the stirring rod between uses. Test Tube number 0.10 M CuSO4 (ml) Distilled H2O (ml) Concentration (M) 1 2 8 0.02 2 4 6 0.04 3 6 4 0.06 4 8 2 0.08 5 ~10 0 0.10 6. To set up the spectrometer, open the Experiment menu and select Connect Interface Spectrometer Scan for Spectrometers. 7. Calibrate the spectrometer. a. Prepare a blank by filling an empty cuvette ¾ full with distilled water. b. Open the Experiment menu and select Calibrate (Spectrometer). The following message appears in the Calibrate dialog box: Waiting seconds for the device to warm up. After 60 seconds, the message changes to: Warmup complete. c. Place the blank in the cuvette holder of the spectrometer. Align the cuvette so that the clear sides are facing the light source of the spectrometer. Click Finish Calibration, and then click. 8. Determine the maximum wavelength for CuSO 4 (aq) and set up the data collection mode. a. Empty the blank cuvette and rinse it twice with small amounts of the 0.10 M CuSO 4 solution. Fill the cuvette ¾ full with the 0.10 M CuSO 4 solution and place it in the cuvette holder of the spectrometer. b. Click. A full spectrum graph of the CuSO 4 solution will be displayed. Note that one area of the graph contains a peak absorbance. Click to complete the analysis. c. To save your graph of absorbance vs. wavelength, select Store Latest Run from the Experiment menu. d. Click the Configure Spectrometer Data Collection icon,, on the toolbar. A dialog box will appear. e. Select Absorbance vs. Concentration under Set Collection Mode. The peak absorbance will be automatically selected. Select a new wavelength, if you wish, by clicking on the graph or checking the box next to the desired wavelength. Click to proceed. If you need to start over, click and select a wavelength (or wavelengths) again. 1-2 Spectroscopy with Vernier
Determining the Concentration of a Solution: Beer s law 9. Collect absorbance-concentration data for the five standard solutions. a. Remove the cuvette from the spectrometer and dispose of the solution as directed. Use the solution in Test Tube 1 to rinse the cuvette twice with ~1 ml amounts, and then fill it ¾ full. Wipe the cuvette with a tissue and place it in the spectrometer cuvette holder. Click. When the absorbance reading stabilizes, click. Enter 0.02 as the concentration of the solution and click. b. Discard the cuvette contents as directed. Using the solution in Test Tube 2, rinse and fill the cuvette ¾ full. Wipe the cuvette and place it in the spectrometer. When the absorbance reading stabilizes, click. Enter 0.04 as the concentration. c. Repeat Step 9b for the remaining test tubes of the standard CuSO 4 solution. When you have finished testing the standard solutions, click. 10. To determine the best-fit line equation for the CuSO 4 standard solutions, click the linear fit button,, on the toolbar. Write down the equation for the standard solutions in your data table or lab book. 11. Determine the concentration of the unknown CuSO 4 solution. a. Obtain about 5 ml of the unknown CuSO 4 solution. b. Rinse the cuvette twice with the unknown solution and fill it about ¾ full. Wipe the outside of the cuvette and place it into the spectrometer. c. Select Interpolation Calculator, from the Analyze menu. A dialog box will appear that displays the concentration of your unknown at the measured absorbance. d. Click. Write down the concentration of the unknown in your data table or lab book. e. Dispose of any of the remaining solutions as directed. 12. Print a copy of your graphs and/or data table. 13. (optional) Select Save As from the File menu and save your experiment file. 14. Select Exit from the File menu to close down Logger Pro 3.4.6. Spectroscopy with Vernier 2006 Vernier Software & Technology 1-3
Vernier Spectrometer Lab 1 DATA TABLE Test Tube Concentration (mol/l) Absorbance 1 0.080 2 0.16 3 0.24 4 0.32 5 0.40 6 Unknown number DATA ANALYSIS 1. Print a graph showing the data and linear-regression equation for the standard solutions. 2. Determine the concentration of the unknown CuSO 4 solution. 3. Describe an alternate method for determining the molar concentration of your unknown sample of copper (II) sulfate solution, using the standard data. 1-4 Spectroscopy with Vernier
Determining the Concentration of a Solution: Beer s law Teacher Information 1. Prepare 100 ml of 0.10 M copper (II) sulfate solution by dissolving 2.50 g of CuSO 4 5H 2 O in sufficient distilled water to make 100 ml of solution. 2. You may substitute blue food coloring for the CuSO 4. One recipe to try is to dissolve 2 drops of food coloring per 100 ml of distilled water. Test the absorbance of this mixture to ensure that the maximum absorbance is no greater than ~1.0. 3. A suitable unknown CuSO 4 solution can be prepared by adding 25 ml of distilled water to 25 ml of the stock 0.10 M copper (II) sulfate solution. 4. The cuvette should be ~ ¾ full to get good absorbance measurements and allow enough room to seal the cuvette with a plastic cap. 5. It is important for each student lab team to use a single cuvette to test their liquids in the spectrometer. This will eliminate errors introduced by slight variations in the absorbance of different plastic cuvettes. 6. In Step 11c, students use the Interpolation Calculator to determine the concentration of their sample of unknown CuSO 4. Interpolate, in this case, is the literal definition of the term. If the absorbance of the unknown falls outside the range of the standard samples, the Interpolation Calculator will not work. Students can use the Interpolate option in the Analyze menu, which will also extrapolate. 7. We included a few questions in the Data Analysis section of the student version as a generic starting point. Please feel free to edit or replace these questions as best fits the needs of your experiment. 8. As a good way to become familiar with this experiment, you should plan to keep a set of sample data as well as develop an answer key. It is our experience that data can vary, based on many factors, and the sample data that we have collected in testing this experiment may not be representative of your students results. HAZARD ALERTS Copper (II) sulfate, pentahydrate: Skin and respiratory irritant; moderately toxic by ingestion and inhalation. Hazard code: C Somewhat hazardous. The hazard information reference is: Flinn Scientific, Inc., Chemical and Biological Catalog Reference Manual, P.O. Box 219, Batavia, IL 60510, (800) 452-1261, www.flinnsci.com. Spectroscopy with Vernier 2006 Vernier Software & Technology 1-5