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Purpose: The intent of this experiment is twofold. The first portion is designed to find the beginning of the colour of a carbonated drink. Be specific in your Purpose. which sodium carbonate are you mensurating? In the 2nd portion you will find how much a sample of grape sodium carbonate has been diluted. i. e. its concentration. Be specific. what is the sample ID for your unknown? Work as a squad. but each individual has their ain unknown and portion of the mark depends on you accuracy.

Procedure: The spectrum of a carbonated drink is obtained by mensurating the optical density of a sample of the drink at different wavelengths utilizing a spectrophotometer. This spectrum can so be related to the colour of the drink. In the 2nd portion. a standardization curve is prepared by mensurating the optical density of different standard concentrations of grape sodium carbonate at a individual wavelength. The optical density of the unknown solution can so be measured at the same wavelength and compared to the standardization curve to find its concentration.

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Any waste in this experiment can be poured down the drain.

Part I: The Visible Spectrum of the Soda Pop.

Sample Preparation: Pour about 15-20 milliliter of the drink into a beaker and splash to take the carbonation. Dilute it to about 50 % of its original concentration by pouring 10 milliliter into a calibrated cylinder and add an equal volume of H2O. Stir.

Measuring the Visible Spectrum of the Carbonated Beverage:

Be certain the spectrophotometer is turned on and warms up for at least 5 proceedingss. Put the wavelength boss to 600 nanometers.
Using the nothing adjust knob on the left side. put the needle to read 0 % transmission ( % T ) on the top of the metre. [ Nothing should be in the sample compartment ] . Be careful non to read the optical density graduated table. Fill one cuvette with distilled H2O. pass over it with a tissue or paper towel. and infix it in the sample compartment with the line confronting the forepart. Close the top. Use the 100 % T adjust boss on the right manus side to put the acerate leaf to 100 % T. Remove the cuvette and put it aside in a beaker without emptying it. Fill the other cuvette with your drink solution. Wipe it with a tissue or paper towel. and infix it in the sample compartment with the line confronting the forepart. Close the top. Read the optical density from the bottom graduated table on the metre. Record. in the Results subdivision of your notebook. the wavelength and optical density readings. The unit for wavelength is nanometer ( nanometer ) and there is no unit for the optical density measuring. Be certain to bespeak which sample you are utilizing. Remove the cuvette. shut the top and alter the wavelength to a scene which is 20 nm lower. Reset the 0 % T if it has changed ( with an empty sample compartment ) . Insert the cuvette of distilled H2O and reset the 100 % T.

Replace the H2O cuvette with your sample-containing cuvette and read the optical density once more entering your consequences. Repeat steps 7 through 9 until you have recorded all the wavelengths down to 360 nanometers. Part II. Determining the Concentration of Diluted Grape Soda.

Set the spectrophotometer wavelength to 500 nm the wavelength where all of these measurings will be made. Put the nothing and 100 % T on the Spectronic 20 as in Part I.
Measure the optical density of each of the four standard solutions of grape sodium carbonate provided. Record the optical density and the grape sodium carbonate solution concentration ( percent given on reagent bottle ) in your notebook. Measure and record the optical density of your unknown grape sodium carbonate solution. Be certain you record your sample ID Consequences:

Part I: Use Excel to do a graph of the spectrum of the drink solution. Your graph should be large plenty to make full one-half of a notebook page. All graphs should hold a rubric and appropriate labels. with units. on the axes. Include the diagram bespeaking the wavelength parts with the corresponding colourss of seeable visible radiation. An illustration is shown below. Use this diagram and graph to explicate the beginning of the colour of the solution in your decision.

Part II: Use Excel to do a graph of the optical density of the different criterion grape dad solutions versus their concentrations ( as per centums ) . See below for an illustration where four unfastened circles indicate the measurings of the four criterion concentrations. Use a TRENDLINE to pull the best line through all of your points. Put the beginning at zero and publish the equation for the line on your graph as in the Density Experiment.

Now you can utilize this standardization secret plan to find the concentration of your unknown grape sodium carbonate solution. The equation for your line should hold the signifier: Y = maxwell. where Yttrium is the optical density of your unknown and X is its concentration. the value you are mensurating. Find the concentration of your unknown by finding where its optical density crosses the standardization line you’ve merely put on your graph. Use the expression: Ten = Y/m. Note in the illustration. the pupil created a 5th point–the 1 with the square — for the terra incognita. which read 0. 31. From m. which is 0. 0124. a value of concentration of 25. 0 % is calculated.

Decision:

In your decision explain the beginning of the colour of your solution and describe the concentration of your unknown solution. along with your unknown ID figure

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