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Thursday, March 14, 2019

Beer’s Law Lab Essay

ObjectiveThe usance of this lab is to demonstrate that thither is a linear relationship amongst the number of molecules that can absorb light present in a dissolvent and the amount of light absorbed by a re resolving. This lab should prove that Beers law and the equating A=a x b x c, is a linear relationship. ProcedureThe only deviations in the lab procedure was that the strain re ancestor was made before r individu every(prenominal)ying to the lab with 0.570 g of KMnO4 in 0.500 L. The reduce rootages and the Spec 20 were use as directed in the lab manual. The same cuvette was used apiece time to eliminate error. Cuvettes ar all made differently and save a difference in how they measure. If a new cuvette was used for each one time, the data would be slightly off due to the possibility of each cuvette having different characteristics which affect the measurements in the Spec 20. Data CalculationsTo reign the one thousand of the simple eye root word* crease Molarity i s moles/ Liters so in the equation below the eldest half(a) is decision the number of moles of KMnO4 and the second half is dividing the moles by the liters of the stem. Grams of KMnO4 x (1 mole / submarine mass (158.04g)) / Liters of stock stem = molar niggardness of Stock Solution 0.570g KMnO4 x (1 mole / 158.04g) / 0.500 Liters = 0.00721 MTo find the molarity of base 1* tag To find the molarity of the prototypical solution, use the molarity found for the stock solution. Since 5.00 mL of the stock solution was used to advance solution 1, multiply the molarity of the stock solution by 5.00 mL to get the moles of solution 1. Once the moles of solution 1 have been found, divide that by the liters of water that were added to solution 1. The 0. c00 L comes from the 100 mL volumetric flask the solution was made in. mL of stock solution x (moles of stock solution / liter) / resume liters of solution 1 (volumetric flask) = M of solution 1 5.00 mL stock solution x (0.00721 moles / 1000mL ) / 0.10000 L = 0.000361 MTo find the molarity of solution 2*Note To find the molarity of solution 2, follow the same go for solution 1 and use 2.00 mL instead of 5.00 mL. The same steps are used due to solution 2 being thin out from the stock solution. mL of stock solution x (moles of stock solution / liter) / total Liters in solution 2(Volumetric flask) = M of solution 2 2.00 mL stock solution x (0.00721 moles / 1000 mL) / 0.10000L = 0.000144 MTo find the molarity of solution 3*Note To find the molarity of the third solution the same procedure is followed as finding the molarity of the first solution, except you will be using the molarity of the first solution since solution three was made using the first solution. mL of solution 1 x ( moles of solution 1 / 1 L) /total liters in solution 3( volumetric flask) =M of solution 3 50.00mL solution 1 x (0.00721 moles / 1000 mL) / 0.10000 = 0.000181 MTo find the molarity of solution 4*Note to find the molarity of the fourth solution follow the steps for finding the molarity of the third solution except use the molarity of solution 2 since solution 4 was made with 50.00 ml of solution 2. mL of solution 2 x ( moles of solution 2 / 1 L) /total liters in solution 4 (volumetric flask) = M of solution 4 50.00 mL solution 2 x (0.000144 moles / 1000 mL ) / 0.10000 L = 0.000072 M Table 1. The molar concentration, absorbance esteems, percent transmittance, average absorbance and transmittance values are shown in the table below. Solution Molar ConcentrationTrialAbsorbance% TAverage AbsorbanceAverage % T10.00003605 M10.82115.10.81415.320.81115.430.81115.520.0001442 M10.32447.40.32547.320.32647.230.32447.430.0001805 M10.38840.90.40239.620.40639.230.41338.740.000072 M10.208620.20961.820.20861.930.21161.5Figure 1. The figure below shows the absorbance vs. the molar concentration of KMnO4.To find the extinction coefficientThe extinction coefficient is found by A/bc = a. A/c is the slope of the line from figure 1. 3 139.9/(mol/L) x 1.00 cm =aa= 3139.9 L * mol-1 * cm-1Discussion and ConclusionIn this lab the equation of Beers law was proven to have a linearrelationship. The purpose was to show that molar concentration and absorbance are proportional to each other. This was proved through diluting solutions and using a stipulation 20 to determine the absorbance values. The solutions were diluted to give different molar concentrations and each concentration was placed in the spec 20. After creating a scatter fleck it was obvious to see as the molar concentration increases the absorbance increases. This is because there are to a greater extent particles present at higher molar concentrations and therefore to a greater extent light will be absorbed by the particles present.There were legion(predicate) possible sources of error in this experiment. First, if one solution was diluted haywirely all of the following solutions were diluted incorrectly since they came from the first incorrectly diluted solution. One of the solutions in the experiment could have been diluted wrong, causing all of the solutions to have incorrect dilutions and the calculated values, especially the extinction coefficient, to have incorrect values. Another source of error is that when diluting the solutions not all of the solution transfers were through exactly due to some of the solution being transferred was often go away in the pipet.The drops left in the pipet after the transfer could make a difference in the actual molar concentration of each solution. The coda source of error occurs from not placing the cuvette in the spec 20 at the same orientation. Although the same cuvette was used each trial, some disuse may have resulted in the cuvette not being placed in the same orientation each time. Because the sides of the cuvette may be different the readings from the spec 20 may be off. The conclusion of the lab is that Beers justness equation is indeed linear, and the absorbance is proportional to the molar concentration. If this lab were preformed again the stock solution should be placed in the spec 20 railroad car and the absorbance should also be found. The measurements from the stock solution could have provided even more evidence to the conclusion. Overall though the lab was very successful in determining the relationship of the equation in Beers Law.Questions2. A large cuvette diameter will produce a higher absorbance value. The diameter of the cuvette is the rail distance, or b, in the equation A = a x b x c. The larger the path length, the higher the absorbance will be becauseyou are multiplying a and c by a higher value. Also there is more particles present in a larger path length to absorb light. 3. To find the extinction coefficient the equation A/cb= a is used. A larger cuvette diameter, or path length, would result in a smaller extinction coefficient. The larger the number is on the bottom the smaller the value of the extinction coefficient. 4. Solution 4 probably has the greatest error because it was the last solution to be diluted. Any errors made in diluting a solution will carry through to the last solution diluted because the first solutions are used to dilute the latter solutions. For example if solution 1 is incorrectly diluted then solution 3 will be incorrectly diluted and then solution 4 will be incorrectly diluted.

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