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Molar Mass by Boiling Point Elevation
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Carmen Belk Professor Brian Reid CHEM-1412. 09 February 2021 Lab Report - Molar Mass by Boiling Point Elevation
PRE-LAB Questions 1. Define the term “colligative properties” and give examples. Colligative properties are the physical properties of a solution. Vapor pressure lower, boiling point higher, freezing point lower, and osmotic pressure. 2. What is molality?
3. Calculate the molality of a solution that contains 1 g of potassium chloride (KCl) in 175g water
4. How much will the boiling point of water change when 2 g of urea (60 g/mol) is
dissolved in 150 g of water?
5. A solution of 100 grams of brucine in 1 kg chloroform freezes at –64 °C. What is the molar mass of brucine?
lowering, boiling point elevation, freezing point lowering, and osmotic pressure. They depend on the amount of solute dissolved into a solvent, regardless of the type of solute. When a solute is dissolved into a solvent, it creates bonds between the solute and solvent that are harder to break compared to bonds between just the solvent molecules. This means more energy is needed to break the bonds then boil out the liquid solvent, which is why the boiling point goes up for a solution compared to pure solvent. This also means the freezing point will be lower for the solution than pure solvent because it’s harder to freeze a mix of chemicals than it is to freeze a pure chemical.
Procedure 1. First prepare a 90 °C water bath by heating 400 mL of water in a 600 ml beaker. 2. The mass of Urea (60 g/mol) necessary to make 50 mL of 0 molal solution in Ethanol (d = 0 g/ml) is 1. Measure out three Urea samples of the calculated mass. 3. Measure 50 mL of ethanol and place it into a clean and dry 8 x 1-inch test tube. Place a small capillary tube (about 3-4 inches long) in the ethanol, open end down. The test tube is then fitted with a two holed rubber stopper with thermometer (or temperature sensor) inserted so that the tip of the thermometer is about an inch below the surface of ethanol, and an 8 inch length of glass tubing. The test tube is then clamped and immersed in the hot water bath and heated gently. 4. Use this set up to determine the boiling point of pure ethanol. 5. Use the same ethanol and determine the elevated boiling point when 0, 1,
and 1 urea is added (measured in step 2). 6. Construct and record your data in a table form. 7. Construct a graph of T ; boiling point (y-axis) vs. m ; molality (x-axis). Show the equation of the line and calculate the slope. Make sure to properly label the axes and title the graph. 8. Get an unknown from your lab instructor. To a new batch of 50 mL ethanol, add a mass of the unknown equal to the mass of 0 of Urea (calculated in step 2). Use the above procedure to measure the boiling point elevation of the unknown/ethanol solution. Calculate the molar mass of the unknown. 9. Given the density of ethanol (0 g/cm 3 ), the mass of ethanol used may be found and hence the mass of unknown in 1 kg of solvent. From these data and the molality, the molecular weight of the unknown may be determined.
Results Include data tables, graphs, statistics, and calculations. Must show ALL work in calculations. Calculation for mass of Urea needed to make 50 mL of .5 molal solution:
Amount of urea (molar mass = 60 g/mol) required to make 0, 1 and 1 molal Urea solution in 30 mL of ethanol (density of ethanol = 0 g/mL):
Kb according to graph: 2.
Kb according to calculation: 2. Kb ethanol accepted value: 1. Kb Percent error: 106%
Change in temperature of unknown solution: 2 C
number was not used later on, it was just solved per the instructions and used as a practice problem. The data given to students is from Urea dissolved in 30 mL of Ethanol, so the calculations below the data tables reflect that. For the first part of the experiment, the amount of Urea required to make 0, 1 and 1. molal Urea solution in 30 mL of ethanol was calculated to be .7108g, 1, and 2, respectively. The density of ethanol was taken and multiplied with the milliliters of ethanol, then that number was divided by 1000 and multiplied by the respective molality. This was multiplied by the molar mass of Urea to get each answer. The boiling points of the three Urea concentrations plus the boiling point of the pure solvent came out to be 76, 77, 78, and 80 degrees Celsius. These values were put in excel and graphed. After plotting a trendline and finding the formula of the line, the Kb was found to be 2 (Kb equal to the m value in the formula y=mx+b). The values were also calculated by hand using the (change in)Tb=m*Kb formula. The result was a Kb of 2. The difference of. is probably because of rounding. The accepted value of Kb is 1 (Eastman & Rellefson, 307), but the value found from experimentation is 2. These two values have a percent error of 106%, so the Kb found through experimentation is about twice the amount it should be. This is most likely due to the measurements being off. The boiling point of pure ethanol measured is 76 Celsius, but the accepted boiling point is 78 Celsius (Eastman & Rellefson, 307). This alone is enough to throw the calculations off. This could be caused by a faulty visual temperature reading or a faulty thermometer, or measuring the BP at the wrong time, like before it was really “boiling”. The last part of the lab involved using both the measured and actual Kb value to calculate the molar mass of an unknown solvent. The measured boiling point of ethanol is 76 Celsius
and the boiling point of the ethanol plus unknown is 78 Celsius, which means the change in Tb is 2 degrees. The molar mass of the unknown calculated with the experimental Kb value is 76 g/mol. The molar mass calculated with the actual Kb value is 37 g/mol. This discrepancy is because of the differences in Kb value.
Conclusion This experiment had bad measurements that provided a Kb value for ethanol that was far greater than what was to be expected. This interfered with the results of the unknown solute’s molar mass.
Works Cited
Eastman. E. and Rollefson, G. Physical Chemistry 1947 ed. McGraw-Hill p. 307
- Multiple Choice
Course : General Chemistry II (CHEM 1412 )
University : collin college.
- Discover more from: General Chemistry II CHEM 1412 Collin College 64 Documents Go to course
- More from: General Chemistry II CHEM 1412 Collin College 64 Documents Go to course
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The boiling point elevation constant of carbon tetrachloride is 4 ºC/m. The density of carbon tetrachloride is 1 g/cm 3. The normal boiling point of carbon tetrachloride is 76ºC. a. Calculate the boiling point of a solution made by mixing 25 grams of solid iodine with 250 ml carbon tetrachloride. (Show all work) b.
1 Boiling Point Elevation Lab Report Purpose: The purpose of the Boiling Point Elevation Lab is to find out how much the boiling point is affected when solute is added to the solvent. Background Information: The boiling point elevation is a colligative property , which means that it is dependent on the presence of dissolved particles and their ...
ions in solution increases (doubling, tripling, and so on). The boiling point elevation changes accordingly. (Ex. 1 mol NaCl has 2 mol ions, [1 mol of Na+ and 1 mol of Cl-]) In this investigation, the boiling points of water, a sugar-water solution, and a salt-water solution will be determined. PROCEDURE 1. Turn on the hot plate. 2.
In this experiment, you will study boiling point elevation using sodium chloride, NaCl. You may recall from your notes that boiling point elevation is described by the equation: Tb iKbcm where ∆Tb is the boiling point elevation, i is the van’t Hoff factor, Kb is the boiling point constant of the solvent, and cm is the molality of the ...
Carmen Belk Professor Brian Reid CHEM-1412. 09 February 2021 Lab Report - Molar Mass by Boiling Point Elevation. PRE-LAB Questions 1. Define the term “colligative properties” and give examples. Colligative properties are the physical properties of a solution. Vapor pressure lower, boiling point higher, freezing point lower, and osmotic ...
Oct 12, 2022 · View CHEM1212K Lab Report.docx from CHEM 1212K at Georgia State University. Boiling point elevation Lab April 8, 2022 CHEM 1212K Khaled Nasrallah (002-606-945) Instructor Aikohi A. Abstract: Boiling
Sep 24, 2022 · View Boiling point of elevation_Lab report 1.pdf from MU 2 at Sunway University. DEPARTMENT OF CHEMICAL ENGINEERING SCHOOL OF ENGINEERING AND TECHNOLOGY ORGANIC CHEMISTRY CHE 1034 EXPERIMENT: BOILING
Chemistry Investigatory Project: Elevation in Boiling Point - Free download as Word Doc (.doc / .docx), PDF File (.pdf), Text File (.txt) or read online for free.
with your lab report. a. Plot temperature on the y-axis and time on the x-axis. b. The 5 consecutive readings indicate the freezing point for the solution Part-B Boiling Point Elevation: 1. Pour 1000 mL of water into a small cooking pot. 2. Turn on you stove. 3. When the water is boiling, measure the temperature of the boiling water by hanging the
The boiling point of a solution is always higher than that of the pure solvent. The dependence of the temperature difference (elevated boiling point) on the concentration of the solute can be determined using a suitable apparatus. Equipment Appar. for elev. of boiling point 36820.00 1 Heat. mantle f. round bott.fl. 250 ml 47550.93 1