Seperation lab: Will rate question

Separation lab - will choose best answer

Seperation lab: will choose best answer

Separation of a Mixture Laboratory

In this experiment we will separate the different components of a mixture made up of sand (SiO2) and sodium chloride (NaCl, commonly known as salt). Both of these compounds are solid white crystals, so it is difficult to tell them apart with the naked eye. However, each component exhibits different physical properties that can be used to separate one from the other. There are several physical separation techniques that can be used to determine the percent composition of the original mixture.

Materials & Apparatus:

Sand/salt mixture provided in your Lab Kit

2 - Erlenmeyer Flasks

Scale

Water

Graduated Cylinder

Background:

It is important to know how to separate mixtures because many reactions carried out in the laboratory produce mixtures of different compounds. It is often necessary to separate the components of these mixtures, which can be done using several techniques. We will explore a few of these techniques: sublimation, filtration, evaporation and decantation.

Sublimation is the process of a substance passing from the solid to the gaseous state without first passing through the liquid state. Not all substances possess this characteristic. In fact, most substances to NOT sublime under normal conditions, but must be placed under low pressure and low temperature. Ammonium chloride (NH4Cl) and iodine (I2) are both substances that do sublime under normal conditions.

Filtration is the process used to separate the components of a mixture of solid substances that differ in solubility in a certain solvent. You can separate a mixture of solid substances by adding a liquid to the original mixture in which only some of the components of the mixture will dissolve. The resulting mixture, which contains both the dissolved and undissolved substances, is then poured through a filter paper--a porous paper that allows liquids to pass through while retaining any solids. The liquid that has passed through the filter paper is called the filtrate; the solid on the paper is the residue.

Evaporation can also be used to separate the solvent from the solution. A solution can be slowly heated in an Erlenmeyer flask, and the solute will remain after the solvent has evaporated.

Decantation is the process of separating a liquid from a solid (sediment) by gently pouring the liquid from the solid so as not to disturb the solid.

For this experiment, a practical plan is as follows: First combine the solid mixture of the two compounds, sodium chloride (NaCl) and sand (SiO2), with water. This will dissolve the sodium chloride. The sand will not dissolve into the water. We will "filter" the entire mixture, which allows the water in which the sodium chloride is dissolved to pass through, but not the sand. We will now have separated the sodium chloride and the sand. Then, we must evaporate off the water so that we weigh only the two original solids and not the water we added.

Procedure:

(NOTE: Do NOT dispose of any part of your lab until you are 100% positive you do not need it again. It is good practice to keep all parts of your lab until you are finished.)

Record the letter (A, B, C, or D) of your mixture (on the bag contents label) on the line above Data Table 1 below.

Obtain an Erlenmeyer flask [label it 1] and weigh and record the mass.

Add the entire contents of your unknown mixture bag to the flask and weigh and record the mass of the Erlenmeyer flask and the mixture.

Add 10 mL of water (preferably distilled) to the solid in the Erlenmeyer flask [Erlenmeyer flask 1] and stir gently for 5 minutes.

Weigh a new clean, dry Erlenmeyer flask [Erlenmeyer flask 2].

Decant the liquid from Erlenmeyer flask 1 into Erlenmeyer flask 2. This may work better if you place a utensil against the lip of the pouring flask to encourage a slow steady stream of liquid into the second flask.

Add another 10 mL of water to the solid in Erlenmeyer flask 1, stir for 1-2 minutes, and decant this liquid into the Erlenmeyer flask 2 as before.

Repeat with still another 10 mL of water. This process extracts (dissolves) the soluble sodium chloride from the insoluble sand.

Allow the two flasks to dry. Let them dry until the sand appears dry and freely moves when you shake the Erlenmeyer flask a little and the sodium chloride looks dry.

To speed up the process, you can heat the flasks slowly over a burner set on low on your stove top or in the oven (set at 125-200˚F). I would suggest heating it on top of another pan (NOT nonstick coated) Use a low setting and watch closely as you don’t want it to boil over.

Allow the Erlenmeyer flasks to cool to room temperature (if they were heated) and weigh the Erlenmeyer flasks and their contents separately. Record their masses in the appropriate sections of the table.

To ensure that there is no water remaining, heat for another 5-10 minutes oven or 1-2 minutes on the stove. Allow to cool to room temperature and reweigh the Erlenmeyer flask. If it is within 0.3 g of your initial weighing you can stop. If the second weighing is not within 0.3 g of your initial weighing, reheat again, cool, and reweigh. The difference between this mass and the mass of the empty Erlenmeyer flask is the mass of NaCl.

Unknown Mixture Label (A, B, C, or D) ___________

Data Table 1

Measure or calculate and record the following (in grams):
mass of the empty Erlenmeyer flask 1:
mass of the Erlenmeyer flask 1 plus the mixture sample:
mass of the mixture sample:
mass of the Erlenmeyer flask 1 and the remaining contents after drying of sand:
mass of Erlenmeyer flask 1 and dry sand (2nd weighing)
Subtract (a) from (e) to obtain the mass of sand in the sample:
Measure or calculate and record the following (in grams):
mass of an empty Erlenmeyer flask 2:
mass of Erlenmeyer flask 2 and dry NaCl (1st weighing)
mass of Erlenmeyer flask 2 and dry NaCl (2nd weighing)
mass of Erlenmeyer flask 2 and dry NaCl (3rd weighing) if necessary
measured mass of dry NaCl:

Assignment Questions (all work must be shown for all calculations):

Using the results of your lab, complete all the questions below.

Upload one picture that is representative of your experiment with this report to the appropriate D2L Brightspace Assignments folder.

Complete Data Table 1 located in the Procedure. Make sure to include all your work for all the calculations performed.

The amount of sodium chloride in the original mixture may also be determined indirectly by subtracting the SiO2 mass from the initial sample mass. Calculate the expected mass of NaCl using this method.

Calculate the percent difference of NaCl (Note: This is not % Error, but it is a similar calculation. This is an error calculation that checks precision between the results of the two methods from the following equation: (Note: the unit for this calculation is “% difference”)

% difference=measured mass-mass by subtractionmass by subtraction x 100

What is the mass percent of each component in your mixture: SiO2, and NaCl? (Note: the units for this calculation are “% SiO2” and “% NaCl”)

mass percent=mass of componenttotal mass of sample x 100

Error Analysis: Was your % difference from Assignment Question 4 within 10%? Why or why not? Did your two mass percentages in Assignment Question 5 add up to 100%? Why or why not? What were your biggest sources of error in this experiment? What would you do differently if you were to repeat this experiment? Explain.

What type of properties (physical or chemical) are we using to separate the mixture in this laboratory. Explain your answer.

A mixture is found to contain 0.69 g SiO2, 1.05 g of cellulose, and 2.17 g of calcium carbonate. What is the mass percentage of SiO2 in this mixture?

Assume you have a mixture of NH4Cl, sand, and salt and access to a regular chemistry laboratory. How would you separate the three?Write out what your procedure would be in numbered steps. Please research the answer to this question and properly cite your source. It is alright to research using the internet. However, Wikipedia, Yahoo Answers, Ask.com, and other non-scientific sources cannot be used.

Introduction:

This week you will be learning another important technique in the organic chemistry laboratory – distillation. Distillation uses the difference in boiling point of two miscible liquids and thus separates compounds by exploiting different volatilities. While often used in the chemical laboratory, the process itself is a physical separation that uses phase changes (gas / liquid) to effect either complete or partial separation. In the simplest form distillation consists of 2 phase changes, evaporation followed by one condensation step (simple distillation), whereas fractional distillation repeats the process of evaporation followed by condensation inside a distillation column. Besides the physical separation, distillation also provides you with a measure of purity as you will be able to constantly monitor the boiling point of the distillate and compare it to literature values. To corroborate your results of this week’s experiment, you will additionally perform gas chromatography of the distillates that you obtain. Gas chromatography allows for the analytical separation of compounds based on their boiling point and will serve in your experiment as a basis for determining the purity of the distillate. You will be given a mixture of 2 alcohols and will perform either a simple or a fractional distillation on it. You will then analyze your distillates using gas chromatography, determine the percent composition and thus the success of your distillation.

Questions for the experiment and the analysis:

1) Using the provided GC sample runs including integrations of each of the alcohol mixtures BEFORE the distillation, determine the percent of each of the alcohols in the sample

2) Obtain and tabulate the results of the other five procedures carried by the class

3) For all six procedures, compare the boiling ranges throughout the distillation, as well as the percent composition of the first and last collected fraction

4) Using this data, determine which distillations were successful in separating the two alcohols and which ones were unsuccessful. Make sure to compare this with the theory of distillation and the performance you should expect for simple vs fractional distillation

5) Based on those results, what factor seemingly determines whether a good separation is possible through distillation?

Lab Results:

Impure Methanol:Propanol

Peak 1: Retention Time (min)= 1.290, Area= 19.56, %Area= 7.25

Peak 2: Retention Time (min)= 2.140, Area= 250.19, %Area=92.75

Impure Methanol:Ethanol

Peak 1: Retention Time (min)= 1.265, Area= -4.83, %Area= 14.00

Peak 2: Retention Time (min)= 1.405, Area= -29.67, %Area= 86.00

Impure Methanol:Butanol

Peak 1: Retention Time (min)= 1.305, Area= 30.79, %Area= 3.41

Peak 2: Retention Time (min)= 3.690, Area= 872.07, %Area= 96.59

5 Procedures Carried by the Class Results:

Student 1:

Methanol:Ethanol- first test tube (simple distillation)

Peak 1: Retention Time (min)= 0.860, Area= 0.89, %Area= 4.42

Peak 2: Retention Time (min)= 1.035, Area= 16.92, %Area= 84.16

Peak 3: Retention Time (min)= 1.110, Area= 2.29, %Area= 11.41

Methanol:Ethanol- last test tube (simple distillation)

Peak 1: Retention Time (min)= 1.195, Area= 198.76, %Area= 100.00

Student 2:

Methanol:Ethanol- first test tube (simple distillation)

Peak 1: Retention Time (min)= 1.755, Area= 12.87, %Area= 100.00

Methanol:Ethanol- last test tube (simple distillation)

Peak 1: Retention Time (min)= 1.615, Area= 44.11, %Area= 100.00

Student 3:

Methanol:Ethanol- first test tube (fractional distillation)

Peak 1: Retention Time (min)= 1.555, Area= 11.11, %Area= 98.84

Peak 2: Retention Time (min)= 1.690, Area= 0.13, %Area= 1.16

Methanol:Ethanol- last test tube (fractional distillation)

Peak 1: Retention Time (min)= 1.496, Area= -0.19, %Area= -1.95

Peak 2: Retention Time (min)= 1.585, Area= 10.07, %Area= 101.95

Student 4:

Methanol:Ethanol- first test tube (fractional distillation)

Peak 1: Retention Time (min)= 1.465, Area= 67.70, %Area= 100.00

Methanol:Ethanol- last test tube (fractional distillation)

Peak 1: Retention Time (min)= 1.710, Area= 196.05, %Area= 100.00

Student 5:

Methanol:Propanol- first test tube (simple distillation)

Peak 1: Retention Time (min)= 1.840, Area= 193.42, %Area= 93.47

Peak 2: Retention Time (min)= 2.425, Area= 13.51, %Area= 6.53

Methanol:Propanol- last test tube (simple distillation)

Peak 1: Retention Time (min)= 2.520, Area= 830.06, %Area= 100.00

Student 6: (My Experiment)

Methanol:Propanol- first test tube (fractional distillation)

Peak 1: Retention Time (min)= 1.640, Area= 105.78, %Area= 94.71

Peak 2: Retention Time (min)= 2.205, Area= 5.90, %Area= 5.29

Methanol:Propanol- last test tube (fractional distillation)

Peak 1: Retention Time (min)= 2.410, Area= 790.25, %Area= 100.00

Student 7:

Methanol:Propanol- first test tube (fractional distillation)

Peak 1: Retention Time (min)= 1.685, Area= 42.94, %Area= 100.00

Methanol:Propanol- last test tube (fractional distillation)

(no peak)

Student 8:

Methanol:Butanol- first test tube (simple distillation)

(no peak)

Methanol:Butanol- last test tube (simple distillation)

(no peak)

Student 9:

Methanol:Butanol- first test tube (simple distillation)

Peak 1: Retention Time (min)= 1.090, Area= 272.21, %Area= 84.34

Peak 2: Retention Time (min)= 2.420, Area= 50.53, %Area= 15.66

Methanol:Butanol- last test tube (simple distillation)

Peak 1: Retention Time (min)= 3.210, Area= 1421.66, %Area= 100.00

Student 10:

Methanol:Butanol- first test tube (fractional distillation)

Peak 1: Retention Time (min)= 1.090, Area= 1.92, %Area= 0.20

Peak 2: Retention Time (min)= 2.070, Area= 2.23, %Area= 0.24

Peak 3: Retention Time (min)= 3.010, Area= 932.02, %Area= 99.56

Methanol:Butanol- last test tube (fractional distillation)

Peak 1: Retention Time (min)= 0.906, Area= 0.25, %Area= 0.13

Peak 2: Retention Time (min)= 1.040, Area= 144.64, %Area= 76.40

Peak 3: Retention Time (min)= 2.435, Area= 44.44, %Area= 23.47

INTRODUCTION

Many transition metal cations can have more than one possible charge (Worksheet 1). Differently charged species of the same element can have different chemical and physical properties. Knowing the charge can allow separation of the different ions based on their properties. For example, Cu²⁺ is blue and stable in solution, while Cu⁺ is colorless and reacts with oxygen. Hemoglobin contains iron as Fe²⁺, but it is inactive at binding oxygen when the iron gets oxidized to Fe³⁺. There are many similar situations in which it is important to always properly indicate charges of ions.

This laboratory experiment uses the difference in chemical properties of Fe²⁺, iron(II), and Fe³⁺, iron(III), to quantify the amount of each present in a solution of unknown concentrations of each. You will first determine the amount of iron(II) in your sample by titrating with a reagent that does not react with iron(III). You will then titrate a second sample after converting all the iron(III) to iron(II) in order to determine the total iron present. The percent composition of Fe²⁺ in the unknown mixture will be calculated.

BACKGROUND

The concentrations of both iron(II) and iron(III) ions in a solution can be determined by titration with potassium permanganate. The reaction is an oxidation-reduction reaction, or redox, for short. A brief introduction to oxidation-reduction reactions is given in the background of the “Acids and Bases” experiment. The permanganate ion effectively oxidizes iron(II) to iron(III) in an acidic solution while being reduced to manganese(II) ion. The balanced net ionic reaction is:

5 Fe²⁺(aq) + MnO4^–(aq) + 8 H⁺(aq) → 5 Fe³⁺(aq) + Mn²⁺(aq) + 4 H₂O(l)

Iron(III) is not oxidized by the permanganate ion, and thus does not react. Thus in order to determine the concentration of iron(III) ions, they must first be reduced to iron(II) ions. Zinc metal is used as the reducing agent, also under acidic conditions.

Zn(s) + 2 Fe³⁺(aq) → 2 Fe²⁺(aq) + Zn²⁺(aq) (reduction of the Fe3+)

Zn(s) + 2 H⁺(aq) → Zn²⁺(aq) + H₂(g) (a side reaction that oxidizes excess Zn)

The Zn2+ formed does not interfere with the subsequent titration because Zn2+ is not oxidized by permanganate. Notice that converting all the iron(III) to iron(II) means that the total iron concentration ([Fe2+] + [Fe3+]) is titrated, not just the iron(II) originally present.

Techniques

This is a lab will utilize several of the techniques introduced in the experiment “Laboratory Techniques and Measurements,” the procedures for which are given in Appendix B. Poor laboratory technique and misuse of the glassware will result in poor data results, which will affect the grade you receive on the laboratory report. In order to use your time efficiently in lab, review how to properly:

rinse glassware prepare a standard solution use a volumetric pipette

weigh by difference set up and use a burette use a graduated cylinder

heat samples on a hot plate

Analysis of Iron by Oxidation-Reduction Titration

This lab uses the common quantitative technique of titration. The only difference between the titration you will be doing in this lab and that done in the Molar Mass of a Known Acid lab is the type of reaction used: this lab will use a redox reaction in place of the acid-base reaction performed in the previous experiment.

In order to determine the concentrations of iron(II) and iron(III) ions in a solution containing both ions, two portions of the same sample must be titrated separately. This first titration will determine only the iron(II) concentration. A second sample will be treated with zinc metal in order to reduce the iron(III) to iron(II). The resulting solution will be titrated with potassium permanganate. The result of this titration will give the total iron concentration in the sample. The difference between the first and second titration is the equal to the iron(III) concentration.

In this titration, potassium permanganate serves as its own indicator. The intense purple color of the permanganate solution becomes colorless when the permanganate is reduced to manganese(II). Thus, as iron(II) is oxidized with the addition of the permanganate solution from the burette it will impart a purple color that will fade. However, once there is no iron(II) left in solution a faint purple color will remain, marking the endpoint of the titration. This color can be slightly altered by the presence of iron(III), which is yellow in solution. Remember that iron(III) is generated by the reaction between iron(II) with permanganate, increasing the yellow appearance of the solution and which can interfere with the detection of the endpoint. Phosphoric acid is added to help minimize this effect.

pre lab questions: