Saturated and Unsaturated Solutions

Learning Objectives

  • Define saturated solution.
  • Define unsaturated solution.
  • Define solution equilibrium.

How do you make sure a compound is pure?

Learning Objectives Know the definition and the notion for independent events. Use the rules for addition, multiplication, and complementation to solve for probabilities of particular events in finite sample spaces. What’s in a Word? The words dependent and independent are used by students and teachers on a daily basis. In fact, they are probably used quite frequently. You may tell your parent or guardian that you are independent enough to go to the movies on your own with your friends. You could say that when you bake a cake or make a cup of hot chocolate, the taste of these are dependent on what ingredients you use. In the English language, the term dependent means to be unable to do without, whereas independent means to be free from any outside influence. What about in mathematics? What do the terms dependent and independent actually mean? This lesson will explore the mathematics of independence and dependence. What are Venn Diagrams and Why are They Used? In probability, a Venn diagram is a graphic organizer that shows a visual representation for all possible outcomes of an experiment and the events of the experiment in ovals. Normally, in probability, the Venn diagram will be a box with overlapping ovals inside. Look at the diagram below: The S represents all of the possible outcomes of an experiment. It is called the sample space. The ovals A and B represent the outcomes of the events that occur in the sample space. Let’s look at an example. Let’s say our sample space is the numbers from 1 to 10. Event A is randomly choosing one of the odd numbers from 1 to 10, and event B is randomly choosing one of the prime numbers from 1 to 10. Remember that a prime number is a number whose only factors are 1 and itself. Now let’s draw the Venn diagram to represent this example. We know that: S = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10}!\A = {1, 3, 5, 7, 9}!\B = {2, 3, 5, 7} Notice that 3 of the prime numbers are part of both sets and are, therefore, in the overlapping part of the Venn diagram. The numbers 4, 6, 8, and 10 are the numbers not part of A or B, but they are still members of the sample space. Now you try. Example 1 2 coins are tossed one after the other. Event A consists of the outcomes when tossing heads on the first toss. Event B consists of the outcomes when tossing heads on the second toss. Draw a Venn diagram to represent this example. Solution: We know that: S = {HH,HT, TH, TT}!\A = {HH,HT}!\B = {HH,TH} Notice that event A and event B share the Heads + Heads outcome and that the sample space contains Tails + Tails, which is neither in event A nor event B. Example 2 Event A represents randomly choosing a student from ABC High School who holds a part-time job. Event B represents randomly choosing a student from ABC High School who is on the honor roll. Draw a Venn diagram to represent this example. Solution: We know that: S = {students in ABC High School} A = {students holding a part-time job} B = {students on the honor roll} Notice that the overlapping oval for A and B represents the students who have a part-time job and are on the honor roll. The sample space, S, outside the ovals represents students neither holding a part-time job nor on the honor roll. In a Venn diagram, when events A and B occur, the symbol used is cap. Therefore, A cap B is the intersection of events A and B and can be used to find the probability of both events occurring. If, in a Venn diagram, either A or B occurs, the symbol is cup. This symbol would represent the union of events A and B, where the outcome would be in either A or B. Example 3 You are asked to roll a die. Event A is the event of rolling a 1, 2, or a 3. Event B is the event of rolling a 3, 4, or a 5. Draw a Venn diagram to represent this example. What is A cap B? What is A cup B? Solution: We know that: S = {1, 2, 3, 4, 5, 6}!\A = {1, 2, 3}!\B = {3, 4, 5} A cap B = {3}!\A cup B = {1, 2, 3, 4, 5} Independent Events In mathematics, the term independent means to have one event not dependent on the other. It is similar to the English definition. Suppose you are trying to convince your parent/guardian to let you go to the movies on your own. Your parent/guardian is thinking that if you go, you will not have time to finish your homework. For this reason, you have to convince him/her that you are independent enough to go to the movies and finish your homework. Therefore, you are trying to convince your parent/guardian that the 2 events, going to the movies and finishing your homework, are independent. This is similar to the mathematical definition. Say you were asked to pick a particular card from a deck of cards and roll a 6 on a die. It does not matter if you choose the card first and roll a 6 second, or vice versa. The probability of rolling the 6 would remain the same, as would the probability of choosing the card. Going back to our Venn diagrams, independent events are represented as those events that occur in both sets. If we look just at Example 2, event A is randomly choosing a student holding a part-time job, and event B is randomly choosing a student on the honor roll. These 2 events are independent of each other. In other words, whether you hold a part-time job is not dependent on your being on the honor roll, or vice versa. The outcome of one event is not dependent on the outcome of the second event. To calculate the probability, you would look at the overlapping part of the diagram. The region representing A and B is the probability of both events occurring. Let’s look at a specific example. In ABC High School, 30 percent of the students have a part-time job, and 25 percent of the students from the high school are on the honor roll. Event A represents randomly choosing a student holding a part-time job. Event B represents randomly choosing a student on the honor roll. What is the probability of both events occurring? Event A is randomly choosing a student holding a part-time job, and event B is randomly choosing a student on the honor roll. These 2 events are independent of each other. In other words, whether you hold a part-time job is not dependent on your being on the honor roll, or vice versa. The outcome of one event is not dependent on the outcome of the second event. To calculate the probability, you would look at the overlapping part of the Venn diagram. The region representing A and B is the probability of both events occurring. Let’s look at the probability calculation, which is done with the Multiplication Rule: P(A) &= 30% text{or} 0.30\P(B) &= 25% text{or} 0.25\ P(A text{and} B) &= P(A) times P(B)\P(A text{and} B) &= 0.30 times 0.25\P(A text{and} B) &= 0.075 In other words, 7.5% of the students of ABC high school are both on the honor roll and have a part-time job. In Example 1, 2 coins are tossed one after the other. Remember that event A consists of the outcomes when getting heads on the first toss, and event B consists of the outcomes when getting heads on the second toss. What would be the probability of tossing the coins and getting a head on both the first coin and the second coin? We know that the probability of getting a head on a coin toss is frac{1}{2}, or 50%. In other words, we have a 50% chance of getting a head on a toss of a fair coin and a 50% chance of getting a tail. P(A) &= 50% text{or} 0.50\P(B) &= 50% text{or} 0.50\\P(A text{and} B) &= P(A) times P(B)\P(A text{and} B) &= 0.50 times 0.50\P(A text{and} B) &= 0.25 Therefore, there is a 25% chance of getting 2 heads when tossing 2 fair coins. Example 4 2 cards are chosen from a deck of cards. The first card is replaced before choosing the second card. What is the probability that they both will be sevens? Solution: Let A = 1^{text{st}} seven chosen. Let B = 2^{text{nd}} seven chosen. A little note about a deck of cards A deck of cards consists of 52 cards. Each deck has 4 parts (suits) with 13 cards in them. Each suit has 3 face cards. & 4 text{suits} qquad 1 text{seven} text{per suit}\& searrow qquad swarrow\text{The total number of sevens in the deck} &= 4 times 1=4. Since the card was replaced, these events are independent: P(A) &= frac{4}{52}\\& qquad qquad text{Note: The total number of cards is}\P(B) &= frac{4}{52} swarrow text{52 after choosing the first card,}\& qquad qquad text{because the first card is replaced.}\\P(A text{and} B) &= frac{4}{52} times frac{4}{52} text{or} P(A cap B)=frac{4}{52} times frac{4}{52}\\P(A cap B) &= frac{16}{2704}\\P(A cap B) &= frac{1}{169} Example 5 The following table represents data collected from a grade 12 class in DEF High School. Plans after High School Gender University Community College Total Males 28 56 84 Females 43 37 80 Total 71 93 164 Suppose 1 student was chosen at random from the grade 12 class. (a) What is the probability that the student is female? (b) What is the probability that the student is going to university? Now suppose 2 people both randomly chose 1 student from the grade 12 class. Assume that it's possible for them to choose the same student. (c) What is the probability that the first person chooses a student who is female and the second person chooses a student who is going to university? Solution: text{Probabilities:} P(text{female}) &= frac{80}{164} swarrow fbox{164 text{total students}}\P(text{female}) &= frac{20}{41}\P(text{going to university}) &= frac{71}{164}\\P(text{female}) times P(text{going to university})&= frac{20}{41} times frac{71}{164}\&= frac{1420}{6724}\&= frac{355}{1681}\&= 0.211 Therefore, there is a 21.1% probability that the first person chooses a student who is female and the second person chooses a student who is going to university.

MSG compounds. User:Ragesoss/Wikimedia Commons.

When compounds are synthesized, they often have contaminating materials mixed in with them. The process of recrystallization can be used to remove these impurities. The crystals are dissolved in a hot solvent, forming a solution. When the solvent is cooled the compound is no longer as soluble and will precipitate out of solution, leaving other materials still dissolved.

Saturated and Unsaturated Solutions

Table salt (NaCl) readily dissolves in water. Suppose that you have a beaker of water to which you add some salt, stirring until it dissolves. So you add more and that dissolves. You keep adding more and more salt, eventually reaching a point that no more of the salt will dissolve no matter how long or how vigorously you stir it. Why? On the molecular level, we know that action of the water causes the individual ions to break apart from the salt crystal and enter the solution, where they remain hydrated by water molecules. What also happens is that some of the dissolved ions collide back again with the crystal and remain there. Recrystallization is the process of dissolved solute returning to the solid state. At some point the rate at which the solid salt is dissolving becomes equal to the rate at which the dissolved solute is recrystallizing. When that point is reached, the total amount of dissolved salt remains unchanged. Solution equilibrium is the physical state described by the opposing processes of dissolution and recrystallization occurring at the same rate. The solution equilibrium for the dissolving of sodium chloride can be represented by one of two equations.

text{NaCl}(s) rightleftarrows text{NaCl}(aq)

While this shows the change of state back and forth between solid and aqueous solution, the preferred equation also shows the dissociation that occurs as an ionic solid dissolves.

text{NaCl}(s) rightleftarrows text{Na}^+ (aq)+text{Cl}^-(aq)

When the solution equilibrium point is reached and no more solute will dissolve, the solution is said to be saturated. A saturated solution is a solution that contains the maximum amount of solute that is capable of being dissolved. At 20°C, the maximum amount of NaCl that will dissolve in 100. g of water is 36.0 g. If any more NaCl is added past that point, it will not dissolve because the solution is saturated. What if more water is added to the solution instead? Now more NaCl would be capable of dissolving in the additional solvent. An unsaturated solution is a solution that contains less than the maximum amount of solute that is capable of being dissolved. The figure below illustrates the above process and shows the distinction between unsaturated and saturated.

A solution that can no longer dissolve solute is saturated

Figure 1. When 30.0 g of NaCl is added to 100 ml of water, it all dissolves, forming an unsaturated solution. When 40.0 g is added, 36.0 g dissolves and 4.0 g remains undissolved, forming a saturated solution. From the CK-12 Foundation – Christopher Auyeung.

 

How can you tell if a solution is saturated or unsaturated? If more solute is added and it does not dissolve, then the original solution was saturated. If the added solute dissolves, then the original solution was unsaturated. A solution that has been allowed to reach equilibrium but which has extra undissolved solute at the bottom of the container must be saturated.

Summary

  • Saturated and unsaturated solutions are defined.
  • Solution equilibrium exists when the rate of dissolving equals the rate of recrystallization.

Practice

Watch the video at the link below and answer the following questions:

http://www.youtube.com/watch?v=gawS3sBHMQw

  1. What is the initial solution used?
  2. What is the heat source for evaporation?
  3. Why does the salt precipitate out of solution?

Review

  1. Why is the preferred equation for solution equilibrium of NaCl an equilibrium between solid NaCl and the ions.
  2. If I add water to a saturated sucrose solution, what will happen?
  3. If I heat a solution and remove water, I see crystals at the bottom of the container. What happened?

 Glossary

  • recrystallization: The process of dissolved solute returning to the solid state.
  • saturated solution: A solution that contains the maximum amount of solute that is capable of being dissolved.
  • solution equilibrium: The physical state described by the opposing processes of dissolution and recrystallization occurring at the same rate.
  • unsaturated solution: A solution that contains less than the maximum amount of solute that is capable of being dissolved.