1. Do First
How is a homogenous mixture different from a heterogeneous mixture?
Another name for a homogenous mixture is a ______________.

2. Mixtures and Solutions

3. Heterogeneous Mixtures
Recall that a mixture is a combination of two or more pure substances in which each pure substance retains its individual chemical properties.
Heterogeneous mixtures do not blend smoothly throughout, and the individual substances remain distinct.

4. Heterogeneous Mixtures
There are two types of heterogeneous mixtures: suspensions and colloids

5. Suspensions
A suspension is a mixture containing particles that settle out if left undisturbed.
Some suspensions will separate into two distinct layers if left undisturbed for awhile

6. Colloids
A colloid is a heterogeneous mixture of intermediate sized particles that will NOT separate if left undisturbed.
Example: HOMOGENIZED MILK! – Even though it doesn’t look like it, homogenized milk is a HETEROGENEOUS mixture, and specifically, a colloid. The components of homogenized milk CAN’T be separated by settling or by filtration.
EBPgo5Q (3 min video)

7. Homogeneous Mixture
Homogenous mixtures (aka: Solutions) contain two or more substances called the solute and the solvent.
The solute is the substance that dissolves; the solvent is the dissolving medium.
When looking at a solution it is not possible to distinguish the solute from the solvent.

8. Types of Solutions
A solution might exist as a gas, a liquid, or a solid, depending on the state of its solvent.
However, most solutions are liquids

9. Forming Solutions
Some combinations of substances readily form solutions, and others do not.
Soluble- a substance that dissolves in a solvent (ex: sugar is soluble in water)
Insoluble- substance that does not dissolve in a solvent (ex: sand is insoluble in water) E

10. Forming Solutions
Miscible- two liquids that are soluble in each other (ex: water and vinegar)
Immiscible- two liquids that can be mixed together but separate shortly after (ex: water and oil)

11. Heat of Solution
Heat of Solution- the overall energy change that occurs during the solution formation process
Think back- some solutions release energy as they form, whereas others absorb energy during formation.
Examples from SPA:
Ammonium chloride = absorbs energy
Calcium chloride = releases energy

12. Factors that Affect Solvation
Solvation occurs only when solute and solvent particles come in contact with each other.
There are three common ways to increase the collisions among solute and solvent particles and thus increase the rate at which the solute dissolves.

13. 1) Agitation
Agitation (stirring or shaking) of the mixture moves dissolved solute particles around quickly, increasing collisions among particles of solute and solvent

14. 2) Surface Area
Breaking the solute into small pieces increase its surface area.
A greater surface area allows more collisions to occur.
This is why a teaspoon of sugar dissolves more quickly than an equal amount of sugar in a cube form.

15. 3) Temperature The rate of solvation is affected by temperature.
Increased temperature = increased particle collisions = faster dissolving!
For example, sugar dissolves more quickly in hot tea than it does in iced tea.

16. Unsaturated Solutions
Unsaturated solution is one that contains less dissolved solute for a given temperature and pressure than a saturated solution.
So more solute can be dissolved in an unsaturated solution

17. Saturated Solutions
Saturated Solutions contain the maximum amount of dissolved solute for a given amount of solvent at a specific temperature and pressure.

18. Temperature and supersaturated solutions
Solubility is affected by raising the temperature of the solvent because the kinetic energy of its particle is increased, resulting in more frequent collisions

19. Solubility Curves
What happens to the solubility of substance B as temperature increases?
It INCREASES!
increased temperature causes higher collisions among particles, which increases solubility
Solute is a SOLID
g solute

20. Solubility Curves
What happens to the solubility of substance C as temperature increases?
It DECREASES!
So, if increased collisions causes the solute to become LESS soluble, this solute is a GAS, because it ESCAPES the liquid
g solute

21. Solubility Curves
At what temperature is the solubility of substance C and substance B the same?
At 20ºC
g solute

22. Solubility Curves
At 10ºC, 20 grams of substance B is dissolved in 100g of water. Is this solution saturated, unsaturated, or supersaturated?
Unsaturated!
The data point falls BELOW substance B’s solubility curve
g solute

23. Solubility Curves
How many grams of substance B can be dissolved in 200g of water at 30ºC?
60 grams!

24. DYL 1. What are the two types of heterogeneous solutions?
2. How are unsaturated solutions different from saturated solutions?