Chapter 16 Lecture Notes
During this unit of study, we will cover three main areas. A lot of this information is NOT included in your text book, which is a shame. Therefore, the notes you take in class (see below) are very important. The three main areas are
- Reaction Energy: Why is energy released by some reactions, and why is energy required to make other reactions occur?
- Reaction Equilibrium: Why don’t all reactions covert 100% of the reactants to products? How can we describe and even change the ratio of products formed to reactants that remain?
- Reaction Rate: What are the factors that affect the rate of a chemical reaction?
I. Reaction Energy
a. The study of energy in chemical reactions is called thermodynamics, which literally means “changes in heat.”
b. The standard conditions for thermodynamics are
i. Standard temperature = 25 °C = 298 K
ii. Standard Pressure = 1 atm
iii. Notice that these are different than STP for gases (where ST=273 K and SP = 1 atm).
c. All chemical reactions either release or require (absorb) energy when they occur.
d. Heat energy is referred to in this course as enthalpy (H).
i. Enthalpy is the heat absorbed or released by a system at constant pressure.
ii. It is impossible to measure enthalpy directly. Only changes in enthalpy are used in this course. We only use “ΔH” in this course. ΔH = Hfinal - Hinitial
iii. Units of heat energy. We will use joules (J) or kilojoules (kJ).
iv. System, surroundings, and universe
1. The system is the chemical reaction under study.
2. The surroundings is every place in the universe except the system.
3. The universe is the system and the surroundings.
v. Exothermic reactions.
1. An exothermic reaction is a reaction in which heat is released by the system to the surroundings.
2. For an exothermic reaction, the sign of ΔH is negative.
3. When an reaction is exothermic (ΔH is negative), that is a favorable condition. Enthalpy is just one of the variables involved when predicting whether or not a reaction will occur, but reactions which release heat are more likely to occur than ones in which heat is required, all things being equal.
vi. Endothermic reactions
1. An endothermic reaction is a reaction in which heat is absorbed by the system from the surroundings.
2. For an endothermic reaction, the sign of ΔH is positive.
3. When an reaction is endothermic (ΔH is positive), that is an unfavorable condition. Enthalpy is just one of the variables involved when predicting whether or not a reaction will occur, but reactions which absorb heat are less likely to occur than ones in which heat is released, all things being equal.
vii. Qualitative example problems
Example
problem: Consider cooking a pot of
soup over a stove’s flame burner. Explain the transfer of heat using the terms
learned in class.
Answer: The stove’s gas is reacting with the air in an exothermic
reaction. The soup is heated, and that is an endothermic process. So, if you
consider the soup the system, this is an endothermic process. On the other
hand, if the burner is considered the system, then the reaction is considered
exothermic.
Example problem: When ice melts because you leave it out on the table, is this an endothermic or exothermic process?
Answer: As ice melts, it has to absorb heat. Therefore, if ice is defined as the system, then the melting of ice is endothermic.
Example problem: When water freezes after you put it in the freezer, is this an endothermic or exothermic process?
Answer: As water freezes, it must get rid of (release, give off) heat. Therefore, the freezing of water is exothermic.
viii. Quantitative example problems using enthalpy data
1. Enthalpy is impossible to measure.
2. However, the change in enthalpy, ΔH, is possible to measure through calorimetry.
3. We use ΔH°f, the standard enthalpy of formation, to determine the change in enthalpy when a substance is formed from its elements in their standard states.
4. Therefore, each element in its standard state is assigned a value of “0” for its ΔH°f.
5. All other reactions are computed by subtracting the sum of the reactants’ ΔH°f from the sum of the products’ ΔH°f.
Example problem #1: Consider the evaporation of water:
Find the standard change in enthalpy for this reaction, and state whether the reaction is exothermic or endothermic. Use the table of standard enthalpies of formation.
Example problem #2: Consider the condensation of water vapor:
Find the standard change in enthalpy for this reaction, and state whether the reaction is exothermic or endothermic. Use the table of standard enthalpies of formation.
Example problem #3: Burning natural gas in the lab is described by the following chemical equation.
Find the standard change in enthalpy for this reaction, and state whether the reaction is exothermic or endothermic. Use the table of standard enthalpies of formation.
Example problem #4: Consider the following chemical equation:
Find the standard change in enthalpy for this reaction, and state whether the reaction is exothermic or endothermic. Use the table of standard enthalpies of formation.
Example
problem #5: Consider the following
chemical equation for the photosynthesis of glucose:
Find the standard change in enthalpy for this reaction, and state whether the reaction is exothermic or endothermic. Use the table of standard enthalpies of formation.
e. Entropy
i. The randomness or disorder of a system is the entropy (S) of that system.
ii. Only changes in entropy are used in this course. We only use “ΔS” in this course.
iii. When an reaction has a positive ΔS, that is a favorable condition. Entropy is just one of the variables involved when predicting whether or not a reaction will occur, but reactions which increase entropy are more likely to occur than ones in which the entropy decreases, all things being equal.
iv. When an reaction has a negative ΔS, that is an unfavorable condition. Entropy is just one of the variables involved when predicting whether or not a reaction will occur, but reactions which decrease entropy are less likely to occur than ones in which the entropy increases, all things being equal.
v. Units of ΔS: J/(K●mol)
vi. Qualitative example problems
vii. Quantitative example problems
f. Gibbs free energy and Reaction spontaneity
i. The spontaneity of a chemical reaction is the possibility of the reaction occurring or not without the aid of outside energy.
ii. If a reaction occurs without a net input of energy, it is called “spontaneous.” This type of reaction actually releases (“gives off”) useful energy.
iii. If a reaction requires energy in order to occur, it is called “nonspontaneous.” This type of reaction “takes in” energy when it occurs.
iv. Depiction of spontaneity with a reaction energy diagram
v. Gibbs free energy is the energy that is “free” to do work. “Free” doesn’t mean “costs nothing,” it means “available,” as in “Are you free tonight at around 8:00?”
vi. It is impossible to measure directly. Only changes in Gibbs free energy are used in this course. We only use “ΔG” in this course.
vii. Units of Gibbs free energy: most often kJ/mol.
viii. Important formula: ΔG = ΔH – TΔS
1. This formula shows that ΔG depends on the enthalpy (ΔH) and the entropy (ΔS)
a. Remember, when ΔH is negative that is a favorable condition, whereas a positive ΔH is unfavorable.
b. Remember, when ΔS is positive that is a favorable condition, whereas a negative ΔS is unfavorable.
2. When the sign of ΔG for some reaction is negative, the reaction is spontaneous.
3. When the sign of ΔG for some reaction is positive, the reaction is nonspontaneous.
4.
Helpful table
summarizing favorability and spontaneity
|
END RESULT |
Sign of ΔH |
Sign of ΔS |
Overall Sign of ΔG |
|
Spontaneous |
- (favorable) |
+ (favorable) |
- |
|
Depends on T |
- (favorable) |
- (unfavorable) |
? |
|
Depends on T |
+ (unfavorable) |
+ (favorable) |
? |
|
Nonspontaneous |
+ (unfavorable) |
- (unfavorable) |
+ |
5. Helpful example that summarizes whether or not a temperature-dependent reaction is spontaneous
g. Example problems
i. Qualitative prediction of reaction favorability
ii. Qualitative prediction of reaction spontaneity
iii. Quantitative prediction of reaction spontaneity