Thermochemistry
The study of heat energy associated with chemical reactions and physical transformations.
Basic Concepts
System and Surroundings
- System: Part of universe under study
- Surroundings: Everything else
- Universe: System + Surroundings
Types of Systems
| Type | Energy Exchange | Matter Exchange |
|---|---|---|
| Open | Yes | Yes |
| Closed | Yes | No |
| Isolated | No | No |
State Functions
Properties depending only on initial and final states:
- Enthalpy (H)
- Internal energy (U)
- Entropy (S)
- Gibbs free energy (G)
First Law of Thermodynamics
$$ΔU = q + w$$
Where:
- ΔU = change in internal energy
- q = heat absorbed by system
- w = work done on system
Enthalpy (H)
Heat content at constant pressure: H = U + PV
Types of Enthalpy Changes
| Symbol | Name | Definition |
|---|---|---|
| ΔH°f | Standard enthalpy of formation | One mole from elements in standard states |
| ΔH°c | Standard enthalpy of combustion | One mole burns in O₂ |
| ΔH°neut | Enthalpy of neutralization | Acid + base → salt + water |
| ΔH°sol | Enthalpy of solution | One mole dissolves |
| ΔH°vap | Enthalpy of vaporization | Liquid → gas |
| ΔH°fus | Enthalpy of fusion | Solid → liquid |
| ΔH°sub | Enthalpy of sublimation | Solid → gas |
| ΔH°at | Enthalpy of atomization | One mole to gaseous atoms |
Standard Conditions
- 1 bar pressure
- 298 K (25°C) temperature
- 1 M concentration for solutions
- Specified physical state
Calorimetry
Coffee-Cup Calorimeter (Constant Pressure)
$$q = mcΔT$$
Where:
- m = mass (g)
- c = specific heat capacity (J/g·K)
- ΔT = temperature change
At constant pressure: q = ΔH
Bomb Calorimeter (Constant Volume)
- Measures ΔU directly
- qv = Cv × ΔT
Hess's Law
The total enthalpy change for a reaction is the same, regardless of the pathway taken.
Applications
Using Formation Enthalpies
$$ΔH°_{rxn} = ΣΔH°_f(products) - ΣΔH°_f(reactants)$$
Using Bond Enthalpies
$$ΔH°_{rxn} = Σ(Bonds\ broken) - Σ(Bonds\ formed)$$
- Breaking bonds: Endothermic (+)
- Forming bonds: Exothermic (-)
Born-Haber Cycle
Hess's law application for ionic compounds:
- Atomization of metal
- Ionization of metal
- Atomization of non-metal
- Electron affinity of non-metal
- Lattice energy
- Formation enthalpy
Enthalpy of Hydration (ΔH°hyd)
Energy released when one mole of gaseous ions is surrounded by water molecules:
- Cations: ΔH°hyd is negative (exothermic); smaller ions and higher charges → more negative
- Anions: ΔH°hyd is negative; smaller ions → more negative
- Overall: ΔH°hyd(total) = ΔH°hyd(cation) + ΔH°hyd(anion)
Relationship: Enthalpy of Solution
$ΔH°_{sol} = ΔH°_{lattice} + ΔH°_{hyd}$
- If |ΔH°hyd| > |ΔH°lattice|: ΔH°sol is negative (exothermic dissolution)
- If |ΔH°hyd| < |ΔH°lattice|: ΔH°sol is positive (endothermic dissolution)
Lattice Energy
Energy required to separate one mole of solid ionic compound into gaseous ions.
Factors affecting lattice energy:
- Ionic charge: Higher charge → Higher LE
- Ionic radius: Smaller ions → Higher LE
Spontaneity and Gibbs Free Energy
$$ΔG = ΔH - TΔS$$
| ΔG | Spontaneity |
|---|---|
| < 0 | Spontaneous |
| = 0 | Equilibrium |
| > 0 | Non-spontaneous |
Temperature Dependence
| ΔH | ΔS | Spontaneity |
|---|---|---|
| - | + | Always spontaneous |
| - | - | Spontaneous at low T |
| + | + | Spontaneous at high T |
| + | - | Never spontaneous |
Related Topics
- Chemical Equilibrium — ΔG° = -RT ln K
- Phase Equilibria — Enthalpy of phase transitions
- Kinetic Chemistry — Activation energy