Enthalpy & Entropy

Definition

Enthalpy is a thermodynamic property of a system that represents the total heat content, calculated as the internal energy plus the product of pressure and volume ($H = U + PV$). Entropy is a measure of the degree of randomness, disorder, or uncertainty within a thermodynamic system, often described as the dispersal of energy.

Main Content

1. Enthalpy (The Heat Content)

Enthalpy measures the total energy of a thermodynamic system, including the internal energy required to create the system and the energy required to make room for it by displacing its environment.
It is a state function, meaning its value depends only on the current state of the system, not the path taken to reach that state.

2. Entropy (The Disorder)

Entropy quantifies the number of microscopic configurations that correspond to a thermodynamic system in a state of specified macroscopic variables.
According to the Second Law of Thermodynamics, the total entropy of an isolated system can never decrease over time; it can only remain constant or increase.

3. The Relationship (Gibbs Free Energy)

Enthalpy and entropy are bridged by Gibbs Free Energy ($G = H - TS$), which determines the spontaneity of a chemical reaction.
If the net change in Gibbs Free Energy is negative, the process is spontaneous.

Energy Relationship:
[ Enthalpy (H) ] - [ Temperature (T) * Entropy (S) ] = [ Gibbs Free Energy (G) ]
        |                   |                              |
Total Heat Content    Degree of Disorder           Spontaneity Indicator

Working / Process

1. Calculating Enthalpy Change ($\Delta H$)

To calculate enthalpy change, subtract the enthalpy of the reactants from the enthalpy of the products: $\Delta H = H_{products} - H_{reactants}$.
If $\Delta H$ is negative, the reaction is exothermic (releases heat); if positive, it is endothermic (absorbs heat).

2. Measuring Entropy Change ($\Delta S$)

Entropy change is determined by the heat transferred in a reversible process divided by the absolute temperature: $\Delta S = Q_{rev} / T$.
A positive $\Delta S$ indicates an increase in molecular disorder (e.g., solid turning into gas).

3. Determining Spontaneity

Use the equation $\Delta G = \Delta H - T\Delta S$ to predict if a reaction will occur naturally.
If $\Delta G < 0$, the reaction is spontaneous; if $\Delta G > 0$, the reaction is non-spontaneous and requires external energy.

Advantages / Applications

Chemical Engineering: Used to design efficient heat exchangers and reactors by calculating energy requirements.
Environmental Science: Entropy explains why energy conversion processes are never 100% efficient, highlighting the limit of natural resources.
Materials Science: Helps in predicting phase transitions, such as why ice melts into water at room temperature due to increased entropy.

Summary

Enthalpy represents the total heat content of a system, while entropy measures the randomness or energy dispersal. Together, these concepts determine whether physical or chemical processes occur spontaneously.

Enthalpy ($H$): Total energy/heat content.
Entropy ($S$): Measure of disorder.
Spontaneity: Determined by the Gibbs Free Energy equation.
Important terms: Exothermic, Endothermic, Thermodynamic Equilibrium, State Function.