Definition and Basic Concepts
Heat Capacity Defined
Heat capacity (C): amount of heat (q) required to raise temperature (T) of a substance by 1 kelvin (K) or 1 degree Celsius (°C) at constant pressure or volume.
Fundamental Relation
Mathematically: C = q / ΔT where ΔT is temperature change; q is heat absorbed or released.
Extensive Property
Heat capacity depends on amount of substance: doubles mass, doubles heat capacity.
Types of Heat Capacity
Heat Capacity at Constant Volume (CV)
Defined when volume is held constant; no work done by expansion; internal energy changes only.
Heat Capacity at Constant Pressure (CP)
Defined when pressure is held constant; includes work done by expansion; generally greater than CV.
Specific Heat Capacity
Heat capacity per unit mass; intensive property; units J·g-1·K-1.
Molar Heat Capacity
Heat capacity per mole; units J·mol-1·K-1; useful for chemical thermodynamics.
Units and Dimensions
SI Units
Heat capacity units: joules per kelvin (J·K-1).
Specific Heat Units
Joules per gram kelvin (J·g-1·K-1), or calories per gram degree Celsius (cal·g-1·°C-1).
Molar Heat Capacity Units
Joules per mole kelvin (J·mol-1·K-1).
Dimensional Analysis
Heat capacity dimension: energy / temperature; M·L2·T-2·Θ-1.
Measurement Techniques
Calorimetry
Direct measurement of heat exchanged using calorimeters; types include bomb and coffee cup calorimeters.
Adiabatic Calorimetry
Measures temperature change with minimal heat loss; high precision for heat capacity determination.
Differential Scanning Calorimetry (DSC)
Measures heat flow difference between sample and reference as temperature varies; useful for phase transitions.
Experimental Considerations
Ensure thermal equilibrium; correct for heat losses; calibrate instruments accurately.
Thermodynamic Significance
Relation to Internal Energy and Enthalpy
CV = (∂U/∂T)V, CP = (∂H/∂T)P; U = internal energy, H = enthalpy.
Thermodynamic Identities
CP - CV = nR for ideal gases; reflects work done during expansion.
Entropy and Heat Capacity
Heat capacity influences entropy changes: dS = C dT / T for reversible processes.
Heat Capacity and Phase Changes
Heat capacity changes drastically near phase transitions; latent heat dominates.
Application in Calorimetry
Heat Transfer Calculations
q = C × ΔT used to quantify heat absorbed or released in reactions.
Determination of Specific Heat
Known mass and temperature change allow calculation of specific heat.
Reaction Enthalpy Measurements
Heat capacities enable conversion from temperature change to energy changes.
Example: Metal Sample
Metal mass heated; temperature recorded; specific heat inferred from heat exchange with water.
Temperature Dependence
Non-constant Heat Capacity
Heat capacity varies with temperature; not strictly linear.
Empirical Models
Heat capacity often expressed as polynomial: C = a + bT + cT2 + ...
Debye Model
Low temperature behavior of solids; C ∝ T3 below Debye temperature.
Einstein Model
Quantized vibrational modes; approximates heat capacity of solids at intermediate temperatures.
Molecular Basis
Degrees of Freedom
Atoms possess translational, rotational, vibrational modes contributing to heat capacity.
Equipartition Theorem
Each quadratic degree of freedom contributes ½ R to molar heat capacity.
Quantum Effects
At low temperatures, vibrational modes freeze out; heat capacity decreases.
Polyatomic vs Diatomic
More complex molecules have higher heat capacities due to additional vibrational modes.
Heat Capacity vs Specific Heat
Definitions
Heat capacity: total heat needed for temperature change; specific heat: per unit mass or mole.
Intensive vs Extensive
Heat capacity: extensive; specific heat: intensive.
Conversions
Specific heat (c) = Heat capacity (C) / mass (m) or moles (n).
Practical Usage
Specific heat used for comparisons; heat capacity used for total energy calculations.
Heat Capacity of Gases
Ideal Gas Behavior
CP and CV related by CP - CV = R.
Monatomic Gases
CV ≈ 3/2 R; CP ≈ 5/2 R; degrees of freedom: 3 translational.
Diatomic Gases
Include rotational and vibrational modes; higher heat capacities.
Real Gas Deviations
Interactions cause deviations from ideal heat capacity values.
Heat Capacity in Materials Science
Metals
Heat capacity influenced by electron and lattice vibrations; linear term at low T.
Polymers
Heat capacity varies with chain flexibility and phase.
Insulators
Lattice vibrations dominate heat capacity; Debye model applicable.
Application in Thermal Management
Materials selected based on heat capacity for thermal storage and insulation.
Practical Examples and Calculations
Example 1: Calculating Heat Required
Calculate q to raise 100 g water from 25°C to 75°C; c = 4.18 J·g-1·°C-1.
q = m × c × ΔTq = 100 g × 4.18 J/g°C × (75 - 25)°Cq = 100 × 4.18 × 50 = 20,900 JExample 2: Determining Specific Heat of Metal
Metal of mass 50 g heated to 100°C placed in 200 g water at 20°C; final temp 25°C; c_water = 4.18 J/g°C.
Heat lost by metal = heat gained by waterm_metal × c_metal × (100 - 25) = m_water × c_water × (25 - 20)50 × c_metal × 75 = 200 × 4.18 × 5c_metal = (200 × 4.18 × 5) / (50 × 75)c_metal ≈ 1.11 J/g°CTable: Heat Capacities of Common Substances
| Substance | Specific Heat (J·g-1·K-1) |
|---|---|
| Water (liquid) | 4.18 |
| Aluminum | 0.897 |
| Copper | 0.385 |
| Iron | 0.449 |
References
- Atkins, P., Physical Chemistry, 10th ed., Oxford University Press, 2014, pp. 152-176.
- Laidler, K.J., Meiser, J.H., Physical Chemistry, 3rd ed., Benjamin/Cummings, 1999, pp. 123-140.
- McQuarrie, D.A., Statistical Mechanics, University Science Books, 2000, pp. 210-235.
- Smith, J.M., Van Ness, H.C., Abbott, M.M., Introduction to Chemical Engineering Thermodynamics, 7th ed., McGraw-Hill, 2005, pp. 45-60.
- Callen, H.B., Thermodynamics and an Introduction to Thermostatistics, 2nd ed., Wiley, 1985, pp. 78-95.
Introduction
Heat capacity quantifies heat required to change a substance's temperature. Essential in thermochemistry, it links energy transfer and temperature variation. Different forms exist: molar, specific, at constant volume and pressure. Applications span calorimetry, materials science, and thermodynamics.
"Heat capacity is a fundamental thermodynamic property characterizing a substance's ability to absorb heat without a significant change in temperature." -- Peter Atkins