🏠 Home 📚 CSEC Physics 🔥 Specific Heat Capacity & Latent Heat

Specific Heat Capacity and Latent Heat

CSEC Physics: Thermal Properties

Essential Understanding: Why does ice melt at 0°C while water temperature stays constant? Why does a metal spoon get hotter faster than a wooden spoon? These questions are answered by understanding specific heat capacity and latent heat – two fundamental concepts explaining how substances absorb heat energy during temperature changes and phase transitions.

🔑 Key Skill: Calculating \( Q = mc\Delta T \) and \( Q = mL \)
📈 Exam Focus: Heating/Cooling Curve Interpretation
🎯 Problem Solving: Energy Conservation in Phase Changes

Core Concepts

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Specific Heat Capacity (c)

Definition: The amount of heat energy required to raise the temperature of 1 kg of a substance by 1°C (or 1 K).

Formula: \[ Q = mc\Delta T \]

  • \( Q \): Heat energy (Joules, J)
  • \( m \): Mass (kg)
  • \( c \): Specific heat capacity (J/kg°C or J/kgK)
  • \( \Delta T \): Temperature change (°C or K)

High c: Substance heats slowly (e.g., water: 4200 J/kg°C)

Low c: Substance heats quickly (e.g., copper: 385 J/kg°C)

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Latent Heat (L)

Definition: The heat energy required to change the phase of 1 kg of a substance without changing its temperature.

Two Types:

  1. Specific Latent Heat of Fusion (\( L_f \)): Solid ↔ Liquid
  2. Specific Latent Heat of Vaporization (\( L_v \)): Liquid ↔ Gas

Formula: \[ Q = mL \]

Unit: J/kg

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Energy Conservation

Heat Gain = Heat Loss

In calorimetry problems, energy transferred from hot object equals energy gained by cold object (assuming no heat loss to surroundings).

\[ m_1c_1\Delta T_1 = m_2c_2\Delta T_2 \]

For phase changes:
Heat to melt + heat to warm = Heat lost by hotter substance

Master Formulas for Thermal Physics

Temperature Change

\[ Q = mc\Delta T \]

When substance temperature changes

Phase Change

\[ Q = mL \]

When substance changes phase at constant temperature

Combined Process

\[ Q_{\text{total}} = mc\Delta T + mL \]

Heating ice to steam involves both!

Specific Heat Capacity Values

Substance Specific Heat Capacity (J/kg°C) Practical Significance
Water 4200 High value moderates coastal climates, used in cooling systems
Ethanol 2400 Lower than water, heats faster
Aluminum 900 Cooking pans heat evenly
Copper 385 Heats quickly, good for heat conductors
Iron 450 Moderate heating rate
Lead 130 Very low, heats very quickly

Worked Examples

1

Example 1: Specific Heat Capacity

Problem: Calculate the energy required to heat 2 kg of water from 20°C to 100°C. (c = 4200 J/kg°C)

Solution:

\[ Q = mc\Delta T \]

\[ Q = (2)(4200)(100 – 20) \]

\[ Q = 2 \times 4200 \times 80 = 672,000 \, \text{J} \]

\[ Q = 672 \, \text{kJ} \]

2

Example 2: Latent Heat of Fusion

Problem: How much energy is needed to melt 0.5 kg of ice at 0°C? (Lf for ice = 334,000 J/kg)

Solution:

\[ Q = mL_f \]

\[ Q = 0.5 \times 334,000 = 167,000 \, \text{J} \]

\[ Q = 167 \, \text{kJ} \]

Note: Temperature remains at 0°C during melting!

3

Example 3: Combined Process (CSEC Style)

Problem: Calculate total energy to convert 1 kg of ice at -10°C to steam at 100°C.

Given: cice = 2100 J/kg°C, cwater = 4200 J/kg°C, Lf = 334,000 J/kg, Lv = 2,260,000 J/kg

Solution in 4 steps:

  1. Heat ice from -10°C to 0°C: \( Q_1 = 1 \times 2100 \times 10 = 21,000 \, \text{J} \)
  2. Melt ice at 0°C: \( Q_2 = 1 \times 334,000 = 334,000 \, \text{J} \)
  3. Heat water from 0°C to 100°C: \( Q_3 = 1 \times 4200 \times 100 = 420,000 \, \text{J} \)
  4. Boil water at 100°C: \( Q_4 = 1 \times 2,260,000 = 2,260,000 \, \text{J} \)

Total: \( Q = 21,000 + 334,000 + 420,000 + 2,260,000 = 3,035,000 \, \text{J} \)

\[ Q = 3.035 \, \text{MJ} \]

CSEC Past Paper Question (Adapted)

June 2019, Question 8: A 0.2 kg copper calorimeter contains 0.5 kg of water at 20°C. A 0.1 kg piece of iron at 80°C is placed in the water. The final temperature is 22°C.

Given: Specific heat capacity of water = 4200 J/kg°C, copper = 385 J/kg°C, iron = 450 J/kg°C.

(a) Calculate the energy gained by the water and calorimeter.

(b) Calculate the energy lost by the iron.

(c) Explain why the answers to (a) and (b) are slightly different in real experiments.

a

Energy gained by water: \( Q_w = 0.5 \times 4200 \times (22-20) = 4200 \, \text{J} \)

Energy gained by calorimeter: \( Q_c = 0.2 \times 385 \times (22-20) = 154 \, \text{J} \)

Total gained = \( 4200 + 154 = 4354 \, \text{J} \)

b

Energy lost by iron: \( Q_i = 0.1 \times 450 \times (80-22) = 0.1 \times 450 \times 58 = 2610 \, \text{J} \)

c

In real experiments, some heat is lost to the surroundings, and the calorimeter isn’t perfectly insulated. Also, some energy may be used to heat the thermometer and stirrer.

Key Examination Insights

Common Mistakes

  • Using wrong specific heat capacity (e.g., using water’s c for ice)
  • Forgetting that temperature doesn’t change during phase change
  • Not converting units (grams to kg, kJ to J)
  • In calorimetry: forgetting to include the calorimeter’s heat capacity

Success Strategies

  • Draw heating/cooling curves for complex problems
  • Label all known values on the diagram
  • Use the principle: Heat lost = Heat gained (with sign for ΔT)
  • Check if phase change occurs by comparing temperatures

CSEC Practice Arena

Test Your Understanding

1
Which substance has the highest specific heat capacity?
Copper
Aluminum
Water
Iron
Explanation: Water has exceptionally high specific heat capacity (4200 J/kg°C) compared to metals (typically 400-900 J/kg°C). This is why water is used in heating systems and why coastal areas have milder temperatures.
2
When ice at 0°C melts to water at 0°C, what happens to its temperature?
Increases
Decreases
Stays the same
First increases then decreases
Explanation: During a phase change at constant pressure, temperature remains constant. The energy added breaks intermolecular bonds rather than increasing kinetic energy (temperature).
3
How much energy is required to heat 0.5 kg of aluminum from 20°C to 100°C? (c = 900 J/kg°C)
18,000 J
27,000 J
36,000 J
45,000 J
Solution: \( Q = mc\Delta T = 0.5 \times 900 \times (100-20) = 0.5 \times 900 \times 80 = 36,000 \, \text{J} \)
4
Why does a burn from steam at 100°C hurt more than from water at 100°C?
Steam has higher temperature
Steam releases latent heat of condensation
Steam moves faster
Water cannot cause burns at 100°C
Explanation: Steam at 100°C contains additional latent heat energy (2,260,000 J/kg for vaporization). When it condenses on skin, it releases this energy plus the cooling from 100°C, causing more severe burns.
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CSEC Examination Mastery Tip

Interpreting Heating/Cooling Curves: In CSEC exams, you’ll often see temperature-time graphs for heating or cooling substances.

  • Flat sections (plateaus): Phase change occurring (melting/freezing or boiling/condensing)
  • Sloping sections: Temperature changing (specific heat capacity in action)
  • Steeper slope: Lower specific heat capacity (heats/cools faster)
  • Longer plateau: Higher latent heat value

Always label the phases on the graph and identify what’s happening at each stage!

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