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Specific Latent Heat (DP IB Physics: HL)

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Specific Latent Heat

  • During a phase change (i.e. a change of state) thermal energy is transferred to a substance or removed from it, while the temperature of the substance does not change
  • In this case, the thermal energy is calculated as follows:

Q = mL

  • Where:
    • Q = heat energy transferred (J)
    • m = mass of the substance in kilograms (kg)
    • L = specific latent heat of the substance in J kg–1

  • The specific latent heat of a substance is defined as:

The amount of energy required to change the state of 1 kg of a substance without changing its temperature

  • This definition can be explained when the above equation is rearranged for L:

L space equals space Q over m

  • This means that the higher the specific latent heat of a substance, the greater the energy needed to change its state
    • Note that the specific latent heat is measured in J kg–1

  • The amount of energy required to melt (or solidify) a substance is not the same as the amount of energy required to evaporate (or condense) the same substance
  • Hence, there are two types of specific heat:
    • Specific latent heat of fusion, Lf
    • Specific latent heat of vaporisation, Lv

  • Specific latent heat of fusion is defined as:

The energy released when 1 kg of liquid freezes to become solid at constant temperature

  • This applies to the following phase changes:
    • Solid to liquid
    • Liquid to solid

  • Therefore, the definition for specific latent heat of fusion could also be:

The energy absorbed when 1 kg of solid melts to become liquid at constant temperature

  • Specific latent heat of vaporisation is defined as:

The energy released when 1 kg of gas condenses to become liquid at constant temperature

  • This applies to the following phase changes:
    • Liquid to gas
    • Gas to liquid

  • Therefore, the definition for specific latent heat of vaporisation could also be:

The energy absorbed when 1 kg of liquid evaporates to become gas at constant temperature

  • For the same substance, the value of the specific latent heat of vaporisation is always much higher than the value of the specific latent heat of fusion
    • In other words, Lv > Lf

  • This is because much more energy is needed to evaporate (or condense) a substance than it is needed to melt it (or solidify it)
    • In melting, the intermolecular bonds only need to be weakened to turn from a solid to a liquid
    • When evaporating, the intermolecular bonds need to be completely broken to turn from liquid to gas. This requires a lot more energy.

Specific Latent Heat Table, downloadable IB Physics revision notes

Worked example

Determine the energy needed to melt 200 g of ice at 0°C.

  • The specific latent heat of fusion of water is 3.3 × 105 J kg–1
  • The specific latent heat of vaporisation of water is 2.3 × 106 J kg–1

Step 1: Determine whether to use latent heat of fusion or vaporisation

    • We need to use the specific latent heat of fusion because the phase change occurring is from solid to liquid

Step 2: List the known quantities

    • Mass of the ice, m = 200 g = 0.2 kg
    • Specific latent heat of fusion of water, Lf = 3.3 × 105 J kg–1

Step 3: Write down the equation for the thermal energy 

Q = mLf

Step 4: Substitute numbers into the equation 

Q = 0.2 kg × (3.3 × 105) J kg–1

 Q = 6.6 × 104 J = 66 kJ

Worked example

Energy is supplied to a heater at a rate of 2500 W.Determine the time taken to boil 0.50 kg of water at 100°C. Ignore energy losses.

  • The specific latent heat of fusion of water is 3.3 × 105 J kg–1
  • The specific latent heat of vaporisation of water is 2.3 × 106 J kg–1

Step 1: Determine whether to use latent heat of fusion or vaporisation

    • We need to use the specific latent heat of vaporisation because the phase change occurring is from liquid to gas

Step 2: Write down the known quantities

    • Power, P = 2500 W
    • Mass, m = 0.50 kg
    • Specific latent heat of vaporisation of water, Lv = 2.3 × 106 J kg–1

Step 3: Recall the equation linking power P, energy E and time t

E = Pt

Step 4: Write down the equation for the thermal energy E 

    • The energy E in the previous equation is the thermal energy Q transferred by the heater to the water

Q= mLv

Step 5: Equate the two expressions for energy 

Pt = mLv

Step 6: Solve for the time t 

t space equals space fraction numerator m L subscript v over denominator P end fraction

t = 460 s

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Ashika

Author: Ashika

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Ashika graduated with a first-class Physics degree from Manchester University and, having worked as a software engineer, focused on Physics education, creating engaging content to help students across all levels. Now an experienced GCSE and A Level Physics and Maths tutor, Ashika helps to grow and improve our Physics resources.