Syllabus Edition

First teaching 2023

First exams 2025

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Entropy (HL) (HL IB Physics)

Revision Note

Katie M

Author

Katie M

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Physics

Entropy

  • The entropy S of a given system is a measure of the number of possible arrangements of the particles and their energies
    • In other words, it is a measure of how disordered a system is
    • When a system becomes more disordered, its entropy will increase
  • The order of entropy for the different states of matter from most disordered to least is:

gas > liquid > solid

  • The entropy of a substance changes during a change in state
  • Entropy increases when a substance melts (solid → liquid) or boils (liquid → gas) 
    • Increasing the temperature of a substance causes the particles to vibrate more
    • The particles in a gas can now freely move around and are far apart from each other
    • The entropy increases as the particles become more disordered
  • Similarly, entropy decreases when a substance condenses (gas → liquid) or freezes (liquid → solid)
    • The particles are brought together and become arranged more regularly
    • The particles become less able to move as they become more ordered
    • There are fewer ways of arranging the energy, hence the entropy decreases

Entropy - Change in Entropy during a State Change, downloadable AS & A Level Chemistry revision notes

The entropy of a substance increases when the temperature is raised as particles become more disordered

  • Entropy can also increase when 
    • A solid dissolves in a solvent
    • A gas diffuses in a container
  • In both cases, entropy increases because:
    • The particles become more spread out
    • There is an increase in the number of ways of arranging the energy

Entropy - Change in Entropy upon Dissolving of a Solid, downloadable AS & A Level Chemistry revision notes

When a solid is dissolved in a solvent to form a dilute solution, the entropy increases as the particles become more disordered

2-4-3-entropy-of-diffusion

Worked example

A freezer door is opened while switched on and placed in a sealed room.

The entropy of the room

A.  equals zero

B.  increases

C.  decreases

D.  does not change

Answer:  B

  • A freezer is a heat pump, so thermal energy is transferred from inside the freezer and released at the back of the freezer
  • While it runs with the door open, the internal energy of the contents of the freezer decreases
  • The entropy of the contents of the freezer decreases because they are colder
  • But the entropy of the room increases because it is hotter

Real Isolated Systems

  • In thermodynamics, the distinction between reversible and irreversible processes at the macroscopic level is very important
  • A reversible process is defined as:

A process where there is no overall change in entropy as the system and its surroundings are returned to their original states

  • Whereas, an irreversible process is defined as:

A process which results in an increase in entropy as the system and its surroundings cannot return to their original states 

  • Processes in real isolated systems are almost always irreversible and consequently, the entropy of a real isolated system always increases

Non-Isolated Systems

  • While the entropy of an isolated system must always increase, the entropy of a non-isolated system can decrease
  • An isolated system is defined as

A system in which neither matter nor energy can be transferred in or out

  • Whereas in a non-isolated system, matter and energy can be transferred in or out
    • In other words, a non-isolated system can be thought of as one which is part of a larger isolated system
  • This means that the entropy of a non-isolated system can decrease locally, but this is compensated by an equal, or greater increase in the entropy of the surroundings

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Katie M

Author: Katie M

Katie has always been passionate about the sciences, and completed a degree in Astrophysics at Sheffield University. She decided that she wanted to inspire other young people, so moved to Bristol to complete a PGCE in Secondary Science. She particularly loves creating fun and absorbing materials to help students achieve their exam potential.