Syllabus Edition

First teaching 2023

First exams 2025

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Heat Engines (HL) (HL IB Physics)

Revision Note

Katie M

Author

Katie M

Expertise

Physics

Heat Engines

  • A heat engine is a device that converts thermal energy into mechanical work
  • Heat engines operate through a series of thermodynamic processes which form a closed cycle
    • A closed cycle is one in which the system returns to its initial state
  • A simple heat engine consists of a gas in a cylinder with a piston

2-4-7-heat-engine-piston-diagram

A simple heat engine converts thermal energy into mechanical work

  • The steps in the operation of a cyclic heat engine process are:

1. Extract heat from a hot reservoir

    • A hot reservoir (a source of thermal energy) at a high temperature T subscript H transfers heat Q subscript H into the engine

2. Use some of the extracted heat to perform work

    • The gas does mechanical work as it expands which pushes the piston out

3. Release excess heat into a cold reservoir

    • The gas is allowed to cool at constant volume, meanwhile, heat Q subscript C is released to the surroundings
    • Some of the energy transferred into the engine is released into a cold reservoir (a sink for excess heat) at a lower temperature T subscript C

4. Repeat cycle

    • Once the heat has been extracted, the piston is pushed down to compress the gas back to its original state
    • The process can then be repeated as many times as needed, continuously converting heat into mechanical work 

2-4-7-thermodynamic-heat-engine-diagram

  • For a cyclic heat engine process, the p-V diagram will form a closed loop
  • The area inside the loop is equal to the net work done during one cycle

2-4-7-heat-engine-pv-diagram

  • The net work done by the engine is:

increment W subscript o u t end subscript space equals space Q subscript H space minus space Q subscript C

  • Where:
    • increment W subscript o u t end subscript = useful work output of the heat engine (J)
    • Q subscript H = heat transferred from hot reservoir to engine (J)
    • Q subscript C = heat transferred from engine to cold reservoir (J)

Efficiency of Heat Engines

  • The goal of a heat engine is to transfer thermal energy into useful mechanical work as efficiently as possible
  • The thermodynamic efficiency of a heat engine can be calculated using

efficiency = fraction numerator u s e f u l space w o r k space o u t p u t over denominator t o t a l space e n e r g y space i n p u t end fraction

eta space equals space W subscript o u t end subscript over Q subscript H space equals space fraction numerator open parentheses Q subscript H space minus space Q subscript C close parentheses over denominator Q subscript H end fraction

eta space equals space 1 space minus space Q subscript C over Q subscript H

  • Where:
    • eta = efficiency of a heat engine
    • W subscript o u t end subscript = useful work output (J)
    • Q subscript H = total energy input from the hot reservoir (J)
    • Q subscript C = energy lost to the cold reservoir (J)

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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.