Kinetic Energy (DP IB Physics): Revision Note

Author

Ashika

Last updated

16 December 2024

Kinetic Energy

Kinetic energy (E_k) is the energy an object has due to its translational motion (i.e. because it's moving)
- The faster an object is moving, the greater its kinetic energy
When an object is falling, it is gaining kinetic energy since it is accelerating under gravity
This energy is transferred from the gravitational potential energy it is losing
An object will maintain this kinetic energy unless its speed or mass changes

Kinetic energy can be calculated using the following equation:

$E_{k} = \frac{1}{2} m v^{2}$

Where:
- E_k = kinetic energy (J)
- m = mass (kg)
- v = velocity (m s^–1)

Kinetic energy diagram, downloadable AS & A Level Physics revision notes

Kinetic energy: The energy an object has when it is moving

Another quantity that also depends on mass m and velocity v is momentum
Therefore, kinetic energy can be written in terms of momentum p, using the equation

$E_{k} = \frac{p^{2}}{2 m}$

Where:
- p = momentum (kg m s^–1)

This form is very useful in particle physics, when comparing the momentum and kinetic energy of a particle

Worked Example

A body travelling with a speed of 12 m s^–1 has kinetic energy 1650 J. The speed of the body is increased to 45 m s^–1.

Estimate the body's new kinetic energy.

Answer:

Examiner Tips and Tricks

When using the kinetic energy equation, note that only the speed is squared, not the mass or the ½. If a question asks about the ‘loss of kinetic energy’, remember not to include a negative sign since energy is a scalar quantity.

Both variations of the kinetic energy equation are given in your data booklet. You will most likely use $\frac{1}{2} m v^{2}$ in a mechanics question, and $\frac{p^{2}}{2 m}$ in particle physics.

If you are not convinced these are in fact the same equation:

$E_{k} = \frac{p^{2}}{2 m} = \frac{{(mv)}^{2}}{2 m} = \frac{m^{2} v^{2}}{2 m} = \frac{{mv}^{2}}{2} = \frac{1}{2} m v^{2}$

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Space, Time & Motion

Kinematics

Distance & Displacement

Speed & Velocity

Acceleration

Kinematic Equations

Motion Graphs

Projectile Motion

Fluid Resistance

Terminal Speed

Forces & Momentum

Free-Body Diagrams

Newton’s First Law

Newton’s Second Law

Newton’s Third Law

Contact Forces

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Hooke's Law

Stoke's Law

Buoyancy

Conservation of Linear Momentum

Impulse & Momentum

Force & Momentum

Collisions & Explosions in One-Dimension

Angular Velocity

Centripetal Force

Centripetal Acceleration

Non-Uniform Circular Motion

Work, Energy & Power

Principle of Conservation of Energy

Sankey Diagrams

Work Done

Kinetic Energy

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Elastic Potential Energy

Conservation of Mechanical Energy

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Efficiency Formula

Energy Density

The Particulate Nature of Matter

Thermal Energy Transfers

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Specific Heat Capacity

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Average Kinetic Energy of a Molecule

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