6.2.7 Energy in SHM | AQA A Level Physics Revision Notes 2017

Energy in SHM

Simple harmonic motion also involves an interplay between different types of energy: potential and kinetic
- The swinging of a pendulum is an interplay between gravitational potential energy and kinetic energy
- The horizontal oscillation of a mass on a spring is an interplay between elastic potential energy and kinetic energy

Energy of a Horizontal Mass-Spring System

When held so the spring is stretched beyond its equilibrium position there is the maximum amount of elastic potential energy
When the mass is released it moves back towards the equilibrium position, accelerating as it goes causing the kinetic energy to increase
At the equilibrium position, kinetic energy is at its maximum and elastic potential energy is at its minimum
Once past the equilibrium position the kinetic energy decreases and elastic potential energy increases

Energy of a Simple-Pendulum

At the amplitude top of the swing, the pendulum has a maximum amount of gravitational potential energy
When the pendulum is released, it moves back towards the equilibrium position, accelerating as it goes and the kinetic energy increases
As the height of the pendulum decreases the gravitational potential energy also decreases
Once the mass has passed the equilibrium position kinetic energy decreases and gravitational potential energy increases

Energy of a Horizontal Mass-Spring System

The system has the maximum amount of elastic potential energy when held so the string is stretched beyond its equilibrium position
When the mass is released it moves back towards the equilibrium position, accelerating as it goes causing the kinetic energy to increase
At the equilibrium position, kinetic energy is at its maximum and elastic potential energy is at its minimum
Once past the equilibrium position the kinetic energy decreases and elastic potential energy increases

Energy of a Simple-Pendulum

At the amplitude at the top of the swing, the pendulum has a maximum amount of gravitational potential energy
When the pendulum is released, it moves back towards the equilibrium position, accelerating as it goes and the kinetic energy increases
As the height of the pendulum decreases the gravitational potential energy also decreases
Once the mass has passed the equilibrium position kinetic energy decreases and gravitational potential energy increases

Total Energy of an SHM System

The total energy in the system remains constant, but the amount of energy in one form goes up, while the amount in the other form goes down
- This constant total energy shows how energy in a closed system is never created or destroyed; it is transferred from one store to another
- This is the law of conservation of energy

The total energy of a simple harmonic system always remains constant and is equal to the sum of the kinetic and potential energy

The total energy is calculated using the equation:

E = E_P + E_K

Where:
- E = total energy in joules (J)
- E_P = potential energy in joules (J)
- E_K = kinetic energy in joules (J)
Remember the equations for potential and kinetic energy:
- Gravitational potential energy: E_p = mgh
- Elastic potential energy, E_p = $\frac{1}{2} k x^{2}$
- Kinetic energy, E_k = $\frac{1}{2} m v^{2}$

Energy-Displacement Graph

The kinetic and potential energy transfers go through two complete cycles during one period of oscillation
- One complete oscillation reaches the maximum displacement twice (on both the positive and negative side of the equilibrium position)
You need to be familiar with the graph showing the total, potential and kinetic energy transfers in half an SHM oscillation (half a cycle)

Graph showing the potential and kinetic energy against displacement in half a period of an SHM oscillation

The key features of the energy-displacement graph are:
- Displacement is a vector, so, the graph has both positive and negative x values
- The potential energy is always maximum at the amplitude positions x = A, and 0 at the equilibrium position x = 0
  - This is represented by a ‘U’ shaped curve
- The kinetic energy is the opposite: it is 0 at the amplitude positions x = A, and maximum at the equilibrium position x = 0
  - This is represented by an ‘n’ shaped curve
- The total energy is represented by a horizontal straight line above the curves

Energy-Time Graph for a Simple Pendulum

You also need to be familiar with the graph showing the total, gravitational potential and kinetic energy transfers against time for multiple cycles of a simple pendulum oscillating in simple harmonic motion

9-1-2-energy-graph-in-shm-new

The kinetic and gravitational potential energy of a simple pendulum oscillating in SHM vary periodically

The key features of the simple pendulum energy-time graph are:
- Both the kinetic and gravitational potential energy transfers are represented by periodic functions (sine or cosine) which vary in opposite directions to one another
- When the gravitational potential energy is 0, the kinetic energy is at its maximum and vice versa
- The total energy is represented by a horizontal straight line directly above the energy curves at the maximum kinetic and gravitational potential energy value
- Energy is always positive so there are no negative values on the y-axis (Any SHM energy graph drawn with negative energy values is incorrect)

Worked example

The following graph shows the variation with displacement of the kinetic energy of an object of mass 0.50 kg oscillating with simple harmonic motion. Energy losses can be neglected.

4-1-4-we-energy-in-shm-question-graph

Determine:

(a) The total energy of the object

(b) The amplitude of the oscillations

(d) The potential energy of the object when the displacement is x = 1.0 cm

Answer:

(a)

From the graph, the maximum value of kinetic energy is 60 mJ
At the equilibrium position $(x = 0)$ , the total energy E is exactly equal to the maximum value of kinetic energy
Since energy losses can be neglected, the total energy is constant

Total energy: E = 60 mJ

(b)

The amplitude is equal to the maximum displacement on either side of the equilibrium position (where the kinetic energy is zero)

Amplitude: $x_{0}$ = 2.0 cm

(c)

The maximum velocity can be found using the maximum kinetic energy in the equation:

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

Using:
- Mass of the object, m = 0.50 kg
- Maximum kinetic energy, E_k = 60 mJ = 0.06 J

$v = \sqrt{\frac{2 \times 0.06}{0.50}}$

Maximum velocity: v = 0.49 m s^–1

(d)

From the graph, when the displacement is x = 1.0 cm, kinetic energy is E_K = 50 mJ
The relationship between total energy E, kinetic energy E_K and potential energy E_P is:

E = E_P + E_K

Therefore, the potential energy is

E_P = E – E_K

E_P = 60 – 50 = 10 mJ

Exam Tip

You may be expected to draw as well as interpret energy graphs against time or displacement in exam questions. Make sure the sketches of the curves are as even as possible and use a ruler to draw straight lines, for example, to represent the total energy.

Energy in SHM (AQA A Level Physics)

Revision Note

Energy in SHM

Energy of a Horizontal Mass-Spring System

Energy of a Simple-Pendulum

Energy of a Horizontal Mass-Spring System

Energy of a Simple-Pendulum

Total Energy of an SHM System

Energy-Displacement Graph

Energy-Time Graph for a Simple Pendulum

Worked example

Exam Tip

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Author: Ann H