Method

1. Set Up Apparatus: Assemble the apparatus as shown in the diagram, ensuring the stand is secure with a counterweight if necessary to prevent toppling.
2. Adjust Initial Height: Position the lower light gate so that the height $h$ between the release point (electromagnet) and this gate is 0.500 m, measured with the metre ruler.
3. Release and Record Time:

• Switch on the electromagnet to hold the steel ball bearing in place.
• Reset the stopwatch, if used, and then turn off the electromagnet to release the ball.
• The ball will pass through the lower light gate, which will record the time $t$ taken to fall from the initial height $h$.

4. Decrease Height in Intervals: Reduce $h$ by 0.050 m by raising the lower light gate, and repeat the timing measurement for each new height, down to a minimum height of 0.250 m.
5. Repeat for Accuracy: Repeat each measurement twice more and record the mean time $t$ for each height $h$ to improve reliability.

Safety

• Securing the Stand: Use a counterweight or clamp to ensure the stand is stable and will not tip over, preventing injuries.
• Protecting the Ball Bearing: Place a soft pad or tray at the bottom to safely cushion the ball after it falls.

Key Concepts

• Free-Fall Motion: The ball bearing is under uniform acceleration due to gravity, and we use the time taken over a set height to measure this acceleration.
• Equation of Motion for Free Fall: Since initial velocity $u = 0$, the simplified equation $h = \frac{1}{2}gt^2$ describes the relationship between height, time, and acceleration due to gravity.
• Graphical Analysis: By plotting $\frac{2h}{t}$ against $t$, we can derive $g$ from the gradient of the best-fit line.