Figure 1 shows an experiment to measure the charge of the electron - AQA - A-Level Physics - Question 1 - 2019 - Paper 7

To find the radius of the droplet, we will use the equation for the terminal velocity:

$v_t = \frac{2 r^2 (\rho_{oil} - \rho_{air})g}{9\eta}$

Where:

• $v_t$ is the terminal velocity ($1.0 × 10^{-1}$ m s⁻¹),
• $r$ is the radius of the droplet,
• $ho_{oil} = 880 ext{ kg m}^{-3}$,
• $ho_{air} = 1.2 ext{ kg m}^{-3}$ (approximate density of air),
• $g = 9.81 ext{ m s}^{-2}$ (acceleration due to gravity),
• $u = 1.8 × 10^{-5} ext{ N s m}^{-2}$ (viscosity of air).

Substituting the values:

$1.0 × 10^{-1} = \frac{2 r^2 (880 - 1.2) (9.81)}{9 \times 1.8 × 10^{-5}}$

Solving this for $r$, we find:

$r ∼ 1 × 10^{-6} ext{ m}$

If the droplet splits into two smaller droplets of equal size, each droplet will have a radius of $r/2$. Since the charge remains the same, the total charge will distribute equally among the two new droplets.

The charge on each smaller droplet will be: $q' = -\frac{4.8 × 10^{-19} C}{2} = -2.4 × 10^{-19} C$

Each smaller droplet will still experience the same forces:

• The weight will reduce since mass is proportional to the volume of the droplet.
• The electrostatic force will also be reduced, as it is proportional to charge.

However, since both forces scale down in relation to the droplet size, they will still balance out, meaning that both smaller spheres would not remain stationary; thus, the student's suggestion is incorrect.