Paper 2
| Gravitational acceleration | \( g=9.81\,\mathrm{m\,s^{-2}} \) |
| Speed of light | \( c=3.00\times10^8\,\mathrm{m\,s^{-1}} \) |
| Elementary charge | \( e=1.60\times10^{-19}\,\mathrm{C} \) |
| Electron mass | \( m_e=9.11\times10^{-31}\,\mathrm{kg} \) |
| Planck constant | \( h=6.63\times10^{-34}\,\mathrm{J\,s} \) |
| Permittivity of free space | \( \epsilon_0=8.85\times10^{-12}\,\mathrm{F\,m^{-1}} \) |
| Magnetic constant | \( \mu_0=1.26\times10^{-6}\,\mathrm{N\,A^{-2}} \) |
| Boltzmann constant | \( k_B=1.38\times10^{-23}\,\mathrm{J\,K^{-1}} \) |
a) Find the electric field magnitude between the plates and state its direction.
[3 marks]b) Calculate the capacitance in air and the magnitude of the charge on either active plate.
[4 marks]c) Find the stored energy in the air-filled sensor.
[3 marks]d) A dielectric slab with relative permittivity \(\kappa=3.20\) is inserted so that it completely fills the gap. Compare the new charge, field, voltage, and stored energy for the cases where the sensor remains connected to the supply and where it is first isolated.
[5 marks]a) Find the motional emf across the rod and identify which end of the rod is at higher potential while the rod is in the field.
[3 marks]b) Calculate the induced current and use Lenz's law to state its direction as the rod enters the field region.
[4 marks]c) Find the magnetic braking force on the rod, including its direction.
[3 marks]d) Compare the mechanical power needed to maintain the rod's motion with the electrical power dissipated in the resistor.
[3 marks]e) State what happens to the emf and current after the rod has left the field region, and describe the Lenz-law direction during the exit interval.
[2 marks]a) Transform the two gate-firing events into the station frame \(S\).
[5 marks]b) State the time order of the two gate-firing events in each frame and explain the difference.
[3 marks]c) At the instant the rear gate fires, it sends a light signal toward the front gate. Find the signal arrival event in both frames.
[4 marks]d) Find the proper time elapsed on the front-gate clock between its firing and the arrival of the rear-gate signal, and check it against the station-frame interval.
[3 marks]a) State the wavefunction outside the window and write the probability density inside the window. Check the boundary values.
[3 marks]b) Normalize the trial wavefunction and find \(A\) in terms of \(L\).
[4 marks]c) Find the probability of detecting the particle in \(0\le x\le L/2\) and in \(L/4\le x\le3L/4\).
[4 marks]d) Estimate the position uncertainty from the normalized distribution. For \(L=0.500\,\mathrm{nm}\), estimate the lower bound on \(\Delta p\) and the corresponding kinetic-energy scale in electronvolts. The position uncertainty is \[ \Delta x=\sqrt{\langle x^2\rangle-\langle x\rangle^2} \] and the Heisenberg uncertainty relation is \[ \Delta x\Delta p\ge\frac{\hbar}{2}. \]
[4 marks]