Unknown areas

Question 1

Explain that consideration of centripetal (radial) acceleration as the rate of change in linear (tangential) velocity leads to?

Answer 1

The concept of a centripetal (radial) force required to maintain circular motion.

Question 2

State what is meant by the moment of a force

Answer 2

A measure of its tendency to cause a body to rotate about a specific point or axis.

Question 3

What is Torque defined as?

Answer 3

The product of radius and force applied at that radius to an axis of rotation.

Question 4

Define the moment of inertia, I, of an object as?

Answer 4

A measure of its resistance to angular acceleration about a given axis.

Question 5

Describe the principles of the Cavendish/Boys and Maskelyne Schiehallion experiments.

Answer 5

Cavendish - measuring Earth’s density (and thus its mass) but also for proving that Newton’s law of gravitation worked on scales much smaller than those of the solar system.

The Schiehallion experiment was an attempt to measure the mass of the earth using a pendulum and a mountain (Mount Schiehallion). The mass of the mountain was approximated and the deflection of a pendulum due to the gravitational force of the mountain was measured.

Question 6

Describe a Gravitational potential ‘well’.

Answer 6

The term “well” is used to describe the shape of the curve created by the gravitational potential of a body. The deeper the well, the more energy that a mass must have in order to leave the gravitational pull of the large body.

Question 7

Explain why smaller planets have no atmosphere and the low incidence of helium in Earth’s atmosphere etc.

Answer 7

Planets with smaller masses, like that of Mercury, or even Earth, don’t have enough gravity to hold onto the lighter gases, like Hydrogen and Helium. These gases can escape the gravitational pull of the planet and drift off into space.

Question 8

Describe the consequences of the Equivalence Principle?

Answer 8

• Clocks in non-inertial reference frames e.g. accelerating spacecraft
• Clocks at altitude i.e. clocks run at different speeds in different
  gravitational field strengths
• Precession of Mercury’s orbit
• Gravitational lensing of light

Question 9

What is spacetime?

Answer 9

A representation of four dimensional space.

Question 10

Light or a freely moving object follows what kind of path?

Answer 10

A geodesic (the shortest
distance between two points) path in spacetime.

Question 11

What curves spacetime?

Answer 11

Mass

Question 12

Where does gravity arise from?

Answer 12

The curvature of spacetime

Question 13

Where are stars born?

Answer 13

Stars are born in interstellar clouds that are particularly cold and
dense (relative to the rest of space).

Question 14

What are the challenges to classical theory by considering experimental observations that could not be explained by classical physics?

Answer 14

• Black-body radiation curves (“ultraviolet catastrophe”)
• Planck’s suggestion that the absorption and emission of
  radiation could only take place in ‘jumps’,
• photoelectric effect could not be explained using
  classical physics,
• Einstein’s suggestion that the energy of electromagnetic
  radiation is quantized,
• The Bohr model of the atom, which explains the
  characteristics of atomic spectra in terms of electron
  energy states, Bohr’s quantisation of angular
  momentum,
• De Broglie suggested that electrons have wave
  properties, the de Broglie relationship between
  wavelength and momentum and electron diffraction is
  evidence for wave/particle duality.

Question 15

Describe of the effects of damping in SHM (to include underdamping, critical damping’ and overdamping)

Answer 15

An overdamped system moves slowly toward equilibrium. An underdamped system moves quickly to equilibrium, but will oscillate about the equilibrium point as it does so. A critically damped system moves as quickly as possible toward equilibrium without oscillating about the equilibrium.

Question 16

Examples of damping include?

Answer 16

Car shock absorbers, bridges, bungee cords, trampolines, diving boards, etc.

Question 17

Applications of superposition of waves include?

Answer 17

o Synthesisers related to addition of waves — Fourier analysis.
o Musical instruments — wind and string.
o Fundamental and harmonic frequencies.
o Beats — tuning of musical instruments.

Question 18

Understand the effect of the nature of boundary on the phase of a reflected wave.

Question 19

Examples of interference by division of amplitude include?

Answer 19

Thin film interference and wedge fringes, oil films, soap bubbles.

Question 20

Explanation of interference by division of wavefront,

Answer 20

Young’s slits interference.

Question 21

State Polarisation can also be produced by?

Answer 21

Reflection

Question 22

What is Brewster’s angle? It is the angle of incidence that causes reflected
light to be linearly polarised.

Answer 22

It is the angle of incidence that causes reflected light to be linearly polarised.

Question 23

Examples of polarisation include?

Answer 23

• Liquid crystal displays,
• computer/phone displays,
• polarising lenses,
• optical activity,
• photoelasticity and saccharimetry.
• Stress analysis of Perspex models of structures.

Question 24

Define electric field strength?

Answer 24

Force acting per unit charge

Question 25

State that the energy required to move charge between two points in an electric field is independent of?

Answer 25

The path taken.

Question 26

State and explain the magnetic effect called ferromagnetism which occurs in certain metals…

Answer 26

Iron, nickel, cobalt, and some rare earths exhibit a magnetic
effect called ferromagnetism, in which magnetic dipoles can be made to align, resulting in
the material becoming magnetised.

Question 27

What is a solenoid?

Answer 27

A coil of insulated or enameled wire wound on a rod-shaped form made of solid iron, solid steel, or powdered iron.

Question 28

State the comparisons between; gravitational, electrostatic, magnetic and nuclear forces, in terms of magnitude and range.

Answer 28

Gravitational weakest then nuclear then electrostatic and magnetic.

Nuclear shortest range all others infiniate range.

Question 29

State what is meant by the self inductance of a coil.

Answer 29

The tendency of a coil to resist changes in current in itself.

Question 30

Definition of back e.m.f..

Answer 30

a reverse voltage, (-VL) in the same coil which opposes the rate at which the current changes, known commonly as self-inductance

Question 31

Definition of inductance

Answer 31

The property of an electric conductor or circuit that causes an electromotive force to be generated by a change in the current flowing.

Question 32

How are electricity and magnetism are linked in Electromagnetic radiation?

Answer 32

A changing magnetic field will induce a changing electric field and vice-versa—the two are linked.

Question 33

What is a calibration uncertainty?

Answer 33

Calibration uncertainty is a manufacturer’s claim for the accuracy of an instrument compared with an approved standard.

Question 34

What is the ultraviolet catastrophe?

Answer 34

The prediction of classical electromagnetism that the intensity of the radiation emitted by an ideal black body at thermal equilibrium goes to infinity as wavelength decrease

Question 35

What does Lenz’s law state?

Answer 35

That the E.M.F produced by self inductance will oppose the current which produced it. The E.M.F produced by self inductance is called back E.M.F.