Reference no: EM132348272

PHYSICS   

Answer all the questions in the spaces provided.

1 A unit is often expressed with a prefix. For example, the gram may be written with the prefix ‘kilo’ as the kilogram. The prefix represents a power-of-ten. In this case, the power-of-ten   is 103.

Complete Fig. 1.1 to show each prefix with its symbol and power-of-ten.

Fig. 1.1

2 (a) Complete Fig. 2.1 to show whether each of the quantities listed is a vector or a scalar.

Fig. 2.1

(b) A ball falls vertically in air from rest. The variation with time t of the distance d moved by the ball is shown in Fig. 2.2.

(i) By reference to Fig. 2.2, explain how it can be deduced that

1. the ball is initially at rest,

2. air resistance is not negligible.

(ii) Use Fig. 2.2 to determine the speed of the ball at a time of 0.40 s after it has been released.

speed  =  ................ m s^–1

(iii) On Fig. 2.2, sketch a graph to show the variation with time t of the distance d moved by the ball for negligible air resistance. You are not expected to carry out any further calculations.

3 (a) The variation with extension x of the tension F in a spring is shown in Fig. 3.1.

Use Fig. 3.1 to calculate the energy stored in the spring for an extension of 4.0 cm. Explain your working.

energy = ................. J

(b) The spring in (a) is used to join together two frictionless trolleys A and B of mass M₁ and M₂ respectively, as shown in Fig. 3.2.

The trolleys rest on a horizontal surface and are held apart so that the spring is extended.

The trolleys are then released.

(i) Explain why, as the extension of the spring is reduced, the momentum of trolley A is equal in magnitude but opposite in direction to the momentum of trolley B.

(ii) At the instant when the extension of the spring is zero, trolley A has speed V₁ and trolley B has speed V₂.

Write down

1. an equation, based on momentum, to relate V₁ and V₂,

2. an equation to relate the initial energy E stored in the spring to the final energies of the trolleys.

(iii) 1. Show that the kinetic energy EK of an object of mass m is related to its momentum p by the expression

E_K =  p² / 2m.

2.Trolley A has a larger mass than trolley B. Use your answer in (ii) part 1 to deduce which trolley, A or B, has the larger kinetic energy at the instant when the extension of the spring is zero.

4 (a) State what is meant by the diffraction of a wave.

(b) A laser produces a narrow beam of coherent light of wavelength 632 nm. The beam is incident normally on a diffraction grating, as shown in Fig. 4.1.

Spots of light are observed on a screen placed parallel to the grating. The distance between the grating and the screen is 165 cm.
The brightest spot is P.  The spots formed closest to P and on each side of P are X   and Y.

X and Y are separated by a distance of 76 cm. Calculate the number of lines per metre on the grating.

number per metre = .................

(c) The grating in (b) is now rotated about an axis parallel to the incident laser beam, as shown in Fig. 4.2.

State what effect, if any, this rotation will have on the positions of the spots P, X and Y.

(d) In another experiment using the apparatus in (b), a student notices that the distances XP and PY, as shown in Fig. 4.1, are not equal.

Suggest a reason for this difference.

5 (a) State what is meant by an electric field.

(b) The electric field between an earthed metal plate and two charged metal spheres is illustrated in Fig. 5.1.

(i) On Fig. 5.1, label each sphere with (+) or (–) to show its charge.

(ii) On Fig. 5.1, mark a region where the magnitude of the electric field is

1.  constant (label this region C),

2. decreasing (label this region D).

(c) A molecule has its centre P of positive charge situated a distance of 2.8 × 10^–10 m from its centre N of negative charge, as illustrated in Fig. 5.2.

The molecule is situated in a uniform electric field of field strength 5.0 × 10⁴V m^–1. The axis NP of the molecule is at an angle of 30° to this uniform applied electric field.

The magnitude of the charge at P and at N is 1.6 × 10^–19 C.

(i) On Fig. 5.2, draw an arrow at P and an arrow at N to show the directions of the forces due to the applied electric field at each of these points.

(ii) Calculate the torque on the molecule produced by the forces in (i).

torque = .................. N m

6 An electric heater is to be made from nichrome wire. Nichrome has a resistivity of 1.0 × 10^–6 Ω m at the operating temperature of the heater. The heater is to have a power dissipation of 60W when the potential difference across its terminals is 12V.

(a) For the heater operating at its designed power,

(i) calculate the current,

current = .............................................. A

(ii) show that the resistance of the nichrome wire is 2.4 Ω.

(b) Calculate the length of nichrome wire of diameter 0.80 mm required for the heater.

length = ................. m

(c) A second heater, also designed to operate from a 12V supply, is constructed using the same nichrome wire but using half the length of that calculated in (b).

Explain quantitatively the effect of this change in length of wire on the power of the heater.

7 One of the isotopes of uranium is uranium-238 ( ²³⁸U₉₂).

(a) State what is meant by isotopes.

(b) For a nucleus of uranium-238, state

(i) the number of protons,

number = .................

(ii) the number of neutrons.

number = .....................

(c) A uranium-238 nucleus has a radius of 8.9 × 10^–15 m.

Calculate, for a uranium-238 nucleus,

(i) its mass,

mass = ................... kg

(ii) its mean density.

density = .............. kg m–3
 
(d) The density of a lump of uranium is 1.9 × 104 kg m^–3.

Using your answer to (c)(ii), suggest what can be inferred about the structure of the atom.