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The drag force $F_D$ acting on a sphere falling through a liquid is given by
$$F_D = 6 \pi \eta r v$$
where $r$ is the radius of the sphere,
$v$ is the speed of the sphere in the liquid and
$\eta$ is a property of the liquid called the viscosity.
(a) Show that the SI base units of viscosity are kg m-1 s-1. [2]
(b) The sphere has a radius of 3.0 cm and is falling vertically downwards at a terminal velocity of 2.0 m s-1 through the liquid. The drag force acting on the sphere is 0.096 N.
Calculate the viscosity of the liquid. [2]
(c) The sphere is shown in Fig. 1.1.
On Fig. 1.1, draw and label arrows to represent the directions of the three forces acting on the sphere as it falls at terminal velocity through the liquid. [2]
(d) (i) The density of the liquid is 920 kg m-3.
Show that the upthrust acting on the sphere is 1.0 N. [2]
(ii) Calculate the mass of the sphere. [2]
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(a) Define displacement from a point. [1]
(b) An object is projected horizontally at a speed of 6.0 m s⁻¹ from a slope, as shown in Fig. 2.1.
The slope is at an angle $\theta$ to the horizontal. Air resistance is negligible.
The object lands on the slope a time of 0.71 s later and stops without rolling or bouncing.
(i) Determine the horizontal distance travelled by the object.[1]
(ii) Determine the vertical distance travelled by the object. [2]
(iii) Use your answers in (b)(i) and (b)(ii) to calculate $\theta$.[2]
(iv) Determine the magnitude of the displacement of the object from its original position.[2]
(v) By considering energy, calculate the speed of the object just before it lands.[3]
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(a) State Hooke's law. [1]
(b) The variation of the applied force with the extension for a sample of a material is shown in Fig. 3.1.
The sample behaves elastically up to an extension of 80mm and breaks at point X.
(i) On the line in Fig. 3.1, draw a cross (×) to show the limit of proportionality. Label this cross with the letter P. [1]
(ii) On the line in Fig. 3.1, draw a cross (×) to show the elastic limit. Label this cross with the letter E. [1]
(c) The sample in (b) has a cross-sectional area of 0.40 mm$^2$ and an initial length of 3.2m. For deformations within the limit of proportionality of the sample, determine:
(i) the spring constant of the sample [2]
(ii) the Young modulus of the material from which the sample is made. [3]
(d) Determine an estimate of the work done on the sample as it is extended from zero extension to its breaking point. Explain your reasoning. [2]
(e) A second sample of the same material has a larger cross-sectional area than the original sample but the same initial length. The two samples are each deformed with the limit of proportionality.
State and explain qualitatively how the spring constant of the second sample compares with that of the original sample. [2]
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A progressive transverse wave travelling from left to right is shown at an instant in time in Fig. 4.1.
R and T are points on the wave.
(a) State the phase difference between the points R and T. [1]
(b) On Fig. 4.1, draw an arrow at point T to show the direction of movement of point T at the instant shown. [1]
(c) The horizontal distance between R and T is 0.62 cm, as shown in Fig. 4.2.
The speed of the wave is 0.27 m s−1.
Calculate the frequency of the wave. [3]
(d) The wave is a water wave produced by a dipper $S_1$ attached to a vibrator in a ripple tank.
An identical dipper $S_2$ is attached to the same vibrator. The two dippers produce an interference pattern on the water in the tank, as shown in Fig. 4.3.
The wave crests from each source are represented by solid lines on Fig. 4.3 and the wave troughs are represented by dashed lines.
At point P in Fig. 4.3, the wave from $S_1$ has the same amplitude A as the wave from $S_2$.
Describe and explain the amplitude of the resultant wave at point P. [3]
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(a) (i) State Kirchhoff’s second law.
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(ii) State the conservation law that gives rise to Kirchhoff’s second law.
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(b) A circuit contains a cell of internal resistance $r$ and two resistors of resistances $R_1$ and $R_2$, as shown in Fig. 5.1.
The potential difference (p.d.) across the two resistors is $V$.
The current in the cell is $I$.
(i) Use Kirchhoff’s laws to show that the total resistance $R_T$ of the external circuit is given by
$$\frac{1}{R_T} = \frac{1}{R_1} + \frac{1}{R_2}.$$
[2]
(ii) The electromotive force (e.m.f.) of the cell is 1.50 V.
When the values of $R_1$ and $R_2$ are 10 Ω and 15 Ω respectively, the p.d. measured by the voltmeter is 1.38 V.
Calculate the internal resistance $r$ of the cell.
$$r=.............................................................. \Omega$$ [3]
(c) A third resistor is added in parallel with $R_1$ and $R_2$ in the circuit in Fig. 5.1.
State and explain the effect, if any, of this change on:
(i) the current in the cell
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(ii) the p.d. measured by the voltmeter.
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(a) State the nuclide notation in the form $_{Z}^{A}X$ for this isotope of samarium.
(b) This isotope of samarium is radioactive and decays by emitting particles. Gamma-radiation is
not emitted. The energy spectrum of the emitted particles is shown in Fig. 6.1.
[Image_1: Fig. 6.1 showing energy spectrum with the number of particles versus kinetic energy of particle]
(i) Explain how Fig. 6.1 shows that this isotope of samarium emits $\alpha$-particles and does not
emit $\beta$-particles.
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(ii) This isotope of samarium decays to an isotope of neodymium (Nd).
Give the radioactive decay equation for this decay. Include the nucleon and proton
numbers of all the particles involved.
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(c) A baryon is composed of three quarks which all have different flavours. The baryon has a
charge of 0.
Two of the quarks in the baryon are an up quark and a bottom quark.
(i) Determine, in terms of the elementary charge $e$, the charge on the third quark in the
baryon.
charge = ..........................................................$e$ [2]
(ii) State a possible flavour for the third quark in the baryon.
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