A-Level PhysicsYear 2020Q18
26 18 At the Culham Centre for Fusion Energy (CCFE) experiments are carried out to investigate nuclear fusion and the properties of plasmas. A plasma consists of ionised gas, containing positive ions and electrons. (a) In a fusion experiment at CCFE, ions of two isotopes of hydrogen fuse to produce helium ions and fast-moving neutrons. 1 2H + 1 3H → 2 4He + 0 1n Show that a single fusion reaction releases about 3 × 10−12 J of energy. mass of 1 2H = 2.013553 u mass of 1 3H = 3.015501 u mass of 2 4He = 4.001506 u mass of 0 1n = 1.008665 u (4) .................................................................................................................................................................................................................................................. .................................................................................................................................................................................................................................................. .................................................................................................................................................................................................................................................. .................................................................................................................................................................................................................................................. .................................................................................................................................................................................................................................................. .................................................................................................................................................................................................................................................. .................................................................................................................................................................................................................................................. .................................................................................................................................................................................................................................................. Turn over 27 (b) Fusion occurs naturally in the core of stars. Explain why very high densities of matter and very high temperatures are needed to bring about and maintain nuclear fusion in stars. (2) ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... (c) In a plasma experiment 5.0 mg of deuterium, an isotope of hydrogen, occupies a volume of 98 m3. The temperature of deuterium is raised to 1.3 × 108 K. In this experiment, the deuterium behaves as an ideal gas. (i) Calculate the pressure due to the deuterium ions. mass of deuterium ion = 3.3 × 10−27 kg (3) ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... Pressure = .................................................................... 28 (ii) Calculate the root mean square speed of the deuterium ions at this temperature. (2) ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... Root mean square speed = .................................................................... (iii) The temperature of the plasma is monitored using the Doppler effect. Light from a laser is directed into the plasma and the wavelength of the light reflected is measured. The Doppler shift observed when light is reflected by a deuterium ion is twice the Doppler shift that would be observed for a source of light moving at the same speed as the deuterium ion. Calculate the maximum wavelength of light that would be detected after reflection from a deuterium ion moving at 1.5 × 106 m s−1. wavelength of laser light = 1064 nm (3) ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... ................................................................................................................................................................................................................................................... Maximum wavelength detected = .................................................................... (Total for Question 18 = 14 marks) TOTAL FOR PAPER = 90 MARKS Every effort has been made to contact copyright holders to obtain their permission for the use of copyright material. Pearson Education Ltd. will, if notified, be happy to rectify any errors or omissions and include any such rectifications in future editions. Turn over 29 List of data, formulae and relationships Acceleration of free fall g = 9.81 m s−2 (close to Earth’s surface) Boltzmann constant k = 1.38 × 10−23 J K−1 Coulomb law constant k = 1 4πε0 = 8.99 × 109 N m2 C−2 Electron charge e = −1.60 × 10−19 C Electron mass me = 9.11 × 10−31 kg Electronvolt 1 eV = 1.60 × 10−19 J Gravitational constant G = 6.67 × 10−11 N m2 kg−2 Gravitational field strength g = 9.81 N kg−1 (close to Earth’s surface) Permittivity of free space ε0 = 8.85 × 10−12 F m−1 Planck constant h = 6.63 × 10−34 J s Proton mass mp = 1.67 × 10−27 kg Speed of light in a vacuum c = 3.00 × 108 m s−1 Stefan-Boltzmann constant σ = 5.67 × 10−8 W m−2 K−4 Unified atomic mass unit u = 1.66 × 10−27 kg Mechanics Kinematic equations of motion s = (u + v)t 2 v = u + at s = ut + 1 2 at2 v2 = u2 + 2as Forces ∑F = ma g = F m W = mg moment of force = Fx Momentum p = mv Work, energy and power ΔW = FΔs Ek = 1 2 mv2 ΔEgrav = mgΔh P = E t P = W t efficiency = useful energy output total energy input efficiency = useful power output total power input 30 Electric circuits Potential difference V = W Q Resistance R = V I Electrical power and energy P = VI P = I 2R P = V 2 R W = VIt Resistivity R = ρl A Current I = ΔQ Δt I = nqvA Materials Density ρ = m V Stokes’ law F = 6πηrv Hooke’s law ΔF = kΔ x Young modulus Stress σ = F A Strain ε = Δ x x E = σ ε Elastic strain energy ΔEel = 1 2 FΔ x Waves and particle nature of light Wave speed v = f λ Speed of a transverse wave on a string v = T μ Intensity of radiation I = P A Power of a lens P = 1 f P = P1 + P2 + P3 + … Thin lens equation 1 u + 1 v = 1 f Magnification for a lens m = image height object height = v u Diffraction grating nλ = d sin θ Refractive index n1 sin θ1 = n2 sin θ2 n = c v Critical angle sin C = 1 n Photon model E = h f Einstein’s photoelectric equation hf = ϕ + 1 2 mv2 max de Broglie wavelength λ = h p Turn over 31 Further mechanics Impulse FΔt = Δp Kinetic energy of a non-relativistic particle Ek = p2 2m Motion in a circle v = ωr T = 2π ω F = ma = mv2 r a = v2 r a = rω2 F = mrω2 Fields Coulomb’s law F = Q1Q2 4πε0r2 Electric field strength E = F Q E = Q 4πε0r2 E = V d Electric potential V = Q 4πε0r Capacitance C = Q V Energy stored in a capacitor W = 1 2 QV W = 1 2 CV 2 W = 1 2 Q 2 C Capacitor discharge Q = Q0e−t/RC I = I0e−t/RC V = V0e−t/RC ln Q = ln Q0 − t RC ln I = ln I0 − t RC ln V = ln V0 − t RC In a magnetic field F = BIl sin θ F = Bqv sin θ Faraday’s and Lenz’s laws E = −d(Nϕ) dt Root-mean-square values Vr ms = V0 √2 Ir ms = I0 √2 32 Nuclear and particle physics In a magnetic field r = p BQ Thermodynamics Heating ΔE = mcΔθ ΔE = LΔm Molecular kinetic theory 1 2 mác2ñ = 3 2 kT pV = 1 3 Nmác2ñ Ideal gas equation pV = NkT Stefan-Boltzmann law L = σAT 4 L = 4πr2σT 4 Wien’s law λmaxT = 2.898 × 10−3 m K Space Intensity I = L 4πd 2 Redshift of electromagnetic radiation z = Δλ λ ≈ Δf f ≈ v c Cosmological expansion v = H0d Nuclear radiation Mass-energy ΔE = c2Δm Radioactive decay A = λN dN dt = −λN λ = ln 2 t½ N = N0 e−λt A = A0 e−λt Gravitational fields Gravitational force F = Gm1m2 r 2 Gravitational field strength g = Gm r 2 Gravitational potential Vgrav = −Gm r Oscillations Simple harmonic motion F = −k x a = −ω2x x = A cos ωt v = −Aω sin ωt a = ‒Aω2 cos ωt T = 1 f = 2π ω ω = 2π f Simple harmonic oscillator T = 2π m k T = 2π l g
Paper Source:9PH0_02_que_20201016.pdf
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Exam Specification Info
This question is part of the UK A-Level Physics syllabus. In the actual exam, structured questions typically require linking specific keywords to gain full marks. Applaa helps you drill these topics.
Syllabus levelAdvanced Level (A-Level)
SubjectPhysics
Official MarksVariable (2–6 marks)