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Transcript
Nuclear and Particle Physics Lecture 2 Dr Daniel Watts 3rd Year Junior Honours Course Thursday January 13th Contact Details Course Organisers Franz Muheim (Particle Physics) [email protected] JCMB Room 4407 Daniel Watts (Nuclear Physics) [email protected] JCMB Room 5404 Nuclear Part: Course handouts will be available on course web portal at end of course (useful as in colour!) Main points of Lecture 1 Nuclear physics is crucial to many fields of research Rutherford: Atoms revealed as consisting of electrons orbiting an incredibly dense positively charged nucleus Nucleus comprised of protons (charged) and neutrons (uncharged) - mn~mp ~10-15m ~10-10m Typical energy scale in nuclei is MeV - Much higher than energies associated with atomic electrons (eV) Nuclei are dense objects: 1cm3 has mass ~ 2.3x1011 kg (equivalent to 630 empire state buildings!!) The forces of nature 1. Strong (nuclear) force • acts on all particles except leptons • always attractive (on average) • short range (10-15 m) ZAP short range force ng, i h not hin not g 10-15 m STRONGEST FORCE Fstrong = 1 2. Electromagnetic force • acts between all particles with charge • attractive/repulsive • always present but inverse square law ~ 1/R2 SECOND STRONGEST FORCE Fem ~ 10-2 Fstrong q2 dominant force in atoms, molecules, solid bodies (binding) long range force q1 3. Weak force → + + ν proton electron (T1/2 ~ 10 min.) neutrino • acts on all particles • very short range (10-18 m) • e.g. responsible for β decay SECOND WEAKEST FORCE Fweak ~ 10-7 Fstrong 4. Gravitational force • acts between all particles with mass • always attractive • always present but inverse square law WEAKEST FORCE ~ 1/R2 m1 long range force m2 Fgrav ~ 10-40 Fstrong but dominant force in the macrocosmos (large masses) … binds Earth ,solar system galaxies… Nucleus – Bound system of protons and neutrons interacting under the competing influence of attractive nuclear (strong) and repulsive electromagnetic forces (between protons) Nuclear force does not win over em repulsion indefinitely electromagnetic force (~Z2) wins at Z≥92 Finite number of naturally occurring atoms (Z≤ 92) Last completely stable nucleus Lead (Z=82) Weak forces important in unstable nuclei - β decay (see later) Rutherford scattering revisited Scattering α particles from gold nuclei Which force(s) are involved in this process? At energies available to Rutherford (~5 MeV) α’s cannot get close enough to nucleus to feel the strong force significantly – “Coulomb scattering” See Tutorial questions! ? 197 Au 79 (charge = +79e !) Only at higher incident energies do we see effects of strong force – deviation from simple Coulomb scattering Quantum mechanics Revision of some basic concepts • observable = physical, measurable quantity ⇔ operator examples total energy position linear momentum angular momentum ⇔ Hamiltonian Ĥ ⇔ x̂ p̂ ⇔ ⇔ L̂2 • system described by wave function ψ(x,t) obeying time dependent Schrödinger equation (TDSE) ⎧ h2 ∂2 ⎫ ∂ − + V ( x , t ) Ψ ( x , t ) = i h Ψ(x,t) ⎨ ⎬ 2 ∂t ⎩ 2m∂x ⎭ • static potential - stationary states exist. Described by spatial wave function ψ(x) obeying time independent Schrödinger equation (TISE) ⎧ h2 d2 ⎫ − + V ( x ) ⎨ ⎬ψE (x) = EψE (x) 2 2 m dx ⎩ ⎭ eigenfunction eigenvalue ĤψE (x) = EψE (x) eigenvalue equation only satisfied by certain values of E energy is QUANTISED measurements of total energy can only yield values which are eigenvalues of Hamiltonian operator Orbital angular momentum L̂2 = L̂2x + L̂2y + L̂z2 L̂2 ⇔ square of magnitude of angular momentum In spherical polar coordinates: 1 ∂ ⎛ 1 ∂2 ⎤ ∂ ⎞ L̂ = −h ⎢ ⎜ sin θ ⎟ + ⎥ sin θ θ ∂ ∂θ ⎠ sin2 θ ∂φ2 ⎦ ⎝ ⎣ 2⎡ 2 Important property: L̂2 commutes with any Cartesian component of angular momentum [L̂ , L̂ ] = 0 2 i both operators have simultaneous eigenfunctions m spherical harmonics Yl (θ, φ) Choose: L̂z = −ih ∂ ∂φ z-component of angular momentum vector • Eigenvalue equation for L̂2 L̂2Ylm (θ, φ) = l(l + 1)h2Ylm (θ, φ) l = 0,1,2,3,... orbital angular momentum quantum number angular momentum is QUANTISED • Eigenvalue equation for L̂z L̂z Ylm (θ, φ) = mhYlm (θ, φ) −l≤m≤l in integer steps magnetic momentum quantum number Eigenstates of L̂2 are DEGENERATE ⇔ (2l+1) possible values experimental evidence: Stern and Gerlach experiment (spatial quantisation) N.B. we refer to a particle in a state of angular momentum l meaning l(l + 1)h Intrinsic angular momentum ⇔ Ŝ No good classical analogue Electrons, protons, neutrons all have half integer spin: FERMIONS Ŝ Ŝz has eigenvalue s = ½ has eigenvalue ms = ± ½ spin up spin down Addition of angular momentum vectors in quantum mechanics when two states of angular momentum quantum numbers j1 and j2 add (or couple) together, they form a state with definite TOTAL angular momentum j and definite jz component ⏐j1-j2⏐ ≤ j ≤ j1 + j2 -j ≤ m ≤ j these states can be expressed as linear combination of states of the uncoupled basis {⏐j1,m1,j2 ,m2>} with coefficients known as Clebsch-Gordan coefficients Total angular momentum J Sum of orbital angular momentum and spin of nucleon J = L + S • Eigenvalue equation for Ĵ2 1 3 j = 0, ,1, ,2,... 2 2 Ĵ2 j, m = j( j + 1)h2 j, m • Eigenvalue equation for Ĵz Ĵz j, m = mh j, m −j≤m≤ j in integer steps (2j+1) possible projections set of (2j+1) states { j, m } called MULTIPLET Central symmetric potential Potential energy function V=V(r) is function of r only, not of θ and ϕ Solution of TISE: u(r,θ, φ) = R(r)Y(θ,φ) • radial wavefunction R(r) solution of radial TISE: ⎡ h2 1 d ⎛ 2 d ⎞ l(l + 1)h2 ⎤ r ⎟ + V(r) + ⎢− ⎥R(r ) = ER(r ) 2 dr ⎜ 2 2 µ dr r 2 µ r ⎝ ⎠ ⎣ ⎦ centrifugal potential (or barrier) • spherical harmonics Y(θ,ϕ) solution of angular TISE: ⎡ 1 ∂ ⎛ 1 ∂ ⎞ ∂2 ⎤ Y(θ, φ) = λY(θ, φ) −⎢ ⎜ sin θ ⎟ + 2 2⎥ sin θ θ θ ∂ ∂ ⎠ ⎝ sin θ φ ∂ ⎣ ⎦ N.B. potential V(r) does not appear in angular equation Ylm (θ, φ) always solutions, no matter what form for V(r) ⇒ Very general result following from spherical symmetry of potential | Ylm (θ , φ ) |2 Parity π r r Parity operator ⇒ inversion in the origin coordinates r → −r In polar coordinates: r→r θ→π−θ φ→π+φ Behaviour of eigenfunction under parity transformation determined by properties of spherical harmonics. [ ] P̂ unlm (r, θ, φ) = P̂ R(r )Ylm (θ, φ) = R(r )Ylm (π − θ, π + φ) = R(r )(− 1)l Ylm (θ, φ) P̂ unlm (r, θ, φ) = (− 1)l unlm (r, θ, φ) Eigenfunctions have definite parity: EVEN (or positive) for even l ODD (or negative) for odd l We will see in later lectures how conservation of total angular momentum and parity are of crucial importance in understanding nuclear structure and reactions
