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P461 - Nuclei II1 Nuclear Shell Model Potential between nucleons can be studied by studying bound states (pn, ppn, pnn, ppnn) or by scattering cross sections:

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Presentation on theme: "P461 - Nuclei II1 Nuclear Shell Model Potential between nucleons can be studied by studying bound states (pn, ppn, pnn, ppnn) or by scattering cross sections:"— Presentation transcript:

1 P461 - Nuclei II1 Nuclear Shell Model Potential between nucleons can be studied by studying bound states (pn, ppn, pnn, ppnn) or by scattering cross sections: np -> np pp -> pp nD -> nD pD -> pD If had potential could solve Schrod. Eq. Don’t know precise form but can make general approximation 3d Finite Well with little r-dependence (except at edge of well) Almost spherically symmetric (fusion can be modeled as deformations but we’ll skip) N-N interactions are limited (at high A) due to Pauli exclusion. p + n -> p’ + n’ only if state is available

2 P461 - Nuclei II2 Infinite Radial Well Radial part of Scrod Eq Easy to solve if l=0 For L>0, angular momentum term goes to infinity at r=0. Reduces effective wavelength, giving higher energy Go to finite well. Wave function extends a bit outside well giving longer effective wavelength and lower energy (ala 1D square wells) In nuceli, potential goes to infinity at r=0 (even with L=0) as that would be equivalent to nucleon “inside” other nucleon

3 P461 - Nuclei II3 Angular part If V(r) then can separate variables  (r,  = R(r)Y(  have spherical harmonics for angular wave function Angular momentum then quantized like in Hydrogen (except that L>0 for n=1, etc) Energy doesn’t depend on m Energy increases with increasing n (same l) Energy increases with increasing l (same n) If both n,l vary then use experimental observation to determine lower energy Energy will also depend on strong magnetic coupling between nucleons Fill up states separately for p,n

4 P461 - Nuclei II4 L,S,J Coupling: Atoms vs Nuclei ATOMS: If 2 or more electrons, Hund’s rules: Maximise total S for lowest E (S=1 if two) Maximise total L for lowest E (L=2 if 2 P) Energy split by total J (J=3,2,1 for S=1,L=2) NUCLEI: large self-coupling. Plus if 2 p (or 2 n) then will anti-align giving a state with J=0, S=0, L=0 leftover “odd” p (or n) will have two possible J = L + ½ or J = L – ½ higher J has lower energy if there are both an odd P and an odd n (which is very rare in stable) then add up Jn + Jp Atom called LS coupling nuclei called jj Note that magnetic moments add differently as different g-factor for p,n

5 P461 - Nuclei II5 Spin Coupling in Nuclei All nucleons in valence shell have same J Strong pairing causes Jz antiparallel (3 and -3) spin wavefunction = antisymmetric space wavefunction = symmetric This causes the N-N to be closer together and increases the attractive force between them e-e in atoms opposite as repulsive force Can also see in scattering of polarized particles Even N, even Z nuclei. Total J=S=L=0 as all n,p paired off Even N, odd Z or odd N, even Z. nuclear spin and parity determined by unpaired nucleon Odd N, odd Z. add together unpaired n,p Explains ad hoc pairing term in mass formula

6 P461 - Nuclei II6 Energy Levels in Nuclei Levels in ascending order (both p,n) State n L degeneracy(2j+1) sum 1S 1/2 1 0 2 2*** 1P 3/2 1 1 4 6 1P 1/2 1 1 2 8*** 1D 5/2 1 2 6 14 2S 1/2 2 0 2 16 1D 3/2 1 2 4 20*** 1F 7/2 1 3 8 28*** 2P 3/2 2 1 4 32 1F 5/2 1 3 6 38 2P 1/2 2 1 2 40 1G 9/2 1 4 10 50*** *** “magic” number is where there is a large energy gap between a filled shell and the next level. More tightly bound nuclei. (all filled subshells are slightly “magic”)

7 P461 - Nuclei II7 Magic Numbers Large energy gaps between some filled shells and next (unfilled) shell give larger dE/A and more made during nucleosnthesis in stars # protons #neutrons 2 He 2 He-4 6 C 6 C-12 8 O 8 O-16 20 Ca 20 28 Ni 28 Cr-52(24,28) 50 Sn 50 Ni-78 82 Pb 82 126 136 Ni-78 (2005) doubly magic. While it is unstable, it is the much neutron rich. Usually more isotopes if p or n are magic. Sn has 20 isotopes, 10 of which are stable

8 P461 - Nuclei II8 Nuclear Magnetic Moments Protons and neutrons are made from quarks and gluons. Their magnetic moment is due to their spin and orbital angular momentum The g-factors are different than electrons. orbital, p=1 and n=0 as the neutron doesn’t have charge spin, g for proton is 5.6 and for neutron is -3.8 (compared to -2 for the electron; sometimes just 2). A proton is made from 2 up and 1 down quark which have charge 2/3 and -1/3 A neutron is made from 1 up and 2 down and has “more” negative charge/moments No theory which explains hadronic magnetic moments orbital and spin magnetic moments aren’t aligned, need to repeat the exercise in atoms (Zeeman effect) to get values for the z-component of the moment

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