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PHYS 3446 – Lecture #6

PHYS 3446 – Lecture #6. Monday, Feb. 7, 2005 Dr. Jae Yu. Nature of the Nuclear Force Short Range Nature of the Nuclear Force Shape of the Nuclear Potential Yukawa Potential Range of Yukawa Potential Nuclear Models Liquid Drop Model Fermi-gas Model Shell Model. Announcements.

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PHYS 3446 – Lecture #6

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  1. PHYS 3446 – Lecture #6 Monday, Feb. 7, 2005 Dr. JaeYu • Nature of the Nuclear Force • Short Range Nature of the Nuclear Force • Shape of the Nuclear Potential • Yukawa Potential • Range of Yukawa Potential • Nuclear Models • Liquid Drop Model • Fermi-gas Model • Shell Model PHYS 3446, Spring 2005 Jae Yu

  2. Announcements • How many of you did send an account request to Patrick at (mcquigan@cse.uta.edu)? • I was told that only 7 of you have contacted him for accounts. • There will be a linux and root tutorial session next Wednesday, Feb. 16, for your class projects. • You must make the request for the account by this Wednesday. • First term exam • Date and time: 1:00 – 2:30pm, Monday, Feb. 21 • Location: SH125 • Covers: Appendix A + from CH1 to what we cover next Monday, Feb. 14 PHYS 3446, Spring 2005 Jae Yu

  3. Nuclear Properties: Binding Energy • The mass deficit • Is always negative and is proportional to the nuclear binding energy • How are the BE and mass deficit related? • What is the physical meaning of BE? • A minimum energy required to release all nucleons from a nucleus PHYS 3446, Spring 2005 Jae Yu

  4. Nuclear Properties: Binding Energy • de Broglie’s wavelength: • Where is the Planck’s constant • And is the reduced wave length • Assuming 8MeV was given to a nucleon (m~940MeV), the wavelength is • Makes sense for nucleons to be inside a nucleus since the size is small. • If it were electron with 8MeV, the wavelength is ~10fm, a whole lot larger than a nucleus. PHYS 3446, Spring 2005 Jae Yu

  5. Nuclear Properties: Sizes • Another way is to use the strong nuclear force using sufficiently energetic strongly interacting particles (p mesons or protons, etc) • What is the advantage of using these particles? • If energy is high, Coulomb interaction can be neglected • These particles readily interact with nuclei, getting “absorbed” into the nucleus • These interactions can be treated the same way as the light absorptions resulting in diffraction, similar to that of light passing through gratings or slits • The size of a nucleus can be inferred from the diffraction pattern • From all these phenomenological investigation provided the simple formula for the radius of the nucleus to its number of nucleons or atomic number, A: How would you interpret this formula? PHYS 3446, Spring 2005 Jae Yu

  6. Nuclear Properties: Magnetic Dipole Moments • Every charged particle has a magnetic dipole moment associated with its spin • e, m and S are the charge, mass and the intrinsic spin of the charged particle • Constant g is called Lande factor with its value: • : for a point like particle, such as the electron • : Particle possesses an anomalous magnetic moment, an indication of having a substructure PHYS 3446, Spring 2005 Jae Yu

  7. Nuclear Properties: Magnetic Dipole Moments • For electrons, me~mB, where mB is Bohr Magneton • For nucleons, magnetic dipole moment is measured in nuclear magneton, defined using proton mass • Magnetic moment of proton and neutron are: • What important information do you get from these? • The Lande factors of the nucleons deviate significantly from 2. • Strong indication of substructure • An electrically neutral neutron has a significant magnetic moment • Must have extended charge distributions • Measurements show that mangetic moment of nuclei lie -3mN~10mN • Indication of strong pairing • Electrons cannot reside in nucleus PHYS 3446, Spring 2005 Jae Yu

  8. Nature of the Nuclear Force • Scattering experiments helped to • Determine the properties of nuclei • More global information on the characteristics of the nuclear force • From what we have learned, it is clear that there is no classical analog to nuclear force • Gravitational force is too weak to provide the binding • Can’t have an electromagnetic origin • Deuteron nucleus has one neutron and one proton • Coulomb force destabilizes the nucleus PHYS 3446, Spring 2005 Jae Yu

  9. Short-range Nature of the Nuclear Force • Atomic structure is well explained by the electromagnetic interaction • Thus the range of nucleus cannot be much greater than the radius of the nucleus • Nuclear force range ~ 10-13 – 10-12cm • Binding energy is constant per each nucleon, essentially independent of the size of the nucleus • If the nuclear force is long-ranged, like the Coulomb force • For A nucleons, there would be ½ A(A-1) pair-wise interactions • Thus, the BE which reflects all possible interactions among the nucleons would grow as a function of A For large A PHYS 3446, Spring 2005 Jae Yu

  10. Short-range Nature of the Nuclear Force • If the nuclear force is long-ranged and is independent of the presence of other nucleons, BE per nucleon will increase linearly with A • This is because long-range forces do not saturate • Since any single particle can interact with as many other particle as are available • Binding becomes tighter as the number of interacting objects increases • The size of the interacting region stays fairly constant • Atoms with large number of electrons have the sizes compatible to those with smaller number of electrons • Long-rangeness of nuclear force is disputed by the experimental measurement that the BE/nucleon stays constant • Nuclear force must saturate • Any given nucleon can only interact with a finite number of nucleons in its vicinity PHYS 3446, Spring 2005 Jae Yu

  11. Short-range Nature of the Nuclear Force • What does adding more nucleons to a nucleus do? • Only increases the size of the nucleus • Recall that R ~ A1/3 • The size of a nucleus grows slowly with A and keep the nuclear density constant • Another supporting evidence of short-range nature of nuclear force PHYS 3446, Spring 2005 Jae Yu

  12. Shape of the Nuclear Potential • Nuclear force keeps the nucleons within the nucleus. • What does this tell you about the nature of the nuclear force? • It must be attractive!! • However, scattering Experiments with high energy revealed a repulsive core!! • Below a certain length scale, the nuclear force changes from attractive to repulsive. • What does this tell you? • Nucleons have a substructure…. • This feature is good, why? • If the nuclear force were attractive at all distances, the nucleus would collapse in on itself. PHYS 3446, Spring 2005 Jae Yu

  13. Attractive force Repulsive Core Shape of the Nuclear Potential • We can turn these behaviors into a square-well potential • For low energy particles, the repulsive core can be ignored, why? • This model is too simplistic, since there are too many abrupt changes in potential. • There would be additional effects by the Coulomb force PHYS 3446, Spring 2005 Jae Yu

  14. Nuclear Potential w/ Coulomb Corrections Results in • Classically an incident proton with total energy E0 cannot be closer than r=r0. Why? • For R<r<r0, V(r) >E0 and KE<0  Physically impossible • What about a neutron? • Could penetrate into the nuclear center. • Low energy scattering experiment did not provide the exact shape of the potential but the range and height of the potential • The square-well shape provides a good phenomenological description of the nuclear force. PHYS 3446, Spring 2005 Jae Yu

  15. Nuclear Potential • Description of nuclear potential using a square well shape suggests the basis of quantum theory with discrete energy levels and corresponding bound state as in atoms • Presence of such nuclear quantum states have been confirmed through • Scattering experiments • Studies of the energies emitted in nuclear radiation • Studies of mirror nuclei and the scattering of protons and neutrons demonstrate • Once Coulomb effects have been corrected, the forces between two neutrons, two protons and a proton and a neutron are the same  Nuclear force is charge independent!! • Inferred as charge independence of nuclear force. PHYS 3446, Spring 2005 Jae Yu

  16. Nuclear Potential • Strong nuclear force is independent of the electric charge carried by nucleons • Concept of strong isotopic-spin symmetry. • Under this symmetry, proton and neutron are the two different iso-spin state of the same particle, nucleon • If Coulomb effect can be turned off, protons and neutrons would be indistinguishable in their nuclear interactions • This is analogues to the indistinguishability of spin up and down states in the absence of a magnetic field!! • Iso-spin symmetry!!! PHYS 3446, Spring 2005 Jae Yu

  17. Range of Nuclear Force • EM force can be understood as a result of a photon exchange • Photon propagation is described by the Maxwell’s equation • Photons propagate at the speed of light. • What does this tell you about the mass of the photon? • Massless • Coulomb potential is expressed as • What does this tell you about the range of the Coulomb force? • Long range. Why? PHYS 3446, Spring 2005 Jae Yu

  18. Yukawa Potential • For massive particle exchanges, the potential takes the form • What is the mass, m, in this expression? • Mass of the particle exchanged in the interaction, or the force mediator • This form of potential is called Yukawa Potential • Formulated by Hideki Yukawa in 1934 • In the limit m 0, Yukawa potential turns into Coulomb potential PHYS 3446, Spring 2005 Jae Yu

  19. Ranges in Yukawa Potential • From the form of the Yukawa potential • The range of the interaction is given by some characteristic value of r, Compton wavelength of the mediator with mass, m: • Thus once the mass of the mediator is known, range can be predicted or vise versa • For nuclear force, range is about 1.2x10-13cm, thus the mass of the mediator becomes: • This is close to the mass of a well known p meson (pion) • Thus, it was thought that p are the mediators of the nuclear force PHYS 3446, Spring 2005 Jae Yu

  20. Assignments • End of the chapter problems: • 2.2, 2.5, 2.9. • Draw Yukawa potential for particles with the following masses as a function of the radial distance, r, in the range of 10-14 – 10-20 m in a semi-logarithmic scale. • 130 MeV/c2 • 80 GeV/c2 • 115 GeV/c2 • Due for these homework problems is next Monday, Feb. 16. PHYS 3446, Spring 2005 Jae Yu

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