Physics 492 Lecture 22 - Michigan State Universitylynch/lecture_wk9.pdf · Physics 492 Lecture 24....

transcript

• Main points of today’s lecture:– Nuclear models.

• Spin-orbit term• Filling single particle

orbits• Nuclear Spins and

parities• Magnetic moments

• Main points of last lecture:– Nuclear models.

• Shell splitting central potential

• Spin-orbit term

Physics 492 Lecture 22

Energy Eigenvalues

• The result is what you expect for adding the energies of H.O. along x, y and z axes. Note ½ kr2= ½ k(x2+y2+z2)

spectroscopic notation: nLJ :L=1,2,3..;→S,P,D...z

What’s needed to get correct magic numbers?

• Spin-orbit interaction is the major missing term

Spin orbit potential

• Mayer and Jensen received Nobel Prize for showing that the nuclear Spin orbit potential gives the correct magic numbers.

• The nucleon-nucleon potential has a spin orbit. This means that the nucleon-nucleus spin orbit potential vanishes in the nuclear interior:

Constants of motion

• Lz, Sz don’t commute with VLS

Solutions of S.O. term

• Rewrite the S.O. operator:

• Hints for H.W.

Solutions of H.O. plus S.O.

• Single particle Wavefunctions

• Multiparticle Wavefunctions.

• Main points of today’s lecture:– Nuclear models.

• Nuclear Spins and parities

• Magnetic moments– Excited states

• Deformed nuclei• Rotations and vibrations

• Spin-orbit interaction• Filling single particle

orbits

Multiparticle wavefunctions

• Spin and parities of Shell model states are straightforward:– Closed shells have even parity and J=0

• Examples:– 7Be

– 46Ca

Magnetic Moments

• There are orbital and spin contributions to the magnetic moments– Orbital contribution:

– Units: Magnetons

– Orbital g factor:

• There are orbital and spin contributions to the magnetic moments– spin contributions:

• Estimation of moments:

Magnetic Moments

Accuracy of simple shell model magnetic moment estimations

Excited states

• Excited single particle states

Simple I.P.M

Excited states

Measured states

Excited states

• Excited single particle states

Collective states

• Nuclear vibrations

• Main points of today’s lecture:– Excited states

• Deformed nuclei• Rotations and vibrations

– Interactions• Gauge invariance• Perturbation series

expansion of the wavefunction

• Nuclear Spins and parities• Magnetic moments

– Excited states • vibrations

Collective excitations

• Rotations

Interactions

• Gauge invariance is an important theoretical requirement:– For E-M fields:

Gauge invariance and w and interactions

• The Haniltonian must not depend on the gauge fields

• Implies that perturbation potential must couple exchanged particle (photon) to a conserved current– EM interaction potential is inner product of Aμ field with

conserved EM current

Exchanged particle

• Aμ is a vector field and corresponds to exchange of spin one particle (photon).

Perturbation series expansion for wavefunction

• To understand Feynman diagrams, you need to recall the pertubationseries expansion for the wavefunction.

What simple models for nuclear shells?Coulomb pot. Square well. V=kr2 pot.

Atomic pot. Nuclear potential.

• Main points of today’s lecture:– particle in a three

dimensional box.

– harmonic oscillator

• Multiplicity function for set of N spinors:

• Probabilities:

• Main points of last lecture:• Single particle orbitals:

– spinor in magnetic field:

Physic 492 Lecture 1

( ) ( ) ( )! 2/! 2/! ,

sNsNNsNg

.... 4 3, 2, 1,,,2

),,( 2

zyxzyx

nnnnnnE

( ) ( ) ( ) nNn ppnNn

NnW −−−

= 1! !

1-mB-1/21/2

1mB1/21/2

mult.Emss

,...3 ,2 ,1 ,0 ;21

=⎟⎠⎞

⎜⎝⎛ += nnE ωh

Physics 492 Lecture 22 - Michigan State Universitylynch/lecture_wk9.pdf · Physics 492 Lecture 24....

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