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Magnetism

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Title: Magnetism


1
Magnetism
  • How to describe the physics
  • Spin model
  • In terms of electrons

2
Spin model Each site has a spin Si
  • There is one spin at each site.
  • The magnetization is proportional to the sum of
    all the spins.
  • The total energy is the sum of the exchange
    energy Eexch, the anisotropy energy Eaniso, the
    dipolar energy Edipo and the interaction with the
    external field Eext.

3
Dipolar interaction
  • The dipolar interaction is the long range
    magnetostatic interaction between the magnetic
    moments (spins).
  • Edipo(1/4??0)?i,j MiaMjb?ia?jb(1/Ri-Rj).
  • Edipo(1/4??0)?i,j MiaMjb?a,b/R3-3Rij,aRij,b/Rij5
  • ?04? 10-7 henrys/m
  • For cgs units the first factor is absent.

4
Interaction with the external field
  • Eext-g?B H S-HM
  • We have set M?B S.
  • H is the external field, ?B e/2mc is the Bohr
    magneton (9.27 10-21 erg/Gauss).
  • g is the g factor, it depends on the material.
  • 1 A/m4? times 10-3Oe (B is in units of G) units
    of H
  • 1 Wb/m(1/4?) 1010 G cm3 units of M (emu)

5
Anisotropy energy
  • The anisotropy energy favors the spins pointing
    in some particular crystallographic direction.
    The magnitude is usually determined by some
    anisotropy constant K.
  • Simplest example uniaxial anisotropy
  • Eaniso-K?i Siz2

6
Orders of magnitude
  • For Fe, between atomic spins
  • J¼ 522 K
  • K¼ 0.038 K
  • Dipolar interaction (g?B)2/a3¼ 0.254 K
  • g?B¼ 1.45 10-4 K/Gauss

7
Last lecture we talk about J a little bit. We
discuss the other contribution next
  • First Hext

8
Hext g factor
  • We give two examples of the calculation of the g
    factor,the case of a single atom and the case in
    semiconductors.

9
Atoms
  • In an atom, the electrons have a orbital angular
    momentum L, a spin angular momentum S and a total
    angular momentum JLS.
  • The energy in an external field is given by
    Eext-g?BltJzgt by the Wigner-Eckert theorem.

10
Derivation of the orbital contribution gL1
  • E-H M.
  • The orbital magnetic moment ML area x current/c
    area? R2 currente?/(2?) where ? is the angular
    velocity. Now Lm? R2l. Thus ML ? emR2 ?
    /(cm2? ) -?0 I? e/(2mc). Recall ?Be?/2mc
  • M?B l.
  • The spin contribution is MS2?B S
  • Here S does not contain the factor of

R
11
Summary
  • E-M H
  • M?B( gL Lgs S) where gL1, gS2 the spin g
    factor comes from Diracs equation.
  • We want ltj,mJzj,mgt.
  • One can show that ltj,mMj,mgtg ltj,mJj,mgt for
    some constant g (W-E theorem). We derive below
    that g1j(j1)s(s1)-l(l1)/2j(j1).

12
Calculation of g
  • ML2SJS
  • ltj,mJMj,mgt?j,mltj,mJjmgt?ltj,mMj,mgt
    g?j,mltj,mJjmgt ? ltj,mJj,mgt g
    ltj,mJ2j,mgt g j (j1).
  • gj(j1)ltj,mJ Mj,mgtltj,mJ2J
    Sj,mgtj(j1)ltj,mJ Sj,mgt.
  • g1ltj,mJ Sj,mgt/j(j1).

13
Calculation of g in atoms
  • L(J-S) L2(J-S)2J2S2-2J S.
  • ltJ Sgtlt(J2S2-L2)gt/2 j(j1)s(s1)-l(l1)/2.
  • Thus g1 j(j1)s(s1)-l(l1)/2j(j1)

14
Another examples in semiconductors, k p
perturbation theory
  • The wave function at a small wave vector k is
    given by ? exp(ik r)uk(r) where u is a periodic
    function in space.
  • The Hamiltonian H-2r2/2mV(r). The equation for
    u becomes -2r2/2mV- k p/2uEu where the k2
    term is neglected.

15
G factor in semiconductors
  • The extra term can be treated as perturbation
    from the k0 state, the energy correction is
  • ? Dijkikj? lt?kipi?gtlt?kjpj?gt/E?-E?
  • In a magnetic field, k is replaced p-eA/c.
  • The equation for u becomes HuEu
  • H? Dij(pi-eAi/c)(pj-eAj/c)-?B? B). Since Ar
    B/2, the Dij term also contains a contribution
    proportional to B.

16
Calculation of g
  • HH1 H1 (e/c)? p ? D? AA? D? p.
  • Since Ar B/2, H1 (e/2c)? p ? D? (r ? B)(r?
    B)? D? p.
  • A? B? CA? B? C, for any A, B, C so H1 (e/2c)?
    (p?D?r?B -B?r?D?p )g?B ? B
  • g m ? (p?D?r - r?D?p)/?.
  • Note pirj??ij/imrjpi
  • gj? /i? Dil?jliO(p) where ?ijk? 1 depending on
    whether ijk is an even or odd permutation of 123
    otherwise it is 0 repeated index means
    summation.

17
gDA /i
  • g_z(D_xy-D_yx)/i, the antisymmetric D.
  • g is inversely proportional to the energy gap.
  • For hole states, g can be large

18
Effect of the dipolar interaction Shape
anisotropy
  • Example Consider a line of parallel spins along
    the z axis. The lattice constant is a. The
    orientation of the spins is described by S(sin?,
    0, cos? ). The dipolar enegy /spin is M02 ?
    1/i3-3 cos2 ? /i3/4??0 a3A-B cos2 ? .
  • ? 1/i3?(3)¼ 1.2
  • E-Keff cos2(?), Keff1.2 M02/4??0.

19
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20
Paramagnetism J0
  • Magnetic susceptibility ?M/B (?0)
  • We want to know ? at different temperatures T as
    a function of the magnetic field B for a
    collection of classical magnetic dipoles.
  • Real life examples are insulating salts with
    magnetic ions such as Mn2, etc, or a gas of
    atoms.

21
Magnetic susceptibility of different non
ferromagnets
Free spin paramagnetism
?
Van Vleck
Pauli (metal)
T
Diamagnetism (filled shell)
22
Boltzmann distribution
  • Probability P/ exp(-U/kB T)
  • U-g?B B J
  • P(m)/ exp(-g?B B m/kBT)
  • ltMgtN?B g?m P(m) m/?m P(m)
  • To illustrate, consider the simple case of J1/2.
    Then the possible values of m are -1/2 and 1/2.

23
ltMgt and ?
  • We get ltMgtNg?B exp(-x)-exp(x)/2exp(-x)exp(x)
    where xg?B B/(2kBT).
  • Consider the high temperature limit with xltlt1,
    ltMgt¼ N g?B x/2.
  • We get ?N(g?B )2/2kT
  • At low T, xgtgt1, ltMgtNg?B/2, as expected.

24
More general J
  • Consider the function Z ?m-jmj exp(-mx)
  • For a general geometric series 1yy2yn(1-yn1)
    /(1-y)
  • We get Zsinh(j1/2)x/sinh(x/2).
  • ltMgt-d ln Z/dxNg?B(j1/2) coth(j1/2)x-coth(x/
    2)/2.

25
Diamagnetism of atoms
  • ? in CGS for He, Ne, Ar, Kr and Xe are -1.9,
    -7.2,-19.4, -28, -43 times 10-6 cm3/mole.
  • ? is negative, this behaviour is called
    diamagnetic.
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