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Introduction of the F1 spinor BEC

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Introduction of the F=1 spinor BEC. ???. ???????????. F=1 spinor BEC :23Na, ... hyperfine spin. nuclear spin. BEC. magnetic trapping (one-component, scalar) ... – PowerPoint PPT presentation

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Title: Introduction of the F1 spinor BEC


1
Introduction of the F1 spinor BEC
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2
Spinor BEC
hyperfine spin
electron spin
nuclear spin
magnetic trapping (one-component, scalar)
BEC
optical trapping (multi-component, vector)
F1 spinor BEC 23Na, 87Rb,...
3
Grand canonical energy-functional for the spinor
BEC (Ho, Ohmi)
N is a fixed number
(gslt0 ferromagnetic gsgt0 antiferromagnetic)
4
order parameter
global phase
rotational symmetry in spin space
spin operators
5
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6
Ground state structure of spinor BEC
Define the normalized spinor by
Such that all spinors are degenerate with the
transformation
where
Euler angles
7
Define
then the free energy can be expressed as
The free energy of K is minimized by
8
Coupled GPE for spinor BEC
Time-dependent coupled GPE
9
Time-independent coupled GPE
10
Modification of GPE conservation of
magnetization
The spin-exchange interaction also preserves the
magnetization M, so we have two constraints for
the GPE
11
The conservation of particle number and
magnetization is equivalent to introduce the
Lagrange multipliers ? and B in the free energy
N and M are both fixed numbers
12
The corresponding GPEs are modified to
13
Some interesting results
Ferromagnetic
3 identical decoupled equations
anti-ferromagnetic
2 coupled-mode equations
14
Field-induced phase segregation of the condensate
configuration
the spin configuration of
Using the inequality
the ground state can be constructed by minimizing
the spin-dependent part of the Hamiltonian
Case 1
Choose
However, since
(ferromagnetic state)
15
Let
(Larmor frequency)
the Hamiltonian is invariant under the gauge
transformation
16
Case 2
so that we have
Choose
The minimum is achieved if
We may assume that
0 and is real but since
which is in contraction with the condition
and we must conclude that
17
For
(polar state )
where
the condition
Note that when
cannot be fulfilled and we must choose F such
that
is as close to
as possible. This implies that
and thus the ground state is described by
(ferromagnetic state )
18
For
the two different configurations coexist
(polar region)
(ferro region)
The phase boundary rb is determined by
19
The free energy is given by
In the Thomas-Fermi limit, the minimization of
the free energy,
leads to
20
Example
phase boundary
radius of atomic cloud
The total particle number and the chemical
potential is related by
21
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23
Derivation of hydrodynamic equations
collective excitations
polar region
hydrodynamic-like mode
ferro region
fluctuation of number density
Furthermore, we let
fluctuation of spin density
24
Substituting
into the time-dependent GP equation
Upon linearization we obtain the hydrodynamic
equations in different regions
ferro region
(Stringari)
polar region
25
Example
where
Now let
26
To solve the coupled equations, let
and we obtain the recursion relation
Denote u? as the eigenvectors of A with
eigenvalues
and let
27
Boundary condition requires that the series must
terminate at some interger k2n
and the solution is
The dispersion relations do not depend on the
magnetic field!
28
?L-independence of solutions of polynomial-type
Consider a general quadratic potential
where the 3?3 matrix (?ij) is positively
definite.
Consider a polynomial solution
where Pk(r) and Qk(r) are homogeneous polynomials
of degree k.
29
Note that if Pk(r) is a polynomial of x,y,z with
degree k
is a polynomial of degree ? k-2
is a polynomial of degree ? k
Clearly, terms of even degree are decoupled from
terms of odd degree. So we may assume
Collecting terms of degree n on both sides
The obtained frequency does not depend on ?L
30
In memory of Prof. W.-J. Huang (???) A friend
and a tutor
31
Gross-Pitaeviski Hamlitonian for the spinor BEC
(Ho, Ohmi)
(gslt0 ferromagnetic gsgt0 antiferromagnetic)
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