Mathematical Analysis and Numerical Simulation for Bose-Einstein Condensation

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Mathematical Analysis and Numerical Simulation for Bose-Einstein Condensation

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Title: Mathematical Analysis and Numerical Simulation for Bose-Einstein Condensation

1
Mathematical Analysis and Numerical
Simulation for Bose-Einstein Condensation

Weizhu Bao
Department of Mathematics
Center of Computational Science and Engineering
National University of Singapore
Email bao_at_math.nus.edu.sg
URL http//www.math.nus.edu.sg/bao

2
Collaborators

External
P.A. Markowich, Institute of Mathematics,
University of Vienna, Austria
D. Jaksch, Department of Physics, Oxford
University, UK
Q. Du, Department of Mathematics, Penn State
University, USA
J. Shen, Department of Mathematics, Purdue
University, USA
L. Pareschi, Department of Mathematics,
University of Ferarra, Italy
I-Liang Chern, Department of Mathematics,
National Taiwan University, Taiwan
C. Schmeiser R.M. Weishaeupl, University of
Vienna, Austria
W. Tang L. Fu, Beijing Institute of Appl. Phys.
Comput. Math., China
Internal
Yanzhi Zhang, Hanquan Wang, Fong Ying Lim, Ming
Huang Chai
Yunyi Ge, Fangfang Sun, etc.

3
Outline

Part I Predication Mathematical modeling
Theoretical predication
Physical experiments and results
Applications
Gross-Pitaevskii equation
Part II Analysis Computation for Ground states
Existence uniqueness
Energy asymptotics asymptotic approximation
Numerical methods
Numerical results

4
Outline

Part III Analysis Computation for Dynamics in
BEC
Dynamical laws
Numerical methods
Vortex stability interaction
Part IV Rotating BEC multi-component BEC
BEC in a rotational frame
Two-component BEC
Spinor BEC
BEC at finite temperature
Conclusions Future challenges

5
Part I

Predication
Mathematical modeling

6
Theoretical predication

Particles be divided into two big classes
Bosons photons, phonons, etc
Integer spin
Like in same state many can occupy one obit
Sociable gregarious
Fermions electrons, neutrons, protons etc
Half-integer spin each occupies a single obit
Loners due to Pauli exclusion principle

7
Theoretical predication

For atoms, e.g. bosons
Get colder
Behave more like waves less like particles
Very cold
Overlap with their neighbors
Extremely cold
Most atoms behavior in the same way, i.e
gregarious
quantum mechanical ground state,
super-atom new matter of wave fifth state

8
Theoretical predication

S.N. Bose Z. Phys. 26 (1924)
Study black body radiation object very hot
Two photons be counted up as either identical or
different
Bose statistics or Bose-Einstein statistics
A. Einstein Sitz. Ber. Kgl. Preuss. Adad. Wiss.
22 (1924)
Apply the rules to atoms in cold temperatures
Obtain Bose-Einstein distribution in a gas

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Experimental results

JILA (95, Rb, 5,000) Science 269 (1995)

Anderson et al., Science, 269 (1995),
198 JILA Group Rb
Davis et al., Phys. Rev. Lett., 75 (1995),
3969 MIT Group Rb
Bradly et al., Phys. Rev. Lett., 75 (1995),
1687, Rice Group Li

12
Experimental results

Experimental implementation
JILA (95) First experimental realization of BEC
in a gas
NIST (98) Improved experiments
MIT, ENS, Rice,
ETH, Oxford,
Peking U.,
2001 Nobel prize in physics
C. Wiemann U. Colorado
E. Cornell NIST
W. Ketterle MIT

ETH (02, Rb, 300,000)
13
Experimental difficulties

Low temperatures ? absolutely zero (nK)
Low density in a gas

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Experimental techniques

Laser cooling
Magnetic trapping
Evaporative Cooling

(100k300k)
15
Possible applications

Quantized vortex for studying superfluidity
Test quantum mechanics theory
Bright atom laser multi-component
Quantum computing
Atom tunneling in optical lattice trapping, ..

Square Vortex lattices in spinor BECs
Vortex latticedynamics
Giant vortices
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Mathematical modeling

N-body problem
(3N1)-dim linear Schroedinger equation
Mean field theory
Gross-Pitaevskii equation (GPE)
(31)-dim nonlinear Schroedinger equation (NLSE)
Quantum kinetic theory
High temperature QBME (331)-dim
Around critical temperature QBMEGPE
Below critical temperature GPE

17
Gross-Pitaevskii equation (GPE)

Physical assumptions
At zero temperature
N atoms at the same hyperfine species (Hartree
ansatz)
The density of the trapped gas is small
Interatomic interaction is two-body elastic and
in Fermi form

18
Second Quantization model

The second quantized Hamiltonian
A gas of bosons are condensed into the same
single-particle state
Interacting by binary collisions
Contained by an external trapping potential

19
Second quantization model

Crucial Bose commutation rules
Atomic interactions are low-energy two-body
s-wave collisions, i.e. essentially elastic
hard-sphere collisions
The second quantized Hamiltonian

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Second quantization model

The Heisenberg equation for motion
For a single-particle state with macroscopic
occupation
Plugging, taking only the leading order term
neglecting the fluctuation terms (i.e., thermal
and quantum depletion of the condensate)
Valid only when the condensate is
weakly-interacting low tempertures

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Gross-Pitaevskii equation

The Schrodinger equation (Gross, Nuovo. Cimento.,
61 Pitaevskii, JETP,61 )
The Hamiltonian
The interaction potential is taken as in Fermi
form

22
Gross-Pitaevskii equation

The 3d Gross-Pitaevskii equation (
)
V is a harmonic trap potential
Normalization condition

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Gross-Pitaevskii equation

Scaling (w.l.o.g. )
Dimensionless variables
Dimensionless Gross-Pitaevskii equation
With

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Gross-Pitaevskii equation

Typical parameters ( )
Used in JILA
Used in MIT

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Gross-Pitaevskii equation

Reduction to 2d (disk-shaped condensation)
Experimental setup
Assumption No excitations along z-axis due to
large energy
2d Gross-Pitaevskii equation (
)

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Numerical Verification
27
Numerical Results
Bao, Y. Ge, P. Markowich R. Weishaupl, 06
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Gross-Pitaevskii equation

General form of GPE ( )
with
Normalization condition

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Gross-Pitaevskii equation

Two kinds of interaction
Repulsive (defocusing) interaction
Attractive (focusing) interaction
Two extreme regimes
Weakly interacting condensation
Strongly repulsive interacting condensation

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Gross-Pitaevskii equation

Conserved quantities
Normalization of the wave function
Energy
Chemical potential

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Semiclassical scaling

When , re-scaling
With
Leading asymptotics (Bao Y. Zhang, Math. Mod.
Meth. Appl. Sci., 05)

32
Quantum Hydrodynamics

Set
Geometrical Optics (Transport
Hamilton-Jacobi)
Quantum Hydrodynamics (QHD) (Euler 3rd
dispersion)

33
Part II

Analysis Computation
for
Ground states

34
Stationary states

Stationary solutions of GPE
Nonlinear eigenvalue problem with a constraint
Relation between eigenvalue and eigenfunction

35
Stationary states

Equivalent statements
Critical points of over the
unit sphere
Eigenfunctions of the nonlinear eigenvalue
problem
Steady states of the normalized gradient
flow(Bao Q. Du, SIAM J. Sci. Compu., 03)
Minimizer/saddle points over the unit sphere
For linear case (Bao Y. Zhang,
Math. Mod. Meth. Appl. Sci., 05)
Global minimizer vs saddle points
For nonlinear case
Global minimizer, local minimizer (?) vs saddle
points

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Ground state

Ground state
Existence and uniqueness of positive solution
Lieb et. al., Phys. Rev. A, 00
Uniqueness up to a unit factor
Boundary layer width matched asymptotic
expansion
Bao, F. Lim Y. Zhang, Trans. Theory Stat.
Phys., 06

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Excited central vortex states

Excited states
Central vortex states
Central vortex line states in 3D
Open question (Bao W. Tang, JCP, 03 Bao, F.
Lim Y. Zhang, TTSP, 06)

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Approximate ground states

Three interacting regimes
No interaction, i.e. linear case
Weakly interacting regime
Strongly repulsive interacting regime
Three different potential
Box potential
Harmonic oscillator potential
BEC on a ring or torus

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Energies revisited

Total energy
Kinetic energy
Potential energy
Interaction energy
Chemical potential

40
Box Potential in 1D

The potential
The nonlinear eigenvalue problem
Case I no interaction, i.e.
A complete set of orthonormal eigenfunctions

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Box Potential in 1D

Ground state its energy
j-th-excited state its energy
Case II weakly interacting regime, i.e.
Ground state its energy
j-th-excited state its energy

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Box Potential in 1D

Case III Strongly interacting regime, i.e.
Thomas-Fermi approximation, i.e. drop the
diffusion term
Boundary condition is NOT satisfied, i.e.
Boundary layer near the boundary

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Box Potential in 1D

Matched asymptotic approximation
Consider near x0, rescale
We get
The inner solution
Matched asymptotic approximation for ground state

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Box Potential in 1D

Approximate energy
Asymptotic ratios
Width of the boundary layer

Numerical observations

46
Box Potential in 1D

Matched asymptotic approximation for excited
states
Approximate chemical potential energy

47
Fifth excited states
48
Energy Chemical potential
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Box potential in 1D

Boundary layers interior layers with width
Observations energy chemical potential are in
the same order
Asymptotic ratios
Extension to high dimensions

50
Harmonic Oscillator Potential in 1D

The potential
The nonlinear eigenvalue problem
Case I no interaction, i.e.
A complete set of orthonormal eigenfunctions

51
Harmonic Oscillator Potential in 1D

Ground state its energy
j-th-excited state its energy
Case II weakly interacting regime, i.e.
Ground state its energy
j-th-excited state its energy

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Harmonic Oscillator Potential in 1D

Case III Strongly interacting regime, i.e.
Thomas-Fermi approximation, i.e. drop the
diffusion term
Characteristic length
It is NOT differentiable at
The energy is infinite by direct definition

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Harmonic Oscillator Potential in 1D

A new way to define the energy
Asymptotic ratios

Numerical observations

55
Harmonic Oscillator Potential in 1D

Thomas-Fermi approximation for first excited
state
Jump at x0!
Interior layer at x0

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Harmonic Oscillator Potential in 1D

Matched asymptotic approximation
Width of interior layer
Ordering

57
Harmonic Oscillator Potential

Extension to high dimensions
Identity of energies for stationary states in
d-dim.
Scaling transformation
Energy variation vanishes at first order in

58
BEC on a ring

The potential
The nonlinear eigenvalue problem
For linear case, i.e.
A complete set of orthonormal eigenfunctions

59
BEC on a ring

Ground state its energy
j-th-excited state its energy
Some properties
Ground state its energy
With a shift
Interior layer can be happened at any point in
excited states

60
Numerical methods for ground states

Runge-Kutta method (M. Edwards and K. Burnett,
Phys. Rev. A, 95)
Analytical expansion (R. Dodd, J. Res. Natl.
Inst. Stan., 96)
Explicit imaginary time method (S. Succi, M.P.
Tosi et. al., PRE, 00)
Minimizing by FEM (Bao W. Tang, JCP,
02)
Normalized gradient flow (Bao Q. Du, SIAM Sci.
Comput., 03)
Backward-Euler finite difference (BEFD)
Time-splitting spectral method (TSSP)
Gauss-Seidel iteration method (W.W. Lin et al.,
JCP, 05)
Spectral method stabilization (Bao, I. Chern
F. Lim, JCP, 06)

61
Imaginary time method

Idea Steepest decent method Projection
Physical institutive in linear case
Solution of GPE
Imaginary time dynamics

62
Mathematical justification

For gradient flow (Bao Q. Du, SIAM Sci.
Comput., 03)
For linear case (Bao Q. Du, SIAM Sci.
Comput., 03)
For nonlinear case ???

63
Mathematical justification
64
Normalized gradient glow

Idea (Bao Q. Du, SIAM Sci. Comput., 03)
The projection step is equivalent to solve an ODE
Gradient flow with discontinuous coefficients
Letting time step go to 0
Mass conservation Energy diminishing

65
Fully discretization

Consider in 1D
Different Numerical Discretizations
Physics literatures Crank-Nicolson FD or Forward
Euler FD
BEFD Energy diminishing monotone (Bao Q.
Du, SIAM Sci. Comput., 03)
TSSP Spectral accurate with splitting error (Bao
Q. Du, SIAM Sci. Comput., 03)
BESP Spectral accuracy in space stable (Bao,
I. Chern F. Lim, JCP, 06)
Crank-Ncolson FD for normalized gradient flow

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Backward Euler Finite Difference

Mesh and time steps
BEFD discretization
2nd order in space unconditional stable at each
step, only a linear system with sparse matrix to
be solved!

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Backward Euler Spectral method

Discretization
Spectral order in space efficient accurate

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Ground states

Numerical results (BaoW. Tang, JCP, 03 Bao, F.
Lim Y. Zhang, TTSP, 06)
In 1d
Box potential
Ground state excited states first fifth
Harmonic oscillator potential
ground first excited Energy and chemical
potential
Double well potential
Ground first excited state
Optical lattice potential
Ground first excited state with potential

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Ground states

Numerical results (BaoW. Tang, JCP, 03 Bao, F.
Lim Y. Zhang, TTSP, 06)
In 2d
Harmonic oscillator potentials
ground
Optical lattice potential
Ground excited states
In 3D
Optical lattice potential
ground excited states

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Part III

Analysis Computation
for
Dynamics in BEC

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Dynamics of BEC

Time-dependent Gross-Pitaevskii equation
Dynamical laws
Time reversible time transverse invariant
Mass energy conservation
Angular momentum expectation
Condensate width
Dynamics of a stationary state with its center
shifted

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Angular momentum expectation

Definition
Lemma Dynamical laws (Bao Y. Zhang, Math.
Mod. Meth. Appl. Sci, 05)
For any initial data, with symmetric trap, i.e.
, we have
Numerical test next

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Angular momentum expectation
Energy
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Dynamics of condensate width

Definition
Dynamic laws (Bao Y. Zhang, Math. Mod. Meth.
Appl. Sci, 05)
When for any initial data
When with initial data
Numerical Test
For any other cases

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Symmetric trap
Anisotropic trap
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Dynamics of Stationary state with a shift

Choose initial data as
The analytical solutions is (Garcia-Ripoll el
al., Phys. Rev. E, 01)
In 2D
In 3D, another ODE is added

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Solution of the center of mass

Center of mass Bao Y. Zhang, Appl. Numer.
Math., 2006
In a non-rotating BEC
Trajectory of the center Motion
of the solution
Pattern Classification
Each component of the center is a periodic
function
In a symmetric trap, the trajectory is a straight
segment
If is a rational , the center
moves periodically with period
If is an irrational , the
center moves chaotically, envelope is a rectangle

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Numerical methods for dynamics

Lattice Boltzmann Method (Succi, Phys. Rev. E,
96 Int. J. Mod. Phys., 98)
Explicit FDM (Edwards Burnett et al., Phys.
Rev. Lett., 96)
Particle-inspired scheme (Succi et al., Comput.
Phys. Comm., 00)
Leap-frog FDM (Succi Tosi et al., Phys. Rev. E,
00)
Crank-Nicolson FDM (Adhikari, Phys. Rev. E 00)
Time-splitting spectral method (Bao,
JakschMarkowich, JCP, 03)
Runge-Kutta spectral method (Adhikari et al., J.
Phys. B, 03)
Symplectic FDM (M. Qin et al., Comput. Phys.
Comm., 04)

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Time-splitting spectral method (TSSP)

Time-splitting
For non-rotating BEC
Trigonometric functions (Bao, D. Jaksck P.
Markowich, J. Comput. Phys., 03)
Laguerre-Hermite functions (Bao J. Shen, SIAM
Sci. Comp., 05)

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Time-splitting spectral method
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Properties of TSSP

Explicit, time reversible unconditionally
stable
Easy to extend to 2d 3d from 1d efficient due
to FFT
Conserves the normalization
Spectral order of accuracy in space
2nd, 4th or higher order accuracy in time
Time transverse invariant
Optimal resolution in semicalssical regime

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Dynamics of Ground states

1d dynamics
2d dynamics of BEC (Bao, D. Jaksch P.
Markowich, J. Comput. Phys., 03)
Defocusing
Focusing (blowup)
3d collapse and explosion of BEC (Bao, Jaksch
Markowich,J. Phys B, 04)
Experiment setup leads to three body
recombination loss
Numerical results
Number of atoms , central density Movie

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Collapse and Explosion of BEC
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Number of atoms in condensate
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Central density
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Central quantized vortices

Central vortex states in 2D
with
Vortex Dynamics
Dynamical stability
Interaction
Pattern I
Pattern II

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Central Vortex states
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Central Vortex states
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Vortex stability interaction

Dynamical stability (Bao Y. Zhang, Math. Mod.
Meth. Appl. Sci., 05)
m1 stable velocity
m2 unstable velocity
Interaction (Bao Y. Zhang, Math. Mod. Meth.
Appl. Sci., 05)
N2 Pair velocity trajectory phase
phase2
Anti-pair phase trajectory
angular trajectory2
N3 velocity trajectory
Pattern II Linear nonlinear
Interaction laws
On-going with Prof. L. Fu Miss Y. Zhang

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Linear case
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Noninear case BEC
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Linear case
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Linear case
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Linear case
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Some Open Questions

Dynamical laws for vortex interaction
With a quintic damping, mass goes to constant
Convergence error estimate of the TSSP?
Energy diminishing of the gradient flow in
nonlinear case error estimate ?

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Part IV

Rotating BEC
multi-component BEC

127
Rotating BEC

The Schrodinger equation (
)
The Hamiltonian
The interaction potential is taken as in Fermi
form

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Rotating BEC

The 3D Gross-Pitaevskii equation (
)
Angular momentum rotation
V is a harmonic trap potential
Normalization condition

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Rotating BEC

General form of GPE ( )
with
Normalization condition

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Rotating BEC

Conserved quantities
Normalization of the wave function
Energy
Chemical potential

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Semiclassical scaling

When , re-scaling
With
Leading asymptotics

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Quantum Hydrodynamics

Set
Geometrical Optics (Transport
Hamilton-Jacobi)
Quantum Hydrodynamics (QHD) (Euler 3rd
dispersion)

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Stationary states

Stationary solutions of GPE
Nonlinear eigenvalue problem with a constraint
Relation between eigenvalue and eigenfunction

134
Stationary states

Equivalent statements
Critical points of over the
unit sphere
Eigenfunctions of the nonlinear eigenvalue
problem
Steady states of the normalized gradient flow
Minimizer/saddle points over the unit sphere
For linear case
Global minimizer vs saddle points
For nonlinear case
Global minimizer, local minimizer (?) vs saddle
points

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Ground state

Ground state
Existence
Seiringer (CMP, 02)
Uniqueness of positive solution
Lieb et al. (PRA, 00)
Energy bifurcation
Aftalion Du (PRA, 01) B., Markowich Wang 04

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Numerical results

Ground states
in 2D in 3D
isosurface
Quantized vortex generation in 2D
surface contour
Vortex lattice
Symmetric trapping anisotropic trapping
Giant vortex generation in 2D
surface contour
Giant vortex
In 2D In 3D

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Numerical Asymptotical results

Critical angular frequency symmetric state vs
quantized vortex state
Asymptotics of the energy
Ratios between energies of different states
Rank according to energy and chemical potential
Stationary states are ranked according to their
energy, then their chemical potential are in the
same order. Next

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Dynamical laws of rotating BEC

Time-dependent Gross-Pitaevskii equation
Dynamical laws
Time reversible time transverse invariant
Conservation laws
Angular momentum expectation
Condensate width
Dynamics of a stationary state with its center
shifted

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Conservation laws

Conserved quantities
Normalization of the wave function
Energy
Chemical potential

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Angular momentum expectation

Definition
Lemma The dynamics of satisfies
For any initial data, with symmetric trap, i.e.
, we have
Numerical test
next
Bao, Du Zhang, SIAM J. Appl. Math., 66 (2006),
758

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Angular momentum expectation
Energy
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Dynamics of condensate width

Definition Bao, Du Zhang, SIAM J. Appl.
Math., 66 (2006), 758
Dynamic laws
When for any initial data
When with initial data
Numerical Test
For any other cases

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Symmetric trap
Anisotropic trap
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Dynamics of Stationary state with a shift

Choose initial data as
The analytical solutions is Bao, Du Zhang,
SIAM J. Appl.Math., 2006
In 2D
In 3D, another ODE is added

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Solution of the center of mass

Center of mass Bao Zhang, Appl. Numer. Math.,
2006
In a non-rotating BEC
Pattern Classification
Each component of the center is a periodic
function
In a symmetric trap, the trajectory is a straight
segment
If is a rational , the center
moves periodically with period
If is an irrational , the
center moves chaotically, envelope is a rectangle

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Solution of the center of mass

In a rotating BEC with a symmetric trap
Trajectory of the center
Distance between the center and trapping center
Motion of the solution 0.5 1 2
4
Pattern Classification

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1/5, 4/5, 1
3/2, 6, Pi
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Pattern Classification

Pattern Classification Bao Zhang, Appl. Numer.
Math., 2006
The distance between the center and trap center
is periodic function
When is a rational
The center moves periodically
The graph of the trajectory is unchanged under a
rotation
When is an irrational ,
The center moves chaotically
The envelope of the trajectory is a circle
The solution of GPE agrees very well with those
from the ODE system

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Solution of the center of mass

In a rotating BEC with an anisotropic trap
When
results
The trajectory is a spiral coil to infinity
The trajectory is an ellipse
Otherwise result1
result2
The center moves chaotically graph is a bounded
set
The center moves along a straight line to
infinity

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Total density with dissipation

Time-dependent Gross-Pitaevskii equation
Lemma The dynamics of total density satisfies
The total density decreases when
density function
energy next

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Numerical Methods

Time-splitting pseudo-spectral method (TSSP)
Use polar coordinates (B., Q. Du Y. Zhang, SIAP
06)
Time-splitting ADI technique (B. H. Wang,
JCP, 06)
Generalized Laguerre-Hermite functions (B., J.
Shen H. Wang, 06)

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Numerical methods for rotating BEC

Numerical Method one (Bao, Q. Du Y. Zhang,
SIAM, Appl. Math. 06)
Ideas
Time-splitting
Use polar coordinates angular momentum becomes
constant coefficient
Fourier spectral method in transverse direction
FD or FE in radial direction
Crank-Nicolson in time
Features
Time reversible
Time transverse invariant
Mass Conservation in discretized level
Implicit in 1D efficient to solve
Accurate unconditionally stable

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Numerical methods for rotating BEC

Numerical Method two (Bao H. Wang, J. Comput.
Phys. 06)
Ideas
Time-splitting
ADI technique Equation in each direction become
constant coefficient
Fourier spectral method
Features
Time reversible
Time transverse invariant
Mass Conservation in discretized level
Explicit unconditionally stable
Spectrally accurate in space

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Dynamics of ground state

Choose initial data as
ground state
Change the frequency in the external potential
Case 1 symmetric
surface contour
Case 2 non-symmetric
surface contour
Case 3 dynamics of a vortex lattice with 45
vortices
image contour
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Interaction of two vortices in linear
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Interaction of two vortices in linear
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Interaction of two vortices in linear
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Interaction of vortices in nonlinear
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Interaction of vortices in nonlinear
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Interaction of vortices in nonlinear
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Interaction of vortices in nonlinear
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Some Open Questions

Dynamical laws for vortex interaction
With a quintic damping, mass goes to constant
Semiclassical limit when initial data has
vortices???
Vortex line interaction laws, topological change?
What is a giant vortex?

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Two-component BEC

The 3D coupled Gross-Pitaevskii equations
Normalization conditions
Intro- inter-atom Interactions

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Two-component BEC

Nondimensionalization
Normalization conditions
There is external driven field
No external driven field

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Two-component BEC

Energy
Reduction to one-component

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Two-Component BEC

Semiclassical scaling
Semiclassical limit
No external field
WKB expansion, two-fluid model
With external field
WKB expansion doesnt work, Winger transform

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Ground state

No external field
Nonlinear eigenvalue problem
Existence uniqueness of positive solution
Numerical methods can be extended

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Ground states
crater
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Ground state

With external field
Nonlinear eigenvalue problem
Existence uniqueness of positive solution ???
Numerical methods can be extended????

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Dynamics

Dynamical laws
Conservation of Angular momentum expectation
Dynamics of condensate width
Dynamics of a stationary state with a shift
Dynamics of mass of each component, they are
periodic function when
Vortex can be interchanged!
Numerical methods
Time-splitting spectral method

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Dynamics
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Dynamics
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Spinor BEC

Spinor F1 BEC
With

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Spinor BEC

Total mass conservation
Total magnetization conservation
Energy conservation

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Spinor BEC

Dimension reduction
Ground state
Existence uniqueness of positive solution??
Numerical methods ???
Dynamics
Dynamical laws
Numerical methods TSSP
Semiclassical limit hydrodynamics equation??

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BEC at Finite Temperature

Condensate coexists with non-condensed thermal
cloud
Coupled equations of motion for condensate and
thermal cloud
Mean-field theory in collisionless regime
ZGN theory in collision dominated regime

208
Mean-field Theory

Evolution of quantum field operator
where is the annihilation field
operator
and is the creation field
operator
Mean-field description
Condensate wavefunction

209
Mean-field Theory

Generalized GPE for condensate wavefunction
Temperature-dependent fluctuation field for
non-condensate

210
Hartree-Fock Bogoliubov Theory

Ignore the three-field correlation function
Bogoliubov transformation
where creates (annihilates) a
Bogoliubov quasiparticle of energy ej
The quasiparticles are non-interacting

211
Hartree-Fock Bogoliubov Theory

Bogoliubov equations for non-condensate
where

212
Time-independent Hartree-Fock Bogoliubov Theory

Stationary states
Time-independent generalized GPE and Bogoliubov
equations

213
HFB-Popov Approximation

HFB produces an energy gap in the excitation
spectrum
Solution leave out
Generalized GPE and Bogoliubov equations within
Popov approximation (gapless spectrum)

214
Hartree-Fock Approximation

Approximate Bogoliubov excitations with
single-particle excitations, i.e. let
Restricted to finite temperature close to Tc,
where the non-condensed particles have higher
energies

215
ZGN Theory

Mean-field theory deals with BEC in collisionless
region (low density thermal cloud)
l gtgt l
l is the collisonal mean-free-path of excited
particles
l is the wavelength of excitations
In collision-dominated region l ltlt l (higher
density thermal cloud), the problem becomes
hydrodynamic in nature
ZGN theory (E. Zaremba, A. Griffin, T. Nikuni,
1999) describes finite-T BEC with interparticle
collisions in the semi-classical limit
kBT gtgt hw0 (w0 trap frequency)
kBT gtgt gn

216
ZGN Theory

Apply Popov approximation (ignore ) but
include the three-field correlation function
GPE for condensate wavefunction
Quantum Boltzmann equation for phase-space
distribution function of non-condensate

217
ZGN Theory

Thermal cloud density
Collision between condensate and non-condensate
-- transfer atoms from/to the condensate
Collision between non-condensate particles

218
ZGN Theory

Energy of condensate atoms
Local chemical potential
Superfluid velocity
Energy of non-condensate atoms Hartree-Fock
energy
Limited to high temperature (close to Tc)
For lower temperature, the spectrum of excited
atoms should be described by Bogoliubov
approximation

219
Open questions