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Continuum Mechanics of Quantum Many-Body Systems

New Approaches in Many-Electron Theory Mainz, September 20-24, 2010. Continuum Mechanics of Quantum Many-Body Systems. J. Tao 1,2 , X. Gao 1,3 , G. Vignale 2 , I. V. Tokatly 4. Los Alamos National Lab 2. University of Missouri-Columbia 3. Zhejiang Normal University, China

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Continuum Mechanics of Quantum Many-Body Systems

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  1. New Approaches in Many-Electron Theory Mainz, September 20-24, 2010 Continuum Mechanics of Quantum Many-Body Systems J. Tao1,2, X. Gao1,3, G. Vignale2, I. V. Tokatly4 • Los Alamos National Lab • 2. University of Missouri-Columbia • 3. Zhejiang Normal University, China • 4. Universidad del Pais Vasco

  2. F Continuum Mechanics: what is it? An attempt to describe a complex many-body system in terms of a few collective variables -- density and current -- without reference to the underlying atomic structure. Classical examples are “Hydrodynamics” and “Elasticity”. Elasticity r0 displacement field

  3. Can continuum mechanics be applied to quantum mechanical systems? In principle, yes! Hamiltonian: Heisenberg Equations of Motion: Local conservation of particle number Local conservation of momentum The Runge-Gross theorem asserts that P(r,t) is a unique functional of the current density (and of the initial quantum state) -- thus closing the equations of motion.

  4. Equilibrium of Quantum Mechanical Systems 2s 1s F + J. Tao, GV, I.V. Tokatly,PRL 100, 206405 (2008) The two components of the stress tensor Kohn-Sham orbitals Density

  5. Pressure and shear forces in atoms pressure shear

  6. Continuum mechanics in the linear response regime Yn, En “Linear response regime” means that we are in a non-stationary state that is “close” to the ground-state, e.g. Y2, E2 Y1, E1 Y0, E0 The displacement field associated with this excitation is the expectation value of the current in Yn0 divided by the ground-state density n0 and integrated over time

  7. Continuum mechanics in the linear response regime - continued Excitation energies in linear continuum mechanics are obtained by Fourier analyzing the displacement field However, the correspondence between excited states and displacement fields can be many-to-one. Different excitations can have the same displacement fields (up to a constant). This implies that the equation for the displacement field, while linear, cannot be rigorously cast as a conventional eigenvalue problem. Excitations Displacement fields Y0, E0

  8. Continuum Mechanics – Lagrangian formulation I. V. Tokatly, PRB 71, 165104 & 165105 (2005); PRB 75, 125105 (2007) Make a change of coordinates to the “comoving frame” -- an accelerated reference frame that moves with the electron liquid so that the density is constant and the current density is zero everywhere. Wave function in Lagrangian frame Hamiltonian in Lagrangian frame Euclidean space Curved space Generalized force

  9. Continuum Mechanics: the Elastic Approximation The elastic equation of motion Assume that the wave function in the Lagrangian frame is time-independent - the time evolution of the system being entirely governed by the changing metric. We call this assumption the “elastic approximation”. This gives... Y0[u] is the deformed ground state wave function: The elastic approximation is expected to work best in strongly correlated systems, and is fully justified for (1) High-frequency limit (2) One-electron systems. Notice that this is the opposite of an adiabatic approximation.

  10. Elastic equation of motion: an elementary derivation Start from the equation for the linear response of the current: Inverting Eq. (1) to first order we get Finally, using and go to the high frequency limit:

  11. Elastic equation of motion: a variational derivation The variational Ansatz density operator current density operator phase displacement ground-state The Lagrangian The Euler-Lagrange equations of motion This approach is easily generalizable to include static magnetic fields.

  12. The elastic equation of motion: discussion 1. The linear functional F[u] is calculable from the exact one- and two body density matrices of the ground-state. The latter can be obtained from Quantum Monte Carlo calculations. 2. The eigenvalue problem is hermitian and yields a complete set of orthonormal eigenfunction. Orthonormality defined with respect to a modified scalar product with weight n0(r). 3. The positivity of the eigenvalues (=excitation energies) is guaranteed by the stability of the ground-state 4. All the excitations of one-particle systems are exactly reproduced.

  13. Exact excitation energies A group of levels may collapse into one but the spectral weight is preserved within each group! Elastic QCM The sum rule Let ul(r) be a solution of the elastic eigenvalue problem with eigenvalue wl2. The following relation exists between wl2 and the exact excitation energies: Oscillator strength rigorously satisfied in 1D systems f-sum rule

  14. Example 1: Homogeneous electron gas TRANSVERSAL LONGITUDINAL static structure factor 1 particle excitations Similar, but not identical to Bijl-Feynman theory: wL Multiparticle excitations w/EF Plasmon frequency wT Multiparticle excitations wp q/kF

  15. Example 2 Elastic equation of motion for 1-dimensional systems a fourth-order integro-differential equation From Quantum Monte Carlo

  16. Eigenvalues: Eigenfunctions: Eigenvalues: Eigenfunctions: A. Linear Harmonic Oscillator This equation can be solved analytically by expanding u(x) in a power series of x and requiring that the series terminates after a finite number of terms (thus ensuring zero current at infinity). B. Hydrogen atom (l=0)

  17. C. Two interacting particles in a 1D harmonic potential – Spin singlet n,m non-negative integers Parabolic trap WEAK CORRELATION w0>>1 STRONG CORRELATION w0<<1 n0(x) n0(x)

  18. Evolution of exact excitation energies E/w0 Breathing mode Kohn’s mode WEAK CORRELATION STRONG CORRELATION

  19. Exact excitation energies (lines) vs QCM energies (dots) (5,0) (3,1) (1,2) (4,0) 3.94 (2,1) (0,2) (3,0) 2.63 E/w0 (1,1) (2,0) (0,1) (1,0) WEAK CORRELATION STRONG CORRELATION

  20. Strong Correlation Limit even odd States with the same n+m and the same parity of m have identical displacement fields. At the QCM level they collapse into a single mode with energy (1,2) (0,2) 3.46 3.94 2.63 (3,0) (2,0) 3 2 4.46

  21. (1,0) even (1,1) (3,0),(1,2)

  22. (0,1) odd (0,2)(2,0) (2,1)(0,3)

  23. Other planned applications Periodic system: Replace bands of single –particle excitations by bands of collective modes Luttinger liquid in a harmonic trap 3D scattering length radius of tube

  24. Conclusions and speculations I • Our Quantum Continuum Mechanics is a direct extension of the collective approximation (“Bijl-Feynman”) for the homogeneous electron gas to inhomogeneous quantum systems. We expect it to be useful for - The theory of dispersive Van derWaals forces, especially in complex geometries - Possible nonlocal refinement of the plasmon pole approximation in GW calculations • Studying dynamics in the strongly correlated regime, which is dominated by a collective response (e.g., collective modes in the quantum Hall regime)

  25. Conclusions and speculations II • As a byproduct we got an explicit analytic representation of the exact xc kernel in the high-frequency (anti-adiabatic) limit • This kernel should help us to study an importance of the space and time nonlocalities in the KS formulation of time-dependent CDFT. • It is interesting to try to interpolate between the adiabatic and anti-adiabatic extremes to construct a reasonable frequency-dependent functional

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