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ISSPI: Time-dependent DFT

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Title: ISSPI: Time-dependent DFT


1
ISSPI Time-dependent DFT
Kieron Burke and friends UC Irvine Physics and
Chemistry Departments
http//dft.uci.edu
2
Recent reviews of TDDFT
To appear in Reviews of Computational Chemistry
3
Book TDDFT from Springer
4
TDDFT publications in recent years
Search ISI web of Science for topic TDDFT
  • Warning! By 2300, entire mass of universe will
    be TTDFT papers

5
Road map
  • TD quantum mechanics-gtTDDFT
  • Linear response
  • Overview of all TDDFT
  • Does TDDFT really work?
  • Complications for solids
  • Currents versus densities
  • Elastic scattering from TDDFT

6
Basic points
  • TDDFT
  • is an addition to DFT, using a different theorem
  • allows you to convert your KS orbitals into
    optical excitations of the system
  • for excitations usually uses ground-state
    approximations that usually work OK
  • has not been very useful for strong laser fields
  • is in its expansion phase Being extended to
    whole new areas, not much known about functionals
  • with present approximations has problems for
    solids
  • with currents is more powerful, but harder to
    follow
  • yields a new expensive way to get ground-state
    Exc.

7
TD quantum mechanics
8
Current and continuity
  • Current operator
  • Acting on wavefunction
  • Continuity

9
Runge-Gross theorem (1984)
  • Any given current density, j(r,t), and initial
    wavefunction, statistics, and interaction,
    theres only one external potential, vext(r,t),
    that can produce it.
  • Imposing a surface condition and using
    continuity, find also true for n(r,t).
  • Action in RG paper is WRONG
  • von Leeuwen gave a constructive proof (PRL98?)

10
TD Kohn-Sham equations
  • Time-dependent KS equations
  • Density
  • XC potential

Depends on entire history(MEMORY)
initial state(s) dependence(MEMORY)
11
Road map
  • TD quantum mechanics-gtTDDFT
  • Linear response
  • Overview of all TDDFT
  • Does TDDFT really work?
  • Complications for solids
  • Currents versus densities
  • Elastic scattering from TDDFT

12
Optical response in box
13
Excitations from DFT
  • Many approaches to excitations in DFT
  • There is no HK theorem from excited-state density
    (PRL with Rene Gaudoin)
  • Would rather have variational approach
    (ensembles, constrained search, etc.)
  • TDDFT yields a response approach, i.e, looks at
    TD perturbations around ground-state

14
TDDFT linear response
In time-dependent external field
For a given interaction and statistics HS KS
RG KS
15
Density response
where
16
Dyson-like equation
Key quantity is susceptibility
Dyson-like equation for a susceptibility
Two inputs KS susceptibility
and XC kernel
17
TDDFT linear response
  • Probe system with AC field of freq w
  • Ask at what w you find a self-sustaining response
  • Thats a transition frequency!
  • Need a new functional, the XC kernel,
    fxcr0(r,r,w)
  • Almost always ignore w-dependence (called
    adiabatic approximation)
  • Can view as corrections to KS response

18
Eigenvalue equations
Casidas matrix formulation (1996)
True transition frequencies
KS transition frequencies
Unoccupied KS orbital
Occupied KS orbital
19
Transitions in TDDFT
In this equation, fHXC is the
Hartree-exchange-correlation kernel,
, where fXC is the unknown XC kernel
20
KS susceptibility
21
How good the KS response is
22
Extracting Exc
23
Adiabatic approximation
24
Road map
  • TD quantum mechanics-gtTDDFT
  • Linear response
  • Overview of all TDDFT
  • Does TDDFT really work?
  • Complications for solids
  • Currents versus densities
  • Elastic scattering from TDDFT

25
Overview of ALL TDDFT
1. General Time-dependent Density Functional
Theory
2. TDDFT linear response to weak fields
3. Ground-state Energy from TDDFT
  • Fluctuationdissipation theorem Exc from
    susceptibility
  • Van der Waals seamless dissociation

26
Methodology for TDDFT
  • In general Propagate TDKS equations forward in
    time, and then transform the dipole moment, eg.
    Octopus code
  • Linear response Convert problem of finding
    transitions to eigenvalue problem (Casida, 1996).

27
Green fluorescent Protein
TDDFT approach for Biological Chromophores, Marque
s et al, Phys Rev Lett 90, 258101 (2003)
28
Success of TDDFT for excited states
  • Energies to within about 0.4 eV
  • Bonds to within about 1
  • Dipoles good to about 5
  • Vibrational frequencies good to 5
  • Cost scales as N2, vs N5 for CCSD
  • Available now in your favorite quantum chemical
    code

29
Naphthalene
TDDFT results for vertical singlet excitations in
Naphthalene Elliot, Furche, KB, Reviews Comp
Chem, sub. 07.
30
Road map
  • TD quantum mechanics-gtTDDFT
  • Linear response
  • Overview of all TDDFT
  • Does TDDFT really work?
  • Complications for solids
  • Currents versus densities
  • Elastic scattering from TDDFT

31
How good the KS response is
32
Quantum defect of Rydberg series
  • Iionization potential, nprincipal, langular
    quantum no.s
  • Due to long-ranged Coulomb potential
  • Effective one-electron potential decays as -1/r.
  • Absurdly precise test of excitation theory, and
    very difficult to get right.

33
Be s quantum defect expt
Top triplet, bottom singlet
34
Be s quantum defect KS
35
Be s quantum defect RPA
KStriplet
fH
RPA
36
Be s quantum defect ALDAX
37
Be s quantum defect ALDA
38
General notes
  • Most papers are lin resp, looking at excitations
    need gs potential, plus kernel
  • Rydberg excitations can be bad due to poor
    potentials (then use OEP, or be clever!).
  • Simple generalization to current TDDFT
  • Charge transfer fails, because little oscillator
    strength in KS response.
  • Double excitations lost in adiabatic
    approximation (but we can put them back in by
    hand)
  • Typically not useful in strong fields
  • Exc schemes still under development

39
Road map
  • TD quantum mechanics-gtTDDFT
  • Linear response
  • Overview of all TDDFT
  • Does TDDFT really work?
  • Complications for solids
  • Currents versus densities
  • Elastic scattering from TDDFT

40
Complications for solids and long-chain polymers
  • Locality of XC approximations implies no
    corrections to (g0,g0) RPA matrix element in
    thermodynamic limit!
  • fH (r-r) 1/r-r, but fxcALDA d(3)(r-r)
    fxcunif(n(r))
  • As q-gt0, need q2 fxc -gt constant to get effects.
  • Consequences for solids with periodic boundary
    conditions
  • Polarization problem in static limit
  • Optical response
  • Dont get much correction to RPA, missing
    excitons
  • To get optical gap right, because we expect fxc
    to shift all lowest excitations upwards, it must
    have a branch cut in w starting at EgKS

41
Two ways to think of solids in E fields
  • A Apply Esin(qx), and take q-gt0
  • Keeps everything static
  • Needs great care to take q-gt0 limit
  • B Turn on TD vector potential A(t)
  • Retains period of unit cell
  • Need TD current DFT, take w-gt0.

42
Relationship between q-gt0 and w-gt0
  • Find terms of type C/((qng)2-w2)
  • For n finite, no divergence can interchange
    q-gt0 and w-gt0 limits
  • For n0
  • if w0 (static), have to treat q-gt0 carefully to
    cancel divergences
  • if doing q0 calculation, have to do t-dependent,
    and take w-gt0 at end

43
Road map
  • TD quantum mechanics-gtTDDFT
  • Linear response
  • Overview of all TDDFT
  • Does TDDFT really work?
  • Complications for solids
  • Currents versus densities
  • Elastic scattering from TDDFT

44
TD current DFT
  • RG theorem I actually proves functional of
    j(r,t).
  • Easily generalized to magnetic fields
  • Naturally avoids Dobsons dilemma Gross-Kohn
    approximation violates Kohns theorem.
  • Gradient expansion exists, called Vignale-Kohn
    (VK).
  • TDDFT is a special case
  • Gives tensor fxc, simply related to scalar fxc
    (but only for purely longitudinal case).

45
Currents versus densities
  • Origin of current formalism Gross-Kohn
    approximation violates Kohns theorem.
  • Equations much simpler with n(r,t).
  • But, j(r,t) more general, and can have B-fields.
  • No gradient expansion in n(rt).
  • n(r,t) has problems with periodic boundary
    conditions complications for solids, long-chain
    conjugated polymers

46
Beyond explicit density functionals
  • Current-density functionals
  • VK Vignale-Kohn (96) Gradient expansion in
    current
  • Various attempts to generalize to strong fields
  • But is just gradient expansion, so rarely
    quantitatively accurate
  • Orbital-dependent functionals
  • Build in exact exchange, good potentials, no
    self-interaction error, improved gaps(?),

47
Basic problem for thermo limit
  • Uniform gas
  • Uniform gas moving with velocity v

48
Polarization problem
  • Polarization from current
  • Decompose current
  • where
  • Continuity
  • First, longitudinal case
  • Since j0(t) not determined by n(r,t), P is not!
  • What can happen in 3d case (Vanderbilt picture
    frame)?
  • In TDDFT, jT (r,t) not correct in KS system
  • So, Ps not same as P in general.
  • Of course, TDCDFT gets right (Maitra, Souza, KB,
    PRB03).

49
Improvements for solids currents
  • Current-dependence Snijders, de Boeij, et al
    improved optical response (excitons) via
    adjusted VK
  • Also yields improved polarizabilities of long
    chain conjugated polymers.
  • But VK not good for finite systems

50
Improvements for solids orbital-dependence
  • Reining, Rubio, etc.
  • Find what terms needed in fxc to reproduce
    Bethe-Salpeter results.
  • Reproduces optical response accurately,
    especially excitons, but not a general
    functional.
  • In practice, folks use GW susceptibility as
    starting point, so dont need effective fxc to
    have branch cut

51
Our recent work
  • Floquet theory
  • Double excitations
  • Understanding how it works
  • Single- and Double-pole approximations
  • X-ray spectra
  • Rydberg series from LDA potential
  • Quantum defects
  • Errors in DFT for transport
  • TDDFT for open systems
  • Elastic electron-atom scattering

52
Road map
  • TD quantum mechanics-gtTDDFT
  • Linear response
  • Overview of all TDDFT
  • Does TDDFT really work?
  • Complications for solids
  • Currents versus densities
  • Elastic scattering from TDDFT

53
Elastic scattering from TDDFT
  • Huge interest in low energy scattering from
    biomolecules, since resonances can lead to
    cleavage of DNA
  • Traditional methods cannot go beyond 13 atoms
  • Can we use TDDFT? Yes!

54
Simple scheme for spherical case
  • Eg e- scattering from H.
  • Put H- into spherical box, and consider Egt0
    states.
  • Old formula due to Fano (1935)
  • Exact for any Rb beyond potential.

55
Is KS a good starting place?
56
Is the LDA potential good enough?
57
TDDFT corrections
58
Summary
  • TDDFT is different from DFT
  • Linear response TDDFT turns KS orbital
    differences into single optical excitations
  • Value is in semi-quantitative spectra
  • Can help determine geometry
  • Identify significant excitations
  • Troubles with strong fields
  • Troubles with solids
  • Current- or orbital-dependence are promising
    alternatives for solids and long-chain polymers
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