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Page 1: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Real-space Green's function approach for electronic, vibrational and optical properties

J. J. RehrDepartment of Physics,

University of WashingtonSeattle, WA, USA

Supported by DOE BES and NIST

Excitations in Condensed Matter: From Basic Concepts to Real Materials

KITP, UCSB October 5, 2009 - December 18, 2009

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Real-space Green's function approach

• GOAL: ab initio theory of electronic, vibrational, and optical properties

• “Pretty good theory”• Broad spectrum VIS – X-ray• Accuracy ~ experiment

• TALK:I. RSGF approachII. Parameter free theory No adjustable parameters

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”The chance is high that the truth lies in thefashionable direction. But on the off chance that it isn’t, who will find it?”

R. P. Feynman

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Experiment vs Theory: Full spectrumOptical - X-ray Absorption Spectra

Photon energy (eV)

fcc Al

UV X-ray

http://leonardo.phys.washington.edu/feff/opcons

RSGF theory vs

expt

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J. J. Rehr & R.C. AlbersRev. Mod. Phys. 72, 621 (2000)

http://leonardo.phys.washington.edu/feff/

I. RSGF Approach

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Physical Considerations in XAS

X-ray energy ω (eV)

XANES EXAFS

EF

XANES EXAFSKE: low HighScattering: Strong weakMFP: long ShortDamping: weak StrongRange: LRO (k-space) SRO (real-space)

ωp

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Key Many body effects in XAS

● Self-energy Σ(E) complex● Core-hole effects ? Screening ?

● Debye-Waller factors e-2σ2 k2

● Multi-electron excitations satellites

Σquasi-particle & beyond

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Ground-state vs Quasiparticle vs Expt

Quasiparticle Theory Essential

Cu

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Conventional Quasi-particle Theory of XAS

Fermi Golden Rule for XAS μ(ω)

Quasi-particle final states ψf with core hole

Final state hamiltonianV′coul = Vcoul + Vcore−hole

Non-hermitian Self-energy Σ(E) (replaces Vxc)

Inelastic Mean free paths λ= k/|Im Σ(E)| ≈ 5 − 20 Å

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Green’s functions vs Wave-functions

Golden rule via Green’s Functions G = 1/( E – h – Σ )

Golden rule via Wave Functions

Ψ

Paradigm shift:

Efficient! No sums over final states

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Connection with Electronic Structure

• Spectral function ρ(E,r,r’) = - Im < r |G (E) r’ >

• Density matrix ρ(r, r’) = ∫ EF ρ(E,r,r’) dE

• Density ρ(r) = ∫ EF ρ(E,r,r) dE

• lDOS ρR,L(E) = <R,L| ρ(E,r,r) |R,L>

DFT GFT

Density operator ρ (E) = - Im G (E)

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Real-space Green’s Function Formalismfull-multiple scattering vs MS path expansion

“Real-space KKR”

G0 free propagators t-matrix = ei δl sin δl δRR’δll’

Ingredients:

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Scattering state representation of G

RL (r,E)= Rl(r,E) YL (ȓ)Angular momentum-site basis

GLn,L’n’ (E)= (eik Rnn’ /Rnn’ )Σss’ Yls Y l’s’

Matrix elements - separable representation*

*JJR + R. Albers Phys. Rev. B 41, 8139 (1990)

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Relativistic RSGF

2 Steps

1) Production

Dirac-Fock atomic theory |< f | d | I >|

2) Scattering G= G0 + G0 T GNon-relativistic, no spin-flips, …

*JJR + A. Ankudinov PRB 56, R1712 (1997)

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Implementation: FEFF8Real Space Green’s Function code

BNCore-hole, SCF potentials

Essential!

89 atom cluster

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FAST! Parallel Computation FEFFMPI

MPI: “Natural parallelization”

Each CPU does few energies

Lanczos: Iterative matrix inverse

Smooth crossover between

XANES and EXAFS!1/NCPU

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Example 1: XAS of Pt Pt L3-edge Pt L2-edge (S. Bare, UOP)

• Good agreement: Relativistic FEFF8 code reproduces all spectral features, including absence of white line at L2-edge.

• Self-consistency essential: position of Fermi level strongly affects white line intensity.

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No peak shift!

Path Expansion 15 paths

Rnn= 2.769 fcc Pt

*Theoretical phases accurate distances to < 0.01 Å

χ(R)

R (Å)

Example 2: Pt EXAFS

Phase Corrected EXAFS Fourier Transform *

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Example 3: Electron energy Loss spectra (EELS)

fcc Al

Photon energy (eV)UV X-ray

-Imε-

1

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Example 4: X-ray Raman Spectra (NRIXS) FEFFq

J.A.Soininen, A.L. Ankudinov, JJR, Phys. Rev. B 72, 045136 (2005)

Finite mom transfer q

feff(q,k)

~ Im ε-1(q,ω)

Page 21: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Expt

BSE*

feff(q)

*

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pDOS vs XES and XANES

Example 5: lDOS and X-ray Spectra

Angular momentum Projected DOS

XANES

XESpDOS

Fermi energy EF Final state electron energy E

Cu

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II. Parameter Free RSGF Theory*

A. Ab initio self-energies and mean free path

B. Multi-electron excitations S02

C. Core-hole and local field effects BSE/TDDFT

D. Ab initio Debye Waller factors

E. Full potential corrections

GOAL: eliminate adjustable parameters

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II. Parameter free RSGF theory

JJR et al., Comptes RendusPhysique 10, 548 (2009)

in Theoretical SpectroscopyL. Reining (Ed) (2009)

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A. Self-energy and Inelastic Losses

• GW Approximation (Hedin 67)

• Screened Coulomb Interaction W

? How to appproximate ε-1 (ω) ?

Need: complex, energy dependent Σ(E)

Page 26: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Dielectric functionEnergy Loss (EELS)Absorption coefficientRefractive indexReflectivityX-ray scattering factors f = f0 +f1 + if2

Hamaker constants ε(iω)

RSGF approach: VIS-UV optical constants

Long wavelength limit q = 0 + extrapolation to finite q

Page 27: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

FEFF8OP*

*WWW: M. Prange http://leonardo.phys.washington.edu/feff/opcons/

-Im

ε-1

Cu

PRB 80, 155110 (2009)

Page 28: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Optical Constants FEFFOP vs DESY Tableshttp://www.leonardo.washington.edu/feff/opcons

Page 29: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Theoretical check: ε2 Sumrule

fcc AlZ=13 13

Photon energy (eV)

neff

Page 30: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Many-pole Self-energy Algorithm*

Plasmon-pole model many-pole model

-Im ε-1(ω) Many-pole Dielectric Function

~ Σ i gi δ(ω - ω i)

Many-pole GW self-energy Σ(E)

* J. Kas et al. PRB 76, 195116(2008)

Page 31: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Cu

ab initio q=0 loss function Sum of single poleself-energies

http://leonardo.phys.washington/feff/opcons

Example: Many-pole model for Cu*

Plasmon pole model

Many-pole pole model

*J. Kas et al., Phys. Rev. B. 76, 195116 (2007)

-Im ε-1(ω)

Cu

Page 32: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Many-pole vs Single Plasmon Pole Self-energy Models

●●●●

Σ =Σ(E) indep of r

Σ =Σ(E,k) Full GW (Lanczos)

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ab initio Inelastic Mean Free Paths

Plasmon-pole model many-pole model

Plasmon-pole model has too much loss!Cu

Inel

astic

mea

n fre

e pa

th

J. Kas et al. 76, 195116 (2008)

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Self-energy Effects in Cu K-edge XAS

J. Kas Phys. Rev. B 76, 195116 (2007)

Σ(E) MPSE Self energy

Re Σ(

E)

Plasmon pole

Page 35: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

Aposteriori Self-energy corrections toDFT and GW codes

µ(E

) (ar

bitra

ry u

nits

)

E (eV) PARATEC: D. Cabaret et al. (2008)

MPSE

MgAl2O4 Spinel

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B. Intrinsic losses: Multi-electron Excitations

Multi-electron excitations

→ satellites in A(k,ω)

Energy Dependent Spectral Function A(k,ω)

Beyond quasiparticles!Quasi-boson Model

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Quasi-Boson Theory of Inelastic Loss*

Excitations - plasmons, electron-hole pairs ... are bosons

*W. Bardyszewski and L. Hedin, Physica Scripta 32, 439 (1985)

“GW++” Same ingredients as GW self-energy Vn → -Im ε-1(ωn,qn) fluctuation potentials

Many-body Model: |e- , h , bosons >

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Effective GW++ Green’s Function geff(ω)

Damped qp Green’s function

Extrinsic + Intrinsic - 2 x Interference

geff(ω)=

Spectral function: A(ω) = -(1/π) Im geff(ω)

L. Campbell, L. Hedin, J. J. Rehr, and W. Bardyszewski, Phys. Rev. B 65, 064107 (2002)

+ - -

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Effect on Spectra: Amplitude reduction

• XAS = Convolution with spectral function A(ω, ω’)

• Explains crossover: adiabatic

to sudden approximation

≈ μqp(ω) S02

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Many-body amplitude reduction in EXAFSQuantitative R-space EXAFS

S02~0.9

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C. Core-hole and local field effects BSE/TDDFT

Two step approach to TDDFT/BSE

χ = (1 – K χ0) -1 χ0 K = V + W

1) χ’ = (1 – V χ0) -1 χ0 χ ~ RPA response

2) χ = (1 – W χ’ ) -1 χ’ W ~ RPA core hole

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Step 1: Local Field Effects

• Transition operator not external x-ray field φext

Must include polarization φ = φext + φinduced

= ε-1 φext

ε = 1 – K χ0 Dielectric matrixK = V RPA (or V+ fxc for TDDFT)

~→ Golden rule with screened matrix elements* M

*A. Zangwill + P Soven, Phys Rev A 21, 1561 (1980)

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Example: local field effects in XAS TDDFT

*Data: Z. Levine et al. J. Research. NIST 108, 1 (2003)

TDDFT

FEFF8

Data*No adjustable parameters

W

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Step 2. Screened Core Hole

Corrections to ad hoc core-hole approxfinal state rule, Z+1, half-core hole …

Stott-Zaremba algorithm (= static RPA) W = ε-1 Vch

Approx: Include W in g’ = 1/( E – h’ – Σ )as in quasi-boson model

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Screened core-hole potential W

0 1 2 3R (bohr)

-6

-4

-2

0

Pote

ntia

l (H

artre

e)

RPA – Stott ZarembaFully screened FEFF8

Unscreened

Tungsten metal (Y. Takimoto)

RPA

W

Page 46: J. J. Rehr Department of Physics, University of Washington …online.itp.ucsb.edu/online/excitcm09/rehr/pdf/Rehr_ExcitationsCM... · • Density matrix ρ (r, r’) = ∫ E F. ...

( ) ωωβωρμ

σ di 2

coth0

22 ∫∞

=

( ) ( ){ }recursion Lanczos step6

22

−=

−= ii QDQ ωδωρ

D. Ab initio XAS Debye Waller Factors e-2σ2 k2

Replaces correlated Debye and Einstein Models !

= VDOS

D = Dynamical matrix

Phys. Rev. B 76, 014301 (2007)

Ψ

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Ab initio DFT Phonon Green’s function

G = (ω2 – D)-1

( ) ⎩⎨⎧

∂∂∂

=ssian03ABINIT/Gau from

Matrix Dynamical1

''

2

21'

'',βα

βαljjljj

ljjl uuE

mmD

NB: Need functional for both bond lengths and phonons:“hGGA” = “half and half PBE”

expt

expt

Strong correlation between lengths a and <ω>

GGALDA

hGGA

oo

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Lanczos Recursion (Many-pole)

Total VDOS of Cu

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XAFS Debye-Waller Factor of Ge

Expt: Dalba et al. (1999)

F. Vila et al.

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Ab Initio Debye-Waller Factors in Rubredoxin

Convert Full System into Smaller Model

Path Theory Exp.Fe-S1 2.9 2.8±0.5

Fe-S2 2.9 2.8±0.5

Fe-S3 3.3 2.8±0.5

Fe-S4 3.5 2.8±0.5

σ2 (in 10-3 Å2)

Fe

S

SS

S

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Interface with ORCA FP-SCF code (J. Kas)

ORCA FEFF-FP

ElectrostaticPotential

Density XANES

F. Full Potential Multiple Scattering* In progress

*A. L. Ankudinov and J. J. Rehr, Physica Scripta, T115, 24 (2005)

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CONCLUSIONS

• Parameter free ab initio RSGF approach forelectronic & vibrational structure &spectra: VIS - X-ray, EELS, NRIXS, …

● Attractive alternative to k-space approach

● Efficient relativistic all electron code FEFF9

Ψ

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Acknowledgments

• J. Kas (UW)• F. Vila (UW)• K. Jorissen (UW)• M. Prange (ORNL,UW)• A. Sorini (SSRL/SLAC,UW)• Y. Takimoto (ISSP,UW)

Collaborators

Supported by DOE BES & NIST

A.L. Ankudinov (APD)R.C. Albers (Los Alamos))Z. Levine (NIST)E. Shirley (NIST)A. Soininen (U. Helsinki) H. Krappe (HZB)H. Rossner (HZB)

Rehr Group

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That’s all folks


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