The all-electron full-potential linearized augmented plane-wave … · 2020. 12. 4. · The LAPW...
Transcript of The all-electron full-potential linearized augmented plane-wave … · 2020. 12. 4. · The LAPW...
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The all-electron full-potentiallinearized augmented plane-wave methodSep 9, 2019 Gregor Michalicek Institute for Advanced Simulation,Forschungszentrum Julich and JARA, 52425 Julich, Germany
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Outline
Theoretical backgroundThe FLAPW method and the LAPW basisSeparation of core electrons from valence electronsRepresentation of density and potential
FLAPW in practiceSetting the parametersSemicore states and ghost bandsThe linearization error
Using fleurThe input file generatorThe inp.xml file
Further readingConclusion
Slide 1
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Outline
Theoretical backgroundThe FLAPW method and the LAPW basisSeparation of core electrons from valence electronsRepresentation of density and potential
FLAPW in practiceSetting the parametersSemicore states and ghost bandsThe linearization error
Using fleurThe input file generatorThe inp.xml file
Further readingConclusion
Slide 2
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Motivation: FLAPW in zoo of electronicstructure methods
[T + VH(r) + Vext(r) + Vxc(r)
]ψν(r) = Eν ψν(r)
Relativity
non-relativistic
scalar-relativistic
fully relativistic
Approximation to exchange-correlation func-tional
local density approximation (LDA)
generalized gradient approximation (GGA)
LDA+U
hybrid functionals
EXX+RPA
. . .
Contributions to potential
pseudopotential
all electron
Representation of potential
spherical approximation
full potential
Representation of wave func-tions
linear combinations of atomicorbitals (LCAO)
Gaussian orbitalsnumerical orbitals
plane waves (PW)
real-space grid
non-linear methods
KKRaugmented plane waves(APW)
linearized methods
LMTOlinearized augmentedplane waves (LAPW)
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Potential and wave functions in a crystal
r
E
Core electrons
Semicore electrons
Valence electrons
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Potential and wave functions in a crystal
r
E
Bloch theorem:
If V (r) = V (r + R):
Ψ(r) = eikr · uk(r),
uk(r) = uk(r + R)
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The LAPW basisAtom-centered functions in MT spheres matched in value andslope to plane waves in interstitial region (IR)
φkG(r) =
1√Ω
ei(k+G)r for r ∈ IR∑L
[aLα
kGuαl (rα,Eαl ) + bLα
kGuαl (rα,Eαl )]
YL(rα) for r ∈ MTα
uαl and uαl are solutions and energy derivatives for the sphericalpotential at energy parameters Eα
l
InterstitialRegion (IR)
Muffin-tinfor atom α
(MTα) 0 RMT
0
Interstitial Region (IR)Muffin-tin(MT)
plane waveul(r),
.ul(r)
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The LAPW basisAtom-centered functions in MT spheres matched in value andslope to plane waves in interstitial region (IR)
φkG(r) =
1√Ω
ei(k+G)r for r ∈ IR∑L
[aLα
kGuαl (rα,Eαl ) + bLα
kGuαl (rα,Eαl )]
YL(rα) for r ∈ MTα
uαl and uαl are solutions and energy derivatives for the sphericalpotential at energy parameters Eα
lParameters:
Kmax = |k + G|max reciprocal plane wave cutofflαmax angular momentum cutoff for sphere αRα
MT radius for muffin-tin sphere αEα
l energy parameter for uαl , uαlNote: LAPW basis depends on atom positions and featuresdiscontinuities at MT boundaries
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Orthogonality of LAPW basis functions tocore electron states (1)
ul(r), ucl (r) given by radial Schrodinger equation:[−1
2∂2
∂r2 +l(l + 1)
2r2 + V sphreff (r)
]rul(r) = El rul(r) (1)
Multiply (1) for ul(r) by rucl (r) and vice versa, subtract the two
resulting equations from each other, and integrate:
RMT∫0
−12
rucl (r)
∂2
∂r2 rul(r)+12
rul(r)∂2
∂r2 rucl (r)dr = (El−Ec
l )
RMT∫0
ul(r)r2ucl (r)dr
Assumption: ucl (r)
∣∣RMT
= 0, ∂∂r uc
l (r)∣∣RMT
= 0
We obtain: 0 =⟨uc
l
∣∣ul⟩
RMTand analogously 0 =
⟨uc
l
∣∣ul⟩
RMT
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Orthogonality of LAPW basis functions tocore electron states (2)
Orthogonality allows to determine core and valence electronenergies and wave functions separately from each otherCore electrons
Representation for each atom separately on radial meshFully relativistic treatment
Valence electronsRepresentation by LAPW basisScalar-relativistic description in MT spheresOptional inclusion of spin-orbit coupling
But: assumption ucl (r)
∣∣RMT
= 0, ∂∂r uc
l (r)∣∣RMT
= 0 onlyapproximately fulfilled
Semicore states can lead to ghost bands
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The linearization within the LAPW basis
Description in MT spheres is not systematically improved byincreasing the reciprocal cutoff parameter Kmax
Linearization of solutions ul at arbitrary energy ε
uαl (rα, ε) = uαl (rα,Eαl ) + (ε− Eα
l )uαl (rα,Eαl ) +O
[(ε− Eα
l )2]Due to the restriction to the function space spanned by uαl (rα,Eα
l )and uαl (rα,Eα
l ) we obtain a linearization error.This description is sufficient to obtain accurate results for manymaterials.
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Extending the LAPW basis with localorbitalsAdditional basis functions localized in MT spheres
φloL (r) =
[alo
L uαl (rα,Eαl ) + blo
L uαl (rα,Eαl ) + c lo
L uαl (rα,E lol )]
YL(rα)
Mainly used to describesemicore statesDetermination of alo
L , bloL , and
c loL by enforcing zero value
and slope at the MT boundary,as well as a normalizationcondition on the local orbital
0 RMT
0
Interstitial Region (IR)
Muffin-tin (MT)
zeroul(r,E
l),
.ul(r,E
l), ul(r,E
l
lo)
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Extending the LAPW basis with localorbitalsAdditional basis functions localized in MT spheres
φloL (r) =
[alo
L uαl (rα,Eαl ) + blo
L uαl (rα,Eαl ) + c lo
L uαl (rα,E lol )]
YL(rα)
Semicore states (SCLO)Choose E lo
l to be energy ofsemicore state
Unoccupied orbitals (HELO)Choose E lo
l above Fermienergy
Higher derivative LOs (HDLO)Choose uα
l (rα,Eαl ) instead
of uαl (rα,E lo
l )0 R
MT
0
Interstitial Region (IR)
Muffin-tin (MT)
zeroul(r,E
l),
.ul(r,E
l), ul(r,E
l
lo)
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The LAPW basis for films
φk‖G(r) =
1√Ω
ei(k‖+G)r for r ∈ IR∑L
[aLα
k‖Guαl (rα,E
αl ) + bLα
k‖Guαl (rα,E
αl )
]YL(rα) for r ∈ MTα[
avack‖Guvac
k‖G‖(z,Evac) + bvac
k‖Guvack‖G‖
(z,Evac)]
× 1√A
ei(k‖+G‖)r‖ for r ∈ VRvac
Interstitial Region (IR)
Muffin-tin (MT)
Vacuum Region 2 (VR2)
Vacuum Region 1 (VR1)
DD
A = surface area
uvack‖G‖
,uvack‖G‖
: solutions,energy derivatives tovacuum potential atenergy parametersEvac
G⊥ = 2πn/D
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The LAPW basis for films
φk‖G(r) =
1√Ω
ei(k‖+G)r for r ∈ IR∑L
[aLα
k‖Guαl (rα,E
αl ) + bLα
k‖Guαl (rα,E
αl )
]YL(rα) for r ∈ MTα[
avack‖Guvac
k‖G‖(z,Evac) + bvac
k‖Guvack‖G‖
(z,Evac)]
× 1√A
ei(k‖+G‖)r‖ for r ∈ VRvac
Interstitial Region (IR)
Muffin-tin (MT)
Vacuum Region 2 (VR2)
Vacuum Region 1 (VR1)
DD
A = surface area
Parameters:D - vacuum boundaryD - determination ofG⊥Evac - vacuum energyparameters
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Representation of density and potential
Plane-wave part
ρPW(r) =Gmax∑
GρG · eiGr
Actually represented by stars
Linear combinations ofplane waves according tosymmetry
MT sphere α
ρα(r) =Lα
max∑LραL (rα)YL(rα)
Actually represented bylattice harmonics
Linear combinations ofspherical harmonicsaccording to symmetry
Parameters:Gmax reciprocal plane-wave cutoff for density, potentialGmaxXC reduced cutoff for exchange correlation potential
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Outline
Theoretical backgroundThe FLAPW method and the LAPW basisSeparation of core electrons from valence electronsRepresentation of density and potential
FLAPW in practiceSetting the parametersSemicore states and ghost bandsThe linearization error
Using fleurThe input file generatorThe inp.xml file
Further readingConclusion
Slide 12
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Choice of Kmax, lαmax, and lαnonsphr
Rayleigh expansion of planes waves at MT boundary:
eiKr = 4πeiKτα∑
L
i lY ∗L (K)jl(Krα)YL(rα)
∣∣∣∣∣rα=Rα
MT
Rule of thumb:
lαmax ≈ Kmax · RαMT
≈ 8− 12
Determinationof Kmax basedon Rα,min
MT
lαnonsphr ≈min(8, lαmax − 2) 0 2 4 6 8 10 12
Kr
-0.2
0
0.2
0.4
0.6
0.8
1
j l(K
r)
j0(Kr)
j1(Kr)
j2(Kr)
j3(Kr)
j4(Kr)
0 2 4 6 8 10 12
Kr
-0.2
0
0.2
0.4
0.6
0.8
1
j l(K
r)
j5(Kr)
j6(Kr)
j7(Kr)
j8(Kr)
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Choice of Gmax and GmaxXC
Gmax is cutoff for different functionsPlane wave part of charge density ρPW(r)Plane wave part of potential V PW
eff (r)Step function Θ(r) indicating the interstitial region
V PWeff (r) and Θ(r) have infinitely many plane-wave coefficients.
Interstitial potential contribution to Hamilton matrix:⟨φkG
∣∣∣Θ(r)V PWeff (r)
∣∣∣φkG′
⟩Rule
Gmax ≥ GmaxXC ≥ 2 · Kmax
typically Gmax ≈ 3 · Kmax, GmaxXC ≈ 2.5 · Kmax
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Choice of the energy parameters
energy center of massof the l-projected DOS
minimizes quadraticerror weighted bycharge in eacheigenstate
atomic solutionsyields more friendlyconvergencebehavior
fcc Ce
-0.25 -0.2 -0.15 -0.1 -0.05 0 0.05E
5d - E
F (Htr)
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
Eto
tal -
Em
in
tota
l (m
Htr
)
LAPWLAPW+HDLO
-0.2 -0.1 00
0.001
0.002
0.003
energycenter of mass
atomic energyparameter
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Choice of MT radii
Due to different bonding lengths in different materials the RMT arematerial dependent.If calculations have to be compared identical MT radii should bechosen.
Large MT radii Small MT radii
Faster calculationsLarger linearization errorFewer SCLOs neededSome quantities onlyevaluated in MT
Slower calculationsMore stable calculationsSmaller linearization errorMore SCLOs neededMore space available forstructural relaxations
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Semicore states and ghost bands
-10
-5
0
5
10
15
20
H N P NΓ Γ
E -
EF (
eV
)
bcc Vanadium
RMT = 2.25 a0, lostElectrons = 0.086
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Semicore states and ghost bands
-10
-5
0
5
10
15
20
H N P NΓ Γ
E -
EF (
eV
)
bcc Vanadium
RMT = 2.20 a0, lostElectrons = 0.100
Slide 17
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Semicore states and ghost bands
-10
-5
0
5
10
15
20
H N P NΓ Γ
E -
EF (
eV
)
bcc Vanadium
RMT = 2.17 a0, lostElectrons = 0.109
Slide 17
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Semicore states and ghost bands
-10
-5
0
5
10
15
20
H N P NΓ Γ
E -
EF (
eV
)
bcc Vanadium
RMT = 2.16 a0, lostElectrons = 0.112
Slide 17
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Semicore states and ghost bands
************** juDFT -Error *****************
Error message:differ 2: problems with solving dirac equation
Error occurred in subroutine:differ
Error from PE:0/1
*****************************************
Last kown location:
Last timer:Updating energy parameters
Timerstack:
Timer:eigen
Timer:gen. of hamil. and diag. (total)
Timer:Iteration
Timer:Total Run
*****************************************
RMT = 2.15 a0, lostElectrons = 0.123This error message can also have other causes.Other error messages are also possible.
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Semicore states and ghost bands - with SCLO
-10
-5
0
5
10
15
20
H N P NΓ Γ
E -
EF (
eV
)
bcc Vanadium
RMT = 2.16 a0, lostElectrons = 0.012, SCLO for 3p state
Slide 18
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Linearization error depending on energymismatch
fcc Cerium
-5 -2.5 0 2.5 5 7.5 10 12.5 15E-E
5d (Htr)
0
0.2
0.4
0.6
0.8
1
∆l=
2(E
)
-0.2 -0.1 0 0.1 0.20
1×10-3
2×10-3
3×10-3
4×10-3
5×10-3
LAPWLAPW+HDLOx1LAPW+HELOx1LAPW+HELOx2
bcc Vanadium
-5 -2.5 0 2.5 5 7.5 10 12.5 15E-E
4p (Htr)
0
0.2
0.4
0.6
0.8
1
∆l=
1(E
)
LAPWLAPW+HDLOx1LAPW+HELOx1LAPW+HELOx2
∆l =√‖ ul(r , ε)− ul(r , ε) ‖2
Slide 19
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The linearization error and MT radiifcc Ce
2.4 2.5 2.6 2.7 2.8 2.9 3R
MT (a
0)
0.944
0.946
0.948
0.95
0.952
0.954
0.956
0.958
0.96
0.962
0.964
equ
ilib
riu
m l
atti
ce c
on
stan
t a
/ a
exp
LAPWLAPW+HDLOx1LAPW+HELOx1LAPW+HELOx2
2.4 2.5 2.6 2.7 2.8 2.9 3
0.9436
0.9438
0.944
0.9442
0.9444
lattice constant changes by1.6% when MT radius isreduced
rock-salt KCl
2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8R
MT (a
0)
0.966
0.967
0.968
0.969
0.97
0.971
equ
ilib
riu
m l
atti
ce c
on
stan
t a
/ a
exp
LAPWLAPW+HDLOx1LAPW+HELOx1LAPW+HELOx2
2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.80.966
0.9662
0.9664
0.9666
0.9668
0.967
lattice constant changes by0.4% when MT radii arereduced
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The linearization error and unoccupiedstates
K Γ L-2
-1
0
1
2
3
4
5
6
7
8
9
10
11
12
E-E
F (
eV
)
LAPWLAPW+HDLOx1
KS band gap for rock-salt KClis reduced by 4% by addingone set of HDLOs
K Γ L-2
0
2
4
6
8
10
12
14
16
E-E
F (
eV
)
LAPWLAPW+HDLOx1
KS band gap for fcc Ar isreduced by 19% by addingone set of HDLOs
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Outline
Theoretical backgroundThe FLAPW method and the LAPW basisSeparation of core electrons from valence electronsRepresentation of density and potential
FLAPW in practiceSetting the parametersSemicore states and ghost bandsThe linearization error
Using fleurThe input file generatorThe inp.xml file
Further readingConclusion
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The input file generator
Fleur uses complex inputInput file with default parameters is generated by input filegenerator inpgenSimple structural input needed for inpgen
Example input for inpgen
NaCl bulk
&lattice latsys=’fcc ’ a0 =10.62026 /
2
11 0.0 0.0 0.0
17 0.5 0.5 0.5
Usage: inpgen < myInputFile.txt
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Input file generator - command line options
-h write out list of command line optionsOptional Input to be generated
-explicit add some optional input direcly to inp.xml file.– List of k points– Symmetry operations (otherwise if needed in sym.out file)– Noncollinear magnetism input
-noco generate noncollinear magnetism input in inp.xml-genEnpara generate enpara file for more energy parameteroptions...
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Fleur input: the inp.xml file
<?xml version ="1.0" encoding ="UTF -8" standalone ="no"?>
<fleurInput fleurInputVersion="0.30">
<comment > Fleur is cool </comment >
<calculationSetup > ... </calculationSetup >
<cell > ... </cell>
<xcFunctional > ... </xcFunctional >
<atomSpecies > ... </atomSpecies >
<atomGroups > ... </atomGroups >
<output > ... </output >
</fleurInput >
Usage: fleur-h command line option to display all fleur modes
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The inp.xml file - calculationSetup
<calculationSetup >
<cutoffs Kmax="3.6" Gmax="10.7" GmaxXC="8.9"
numbands="0"/>
<scfLoop itmax="15" minDistance=".0"
imix="Anderson" alpha=".05"/>
<coreElectrons ctail="T" frcor="F" kcrel="0"/>
<magnetism jspins="1" l_noco="F"/>
<bzIntegration valenceElectrons="16.0" mode="hist"
fermiSmearingEnergy=".001">
<kPointCount count="15" gamma="F"/>
</bzIntegration >
</calculationSetup >
+ Optional input, e.g., nocoParams, geometryOptimization
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The inp.xml file - cell, xcFunctional
<cell >
<symmetryFile filename="sym.out"/>
<bulkLattice scale="1.000" latnam="any">
<bravaisMatrix >
<row -1> 0.00000 5.31013 5.31013 </row -1>
<row -2> 5.31013 0.00000 5.31013 </row -2>
<row -3> 5.31013 5.31013 0.00000 </row -3>
</bravaisMatrix >
</bulkLattice >
</cell>
<xcFunctional name="pbe"
relativisticCorrections="F"/>
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The inp.xml file - atomSpecies
<atomSpecies >
<species name="Na -1" element="Na" atomicNumber="11"
coreStates="1" magMom=".00" flipSpin="T">
<mtSphere radius="2.80" gridPoints="925"
logIncrement=".0120"/>
<atomicCutoffs lmax="10" lnonsphr="8"/>
<energyParameters s="3" p="3" d="3" f="4"/>
<lo type="SCLO" l="0" n="2" eDeriv="0"/>
<lo type="SCLO" l="1" n="2" eDeriv="0"/>
</species >
<species name="Cl -2" element="Cl" atomicNumber="17"
coreStates="4" magMom=".00" flipSpin="T">
...
</species >
</atomSpecies >
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The inp.xml file - atomGroups
<atomGroups >
<atomGroup species="Na -1">
<relPos > .000000 .000000 .000000 </relPos >
<force calculate="T" relaxXYZ="TTT"/>
</atomGroup >
<atomGroup species="Cl -2">
<relPos > 1.0/2.0 1.0/2.0 1.0/2.0 </relPos >
<force calculate="T" relaxXYZ="TTT"/>
</atomGroup >
</atomGroups >
+ Optional input, e.g., nocoParams
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The inp.xml file - output
<output dos="F" band="F" vacdos="F" slice="F">
<densityOfStates ndir="0" minEnergy=" -.50"
maxEnergy=".50" sigma=".015"/>
</output >
+ Optional input, e.g., vacuumDOS, plotting, chargeDensitySlicingFull documentation of inp.xml file on www.flapw.de
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Overview on files
with HDF5 without HDF5
inp.xml(sym.out)enpara (optional)cdn.hdfmixing history.*input for special calculationsout, inf, out.xml
inp.xml(sym.out)enpara (optional)cdn1, cdn??, cdncmixing history.*stars, wkf2input for special calculationsout, inf, out.xml
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Further reading
The FLAPW methodOverview book - Singh et al., Planewaves, Pseudopotentials,
and the LAPW Method, SpringerInitial publication - Andersen, PRB 12, 3060 (1975)FLAPW for films - Krakauer et al., PRB 19, 1706 (1979)Potential calculation - Weinert, J.Math.Phys. 22, 2433 (1981)Predecessor (APW) - Slater, Phys.Rev. 51, 846 (1937)
Local orbitalsSCLOs - Singh, PRB 43, 6388 (1991)HELOs - Betzinger et al., PRB 83, 045105 (2011)HDLOs - Friedrich et al., PRB 74, 045104 (2006)Linearization error - Michalicek et al., CPC 184, 2670 (2013)
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Conclusions
LAPW basis + local orbitalsGuidelines for setting parameters
Kmax, lαmax, lαnonsphrRα
MT, Eαl
Gmax, GmaxXC
Semicore states and ghost bandsThe linearization errorFleur input filesNot discussed
General numerical DFT parameters,e.g., k point set, Fermi smearing, ...
0 RMT
0
Interstitial Region (IR)Muffin-tin(MT)
plane waveul(r),
.ul(r)
lαmax ≈ Kmax · RαMT
-10
-5
0
5
10
15
20
H N P NΓ Γ
E -
EF (
eV
)
bcc Vanadium
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