- Email: [email protected]
A calculation of correlation functions based on band structure
Physica B 172 (1991) North-Holland
271-278
A calculation
of correlation
functions based on band structure
H. Winter”, Z. Szotekb and W.M. Temmerman” “Kernforsckur2~.~zenrrum Karlsruhe. INFP, P. 0. Box 3640, W-7_SOO Karlsruhe. “SERC Dawshury Laboratory. Warrington, WA 44A D. UK
We discuss the evaluation of functions are constructed using equations are approximated by reasonable results for a wide class the case of ceramic materials.
Germany
correlation functions in the framework of the RPA. Whereas the one-particle Green the calculated band structures, the K-matrices of the corresponding Bethc-Salpeter functional derivatives of the exchange-correlation potentials. This approach leads to of transition metals and compounds. We point out extensions of the theory. necessary in
1. Formulation In addition to one-particle quantities that are directly obtained from band structure calculations the knowledge of correlation functions is vital for the understanding of both equilibrium and nonequilibrium properties of solids. This is obvious for the spin-density-spin-density correlation function, with magnetic phenomena. However, it turns out x“, and the orbital susceptibility, x “, in connection that x’ together with the density correlation function, x”, has also to be known in order to account for superconducting properties. To calculate any correlation function, x, we need two ingredients: an approximation for the “non-interacting” part xp and the particle-hole irreducible K-matrix. The results of a satisfactory theory for x should both compare favourably to scattering experiments that probe its spectral density directly (magnetic neutron scattering in the case of x’ and x0, ELS in the case of x”) and lead to reasonable values for the derived quantities like effective masses, superconducting transition temperafirst-principles theory is desirable. A tures, etc. To fulfill these requirements a parameter-free, reasonable first approach worthwhile to be tested is the RPA-LDA approximation, where xp is approximated by the “bubble” diagram consisting of the one-particle Green function of the LDA response of HLDA to an appropriate Hamiltonian, fILDA, and K is derived from the linear unretarded external field. The Bethe-Salpeter-equation for the lattice Fourier transform x,(p~, ~‘7’; w) of x, which contains all the information, then reads [l]:
restricted to the Wigner-Seitz cells of the sites T, T’, . . , Here p, p’, . . . , are the local coordinates within one unit cell. The expression for the lattice Fourier transform of K, K,, depends on the kind of correlation function in question, in particular, KJ pi, ~‘7’)
forx,
= - ; [8V,,(n,
m) /6m]6(p
- p’)S,,,.
= K;,
(24
,
KJ PT, ~‘7’) = 0 , 0921.3526/91/$03.50
0
1991 ~ Elsevier
(2b) Science
Publishers
B.V. (North-Holland)
tor x,, It is ;I massive piece of work to evaluate k i ah the l’ollowing formula show\. quantity in terms of the angular momentum-dccomposecl Bloch state coefticienh. I?;( p. F). and the hand cncrgiea tA (. part> of the single-site wave functions,,
I‘0
obtain
Im
,,y“
we
perform
careful
Brillouin
/.onc
integration4
o\‘cr
thaw
~rcgion\
which cxprcac\ ( i , , . the
whcl-e
the\ tratli;ll
tt-an41tion4
~~1.
2. Results for the spin density
correlation
function
We have calculated x” for some systems differing in their spin tluctuation amplitudes 141. Vanadium is an example of a moderately Stoner-enhanced system (S -- 2.7). Iii fig. 1 \vc 4hon the diagonal part of the double real-space Fourier transform of Im x ” for some wa\‘c vector\ 9 in the (1. 0, 0) direction and fig. 2 shows the same for the interacting quantity 4 The sharp peaks at small frequencies and the wave vectors are related to intraband transitrona III the vicinity of the Fermi energy. The interaction enhances them and shifts them to smaller frequcncic\ III proportion to S. Because of matrix-element effects. the widths of x” and % ’ shrink to Lcro ;15 q transitions come in and cnhanccmcnt approaches zero. For increasing q more and more interband effects are of minor importance. As an example for a highly Stoner-enhanced system WC considered Pd( S = 0 ). Figure5 -3 and 4 \hov, lm x”( 9, 9’; w) and Im x‘( 9. 9’; CO). respectively. Again, enhancement effcctx arc most import;lnt ;II small wave vectors and frequencies, where interband transitions rclatcd to the scaffolding structure parts of the energy surfaces near the Fermi surface dominate. In those systems the magnitudes of the differential cross sections for magnetic neutron scattering arc too small to allow for ;I measurcmcnt of Im x‘( 9. 9: w) through the use of contemporary neutron sources. The situation is different for the nearly ferromagnetic compound Ni,Ga 151. the Stoner enh;tncemc~nt of which is estimated to be near 100. from the cxpcrimcnts of ref. [6]. Th c Grnilar compound Ni :A1 i\ ferromagnetic at low temperatures as refs. 171 and [X] have shown. Our results for Im ,y’( 9. 9: CO)in the long-wavelength limit arc displayed in tig. 5 and the quantity Im x’( 9. 9: W);OJ folded with the experimental resolution function (fig. 6) allows for :I direct comparison with the results of ref. (61
ofcorrelationfunctions
H. Winter et al. I Calculation
9
.06
--I
273
---
0.80
--
0.60
q
0.40
_ z ' S'
04
-
0.20
~--
0.10
-
”
0.80
--
0.60
-
0.20
---.
0.10
-
0.05
0.40
0.05
3
---
r.
02
cr--
A _E
__-_.-.- -------_________
c_-___..
0 0
0.2
0.4
0.6
FREQUENCY
a
0.8
1.0
I .2
(t-V)
I
I
I
1
I
I
0.2
0.4
0.6
0.8
1.0
I.:
a
FREQUENCY
(eV)
0.08 0.04 0.06
---
0.80
--
0.60 0.40
0.04
-
0.20
---
0.10
-
0.05
\ 4 0 2
b
FREQUENCY
(eV)
Fig. 1. Im x”( q. q: W) for C’ with q in the (1.0.0) direction. (a). high-frequency range; (b). low-frequency range. q is in units of 27FIa.
b
4
6 FREQUENCY
Fig. 2. Im
8
10
(eV)
,y‘(q. 9; w) for V
In agreement with the experiment are the small widths of the curves (~0.5 meV at q = 0.04 T/U), the high value of the Stoner enhancement (S = 30 at q = 0.04 T/U), which extrapolates to about 100 for q - 0 and the rapid decay of the fluctuation amplitudes with increasing q. We stress again that it is essential to solve the full Bethe-Salpeter equation (1) for x’ instead of using any scalar version of it. Most important are the matrix element effects, because the so-called generalized susceptibility, which adds up the intraband transitions while leaving the matrix elements out differs markedly from the full susceptibility. Indeed, as the investigations of refs. [9] and [lo] show, x0 behaves quite differently from x’ and xp, though one and the same particle-hole transition contributes to both quantities and this difference is entirely the result of matrix element effects.
0 020
0 015
0.010
0.005
0 0
?
t1
3. Derived
4 FREQUENCY
6
Y
I ,_ 1
(e'i)
quantities
As an example WC consider the effect of the electron-spin tluctuation coupling to the normi self-energy. that is its contribution to the electronic mass cnhanccmcnt. It i\ pwsihle to formulate thi< in close analogv to the electron-phonon coupling case. We obtain the follow~in~ wt of cquntions:
27s
H. Winter et al. I Calculation of correlution functions
q=OO2
-E
)
(du
l.W4~
-
sol 020
0
I
I
I
I
I
I
I
080
loo
Ix)
140
I60
180
I
I
14
16
IE
I
040
063
2
0
(b) qz0.05 Cd u
I 0
Frequency Fig. 5. Im
x‘(q, q; w) of Ni,Ga
II 2
4
for small wave vectors.
I
I
I
II
6
a
IO
12
Frequency
CmeV) Fig. 6. Im ,y‘(q. q; perimental resolution
J
imeV
w)/w for Ni,Ga, function.
21
I
folded
with
the
ex-
7‘he
analogy
between
electron-phonon lattice full
Fourier
dependence
on Our
V and 0.16 It
is
yields
for
enhancement
Pd.
of
The
the
7‘,
by for
coupling
Hecause
~lrouIl‘, put
the
in
/lq. order
arc compatible parameter-free like
from
using
the
Note. 2nd to
one
Grlc
get
and
h’;,
that it i4 exential
the correlation
the
with
:~ncl the
to emplo\
t’unction.
reasonable
magnetic
specific
\aluc5
the
1 ‘. 111-thcll
1hc ITI;IS\
for
band
neutron
No simple
structure
heat mcauremcnt~.
baxccl on band
KPA
\cattcring
\tructurc cros\
\imult:mcou\l!
xxtion.
scalin g hetb\ecn the latter
the fact that WC have taken
the
electron
of x‘
;I
McMillan
the
Green
mechanism
in parallel
(_Y. J’ = F, ).
F~ cc.4:“<“1’1”” which to 0. I3 with
x. the
account
the
function>
instead
of
Stoncl
quantity
of the broken
espre\sccl
transition
and ~lpE’r”“ir-natinf
and alloys.
the
the
WC have formulated and
elect-ran-phonoll
and
.\
translational
reorting
to
an\
LX_
the
(4) In
\uggcsts
that
\+c
prcvlou\
tact.
dvnamic
C‘oulomb
correct
the \ ;iluc’\ oi
a11 Eliashbergh clcctron-spin
I
Inlcl
cquatlor fluctuation
It is
range of x‘ the gap now depends K”‘““‘.
relevant
energy
for
II!
temperature\.
’ . of the order- of 0. 1.3 failccl to predict
Whereas
stands
respect
F
containing
[ I I].
coupling
alone
compounds
frcqucncy
energy-variable
fluctuation
superconducting
mechanism
parameter.
V and V-based self-energy
energy
spin
on
on the phonon
of the extended
equal
propagator
mass enhancement.
result
anomalous
F and a real Fermi
of
based
effects
the
the
quantities
by
influence
, especially
for
(I ‘b on
is obvious.
&sumptic;ns.
the
calculations action
IOU values that
for
systems
formulation
investigate
‘I‘hcsc
findings
jellium-model-like
function side
q. p and p’
variables
results
These
Eliashberg
on the other
arc
and the electronic
is observed. symmetry
their
to observe
reasonable
the
of the particle-hole
results
gratifying
and
potential
transform
enhancement.
for
I( lo)
coupling
the usual phonon region
of
the s17in-independent
to ;I cut-off
of 50[:,‘:::“.
ti““”
on both the Matsubnra
kernel. ” with
part
is essentially respect
for- I’
to the
to .\ and 1‘ ih ;I tcu
of the (‘oulomb
OUI- results
trcquc‘nclc’x
restricted
inter&on.
ha
CL’
been
;iic‘
I‘, ==20 K. if K“““”
is put
‘f‘, -9.5 if k“‘““” We transition
K
equal
to zero.
and
.
is included. conclude
that
spin
temperatures
in
fluctuations the
ca\c of
are V
indeed
and its
\‘ery
effective
compounds.
in
reducing
Ncverthelcss.
the
the
supcrconductlng
present
thcor!
stiII
H.
Winter
et al.
I Calculation
of correlation
277
functions
So it seems necessary to try a overestimates the value of T, of V (TzxP ~5.4 K) appreciably. as well by coupling the electrons to the density fluctuations. Work first-principles theory for p * “““sp’n along this line, implying the calculation of x” in the LDA-RPA approximation, is in progress.
4. Limitations
of the LDA-RPA
It is interesting to apply the LDA-RPA to the parent material of high-temperature superconductors, LazCuO,, in spite of the fact that other investigations [12-141. show that spin-polarized LSDA to be unable to account for the antiferromagnetic semiconducting ground state of this substance. In this way one learns about the degree of failure and the main causes for that failure. Our calculations of the BZ boundary in the x”(P, p;(j) [I51 s h ow the following features: as the wave vector q approaches (1, 1,O) direction, matrix element effects become more and more effective in depressing the contributions of band 17 crossing the Fermi level (fig. 7). On the other hand, interband contributions become important. As a whole, however, x ’ is too small by a factor of three to five to allow for a magnetic phase transition. This disencouraging result could cause one to abandon the LDA altogether and to resort instead to some kind of Hubbard model-like treatment of this strongly correlated electron system.
5. Summary We have demonstrated in this contribution that band structure theory based on the local spin density approach is not only able to account for the ground state properties of a wide class of materials but also leads to a reasonable description of excited states as it provides an approximation to the one-particle Green function entering the evaluation of correlation functions. In spite of the simple approximation
la)
t
Fig. 7. The contributions matrix-element effects.
of band
17 to Im ~‘(9.
9; w) of La?CuO,
both
neglecting
(hatched
lines) and including
(full
lines)
used
for
the
clcctronic
K-matrix
we
self-energies
dcnsit4’-“orr”lation for
the
obtain
and function
“classical”
;I consistent
the
quantities
along
the
superconductors
LVe conclude that the drawhacks
;trc
not
mainlv
electronic
the
result
Work ceramic
of the
one-particle
states
sp;ic~-averaged instead
of
is undet- way systems
procccdiugs,
nlethods encouraging
References
by
vc2t-v
bjth
tht: results.
that
going
promising for
RPA
and
prck~ious
this
remedy
LDA.
connection
self-interaction
example.
the
hut
solid
the
ot
our
to ;I fully
method
the
A\
gase\
wattcring
failure
of
the
(SIC‘)
[ IS]
and
prcwnt eutcnsivelv
[ lb.
171. which
or some
patxmc~et’. functioti~
cmploving
unrcali~tk
barking
with
t-c‘;tl
function\.
more
implctiicntatic)n
the
theor\
c‘clrrel;ition
;ind
interactic)n
described
is the
of
10
mitt-oscopic
lot.
cot~wqucn~‘c
umkhpp
corrections noble
lexl theorie
arc‘
neglecting
to the
no1-111;11 and the ;IIIOIIWI~~LI~
the estcn\ion
jelliitm-model-liar
eluctt-on-fluctuation
is intended beyond
both ‘I‘hc
~thovc ma> well
used therchv
encrgie4.
tor them.
use of the ad hoc ~aluc~ Ior the McMillan
the
of
thcorl from
sketched
spcc-dqwndent
in
so-called
lines
avoiding
p
unified dcrivcd
approxh
con\:ctitional
tranxition-inctal
111 the
clsewhct-c
htld
IGI\C alread! oxidc\
~‘25~ itI
01
thcx,
~tt~uc‘tut~c~ ytcldcci
[ l(Jj.
271-278
A calculation
of correlation
functions based on band structure
H. Winter”, Z. Szotekb and W.M. Temmerman” “Kernforsckur2~.~zenrrum Karlsruhe. INFP, P. 0. Box 3640, W-7_SOO Karlsruhe. “SERC Dawshury Laboratory. Warrington, WA 44A D. UK
We discuss the evaluation of functions are constructed using equations are approximated by reasonable results for a wide class the case of ceramic materials.
Germany
correlation functions in the framework of the RPA. Whereas the one-particle Green the calculated band structures, the K-matrices of the corresponding Bethc-Salpeter functional derivatives of the exchange-correlation potentials. This approach leads to of transition metals and compounds. We point out extensions of the theory. necessary in
1. Formulation In addition to one-particle quantities that are directly obtained from band structure calculations the knowledge of correlation functions is vital for the understanding of both equilibrium and nonequilibrium properties of solids. This is obvious for the spin-density-spin-density correlation function, with magnetic phenomena. However, it turns out x“, and the orbital susceptibility, x “, in connection that x’ together with the density correlation function, x”, has also to be known in order to account for superconducting properties. To calculate any correlation function, x, we need two ingredients: an approximation for the “non-interacting” part xp and the particle-hole irreducible K-matrix. The results of a satisfactory theory for x should both compare favourably to scattering experiments that probe its spectral density directly (magnetic neutron scattering in the case of x’ and x0, ELS in the case of x”) and lead to reasonable values for the derived quantities like effective masses, superconducting transition temperafirst-principles theory is desirable. A tures, etc. To fulfill these requirements a parameter-free, reasonable first approach worthwhile to be tested is the RPA-LDA approximation, where xp is approximated by the “bubble” diagram consisting of the one-particle Green function of the LDA response of HLDA to an appropriate Hamiltonian, fILDA, and K is derived from the linear unretarded external field. The Bethe-Salpeter-equation for the lattice Fourier transform x,(p~, ~‘7’; w) of x, which contains all the information, then reads [l]:
restricted to the Wigner-Seitz cells of the sites T, T’, . . , Here p, p’, . . . , are the local coordinates within one unit cell. The expression for the lattice Fourier transform of K, K,, depends on the kind of correlation function in question, in particular, KJ pi, ~‘7’)
forx,
= - ; [8V,,(n,
m) /6m]6(p
- p’)S,,,.
= K;,
(24
,
KJ PT, ~‘7’) = 0 , 0921.3526/91/$03.50
0
1991 ~ Elsevier
(2b) Science
Publishers
B.V. (North-Holland)
tor x,, It is ;I massive piece of work to evaluate k i ah the l’ollowing formula show\. quantity in terms of the angular momentum-dccomposecl Bloch state coefticienh. I?;( p. F). and the hand cncrgiea tA (. part> of the single-site wave functions,,
I‘0
obtain
Im
,,y“
we
perform
careful
Brillouin
/.onc
integration4
o\‘cr
thaw
~rcgion\
which cxprcac\ ( i , , . the
whcl-e
the\ tratli;ll
tt-an41tion4
~~1.
2. Results for the spin density
correlation
function
We have calculated x” for some systems differing in their spin tluctuation amplitudes 141. Vanadium is an example of a moderately Stoner-enhanced system (S -- 2.7). Iii fig. 1 \vc 4hon the diagonal part of the double real-space Fourier transform of Im x ” for some wa\‘c vector\ 9 in the (1. 0, 0) direction and fig. 2 shows the same for the interacting quantity 4 The sharp peaks at small frequencies and the wave vectors are related to intraband transitrona III the vicinity of the Fermi energy. The interaction enhances them and shifts them to smaller frequcncic\ III proportion to S. Because of matrix-element effects. the widths of x” and % ’ shrink to Lcro ;15 q transitions come in and cnhanccmcnt approaches zero. For increasing q more and more interband effects are of minor importance. As an example for a highly Stoner-enhanced system WC considered Pd( S = 0 ). Figure5 -3 and 4 \hov, lm x”( 9, 9’; w) and Im x‘( 9. 9’; CO). respectively. Again, enhancement effcctx arc most import;lnt ;II small wave vectors and frequencies, where interband transitions rclatcd to the scaffolding structure parts of the energy surfaces near the Fermi surface dominate. In those systems the magnitudes of the differential cross sections for magnetic neutron scattering arc too small to allow for ;I measurcmcnt of Im x‘( 9. 9: w) through the use of contemporary neutron sources. The situation is different for the nearly ferromagnetic compound Ni,Ga 151. the Stoner enh;tncemc~nt of which is estimated to be near 100. from the cxpcrimcnts of ref. [6]. Th c Grnilar compound Ni :A1 i\ ferromagnetic at low temperatures as refs. 171 and [X] have shown. Our results for Im ,y’( 9. 9: CO)in the long-wavelength limit arc displayed in tig. 5 and the quantity Im x’( 9. 9: W);OJ folded with the experimental resolution function (fig. 6) allows for :I direct comparison with the results of ref. (61
ofcorrelationfunctions
H. Winter et al. I Calculation
9
.06
--I
273
---
0.80
--
0.60
q
0.40
_ z ' S'
04
-
0.20
~--
0.10
-
”
0.80
--
0.60
-
0.20
---.
0.10
-
0.05
0.40
0.05
3
---
r.
02
cr--
A _E
__-_.-.- -------_________
c_-___..
0 0
0.2
0.4
0.6
FREQUENCY
a
0.8
1.0
I .2
(t-V)
I
I
I
1
I
I
0.2
0.4
0.6
0.8
1.0
I.:
a
FREQUENCY
(eV)
0.08 0.04 0.06
---
0.80
--
0.60 0.40
0.04
-
0.20
---
0.10
-
0.05
\ 4 0 2
b
FREQUENCY
(eV)
Fig. 1. Im x”( q. q: W) for C’ with q in the (1.0.0) direction. (a). high-frequency range; (b). low-frequency range. q is in units of 27FIa.
b
4
6 FREQUENCY
Fig. 2. Im
8
10
(eV)
,y‘(q. 9; w) for V
In agreement with the experiment are the small widths of the curves (~0.5 meV at q = 0.04 T/U), the high value of the Stoner enhancement (S = 30 at q = 0.04 T/U), which extrapolates to about 100 for q - 0 and the rapid decay of the fluctuation amplitudes with increasing q. We stress again that it is essential to solve the full Bethe-Salpeter equation (1) for x’ instead of using any scalar version of it. Most important are the matrix element effects, because the so-called generalized susceptibility, which adds up the intraband transitions while leaving the matrix elements out differs markedly from the full susceptibility. Indeed, as the investigations of refs. [9] and [lo] show, x0 behaves quite differently from x’ and xp, though one and the same particle-hole transition contributes to both quantities and this difference is entirely the result of matrix element effects.
0 020
0 015
0.010
0.005
0 0
?
t1
3. Derived
4 FREQUENCY
6
Y
I ,_ 1
(e'i)
quantities
As an example WC consider the effect of the electron-spin tluctuation coupling to the normi self-energy. that is its contribution to the electronic mass cnhanccmcnt. It i\ pwsihle to formulate thi< in close analogv to the electron-phonon coupling case. We obtain the follow~in~ wt of cquntions:
27s
H. Winter et al. I Calculation of correlution functions
q=OO2
-E
)
(du
l.W4~
-
sol 020
0
I
I
I
I
I
I
I
080
loo
Ix)
140
I60
180
I
I
14
16
IE
I
040
063
2
0
(b) qz0.05 Cd u
I 0
Frequency Fig. 5. Im
x‘(q, q; w) of Ni,Ga
II 2
4
for small wave vectors.
I
I
I
II
6
a
IO
12
Frequency
CmeV) Fig. 6. Im ,y‘(q. q; perimental resolution
J
imeV
w)/w for Ni,Ga, function.
21
I
folded
with
the
ex-
7‘he
analogy
between
electron-phonon lattice full
Fourier
dependence
on Our
V and 0.16 It
is
yields
for
enhancement
Pd.
of
The
the
7‘,
by for
coupling
Hecause
~lrouIl‘, put
the
in
/lq. order
arc compatible parameter-free like
from
using
the
Note. 2nd to
one
Grlc
get
and
h’;,
that it i4 exential
the correlation
the
with
:~ncl the
to emplo\
t’unction.
reasonable
magnetic
specific
\aluc5
the
1 ‘. 111-thcll
1hc ITI;IS\
for
band
neutron
No simple
structure
heat mcauremcnt~.
baxccl on band
KPA
\cattcring
\tructurc cros\
\imult:mcou\l!
xxtion.
scalin g hetb\ecn the latter
the fact that WC have taken
the
electron
of x‘
;I
McMillan
the
Green
mechanism
in parallel
(_Y. J’ = F, ).
F~ cc.4:“<“1’1”” which to 0. I3 with
x. the
account
the
function>
instead
of
Stoncl
quantity
of the broken
espre\sccl
transition
and ~lpE’r”“ir-natinf
and alloys.
the
the
WC have formulated and
elect-ran-phonoll
and
.\
translational
reorting
to
an\
LX_
the
(4) In
\uggcsts
that
\+c
prcvlou\
tact.
dvnamic
C‘oulomb
correct
the \ ;iluc’\ oi
a11 Eliashbergh clcctron-spin
I
Inlcl
cquatlor fluctuation
It is
range of x‘ the gap now depends K”‘““‘.
relevant
energy
for
II!
temperature\.
’ . of the order- of 0. 1.3 failccl to predict
Whereas
stands
respect
F
containing
[ I I].
coupling
alone
compounds
frcqucncy
energy-variable
fluctuation
superconducting
mechanism
parameter.
V and V-based self-energy
energy
spin
on
on the phonon
of the extended
equal
propagator
mass enhancement.
result
anomalous
F and a real Fermi
of
based
effects
the
the
quantities
by
influence
, especially
for
(I ‘b on
is obvious.
&sumptic;ns.
the
calculations action
IOU values that
for
systems
formulation
investigate
‘I‘hcsc
findings
jellium-model-like
function side
q. p and p’
variables
results
These
Eliashberg
on the other
arc
and the electronic
is observed. symmetry
their
to observe
reasonable
the
of the particle-hole
results
gratifying
and
potential
transform
enhancement.
for
I( lo)
coupling
the usual phonon region
of
the s17in-independent
to ;I cut-off
of 50[:,‘:::“.
ti““”
on both the Matsubnra
kernel. ” with
part
is essentially respect
for- I’
to the
to .\ and 1‘ ih ;I tcu
of the (‘oulomb
OUI- results
trcquc‘nclc’x
restricted
inter&on.
ha
CL’
been
;iic‘
I‘, ==20 K. if K“““”
is put
‘f‘, -9.5 if k“‘““” We transition
K
equal
to zero.
and
.
is included. conclude
that
spin
temperatures
in
fluctuations the
ca\c of
are V
indeed
and its
\‘ery
effective
compounds.
in
reducing
Ncverthelcss.
the
the
supcrconductlng
present
thcor!
stiII
H.
Winter
et al.
I Calculation
of correlation
277
functions
So it seems necessary to try a overestimates the value of T, of V (TzxP ~5.4 K) appreciably. as well by coupling the electrons to the density fluctuations. Work first-principles theory for p * “““sp’n along this line, implying the calculation of x” in the LDA-RPA approximation, is in progress.
4. Limitations
of the LDA-RPA
It is interesting to apply the LDA-RPA to the parent material of high-temperature superconductors, LazCuO,, in spite of the fact that other investigations [12-141. show that spin-polarized LSDA to be unable to account for the antiferromagnetic semiconducting ground state of this substance. In this way one learns about the degree of failure and the main causes for that failure. Our calculations of the BZ boundary in the x”(P, p;(j) [I51 s h ow the following features: as the wave vector q approaches (1, 1,O) direction, matrix element effects become more and more effective in depressing the contributions of band 17 crossing the Fermi level (fig. 7). On the other hand, interband contributions become important. As a whole, however, x ’ is too small by a factor of three to five to allow for a magnetic phase transition. This disencouraging result could cause one to abandon the LDA altogether and to resort instead to some kind of Hubbard model-like treatment of this strongly correlated electron system.
5. Summary We have demonstrated in this contribution that band structure theory based on the local spin density approach is not only able to account for the ground state properties of a wide class of materials but also leads to a reasonable description of excited states as it provides an approximation to the one-particle Green function entering the evaluation of correlation functions. In spite of the simple approximation
la)
t
Fig. 7. The contributions matrix-element effects.
of band
17 to Im ~‘(9.
9; w) of La?CuO,
both
neglecting
(hatched
lines) and including
(full
lines)
used
for
the
clcctronic
K-matrix
we
self-energies
dcnsit4’-“orr”lation for
the
obtain
and function
“classical”
;I consistent
the
quantities
along
the
superconductors
LVe conclude that the drawhacks
;trc
not
mainlv
electronic
the
result
Work ceramic
of the
one-particle
states
sp;ic~-averaged instead
of
is undet- way systems
procccdiugs,
nlethods encouraging
References
by
vc2t-v
bjth
tht: results.
that
going
promising for
RPA
and
prck~ious
this
remedy
LDA.
connection
self-interaction
example.
the
hut
solid
the
ot
our
to ;I fully
method
the
A\
gase\
wattcring
failure
of
the
(SIC‘)
[ IS]
and
prcwnt eutcnsivelv
[ lb.
171. which
or some
patxmc~et’. functioti~
cmploving
unrcali~tk
barking
with
t-c‘;tl
function\.
more
implctiicntatic)n
the
theor\
c‘clrrel;ition
;ind
interactic)n
described
is the
of
10
mitt-oscopic
lot.
cot~wqucn~‘c
umkhpp
corrections noble
lexl theorie
arc‘
neglecting
to the
no1-111;11 and the ;IIIOIIWI~~LI~
the estcn\ion
jelliitm-model-liar
eluctt-on-fluctuation
is intended beyond
both ‘I‘hc
~thovc ma> well
used therchv
encrgie4.
tor them.
use of the ad hoc ~aluc~ Ior the McMillan
the
of
thcorl from
sketched
spcc-dqwndent
in
so-called
lines
avoiding
p
unified dcrivcd
approxh
con\:ctitional
tranxition-inctal
111 the
clsewhct-c
htld
IGI\C alread! oxidc\
~‘25~ itI
01
thcx,
~tt~uc‘tut~c~ ytcldcci
[ l(Jj.