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PhysRevB.90.115421.pdf | PHYSICAL REVIEW B 90, 115421 (2014)
Multiterminal Anderson impurity model in nonequilibrium: Analytical perturbative treatment
Nobuhiko Taniguchi*
Institute of Physics, University of Tsukuba, Tennodai Tsukuba 305-8571, Japan
(Received 1 May 2014; revised manuscript received 28 August 2014; published 16 September 2014)
We study the nonequilibrium spectral function of the single-impurity Anderson model connecting with
multiterminal leads. The full dependence on frequency and bias voltage of the nonequilibrium self-energy andspectral function is obtained analytically up to the second-order perturbation regarding the interaction strength U.
High- and low-bias voltage properties are analyzed for a generic multiterminal dot, showing a crossover from theKondo resonance to the Coulomb peaks with increasing bias voltage. For a dot where the particle-hole symmetryis not present, we construct a current-preserving evaluation of the nonequilibrium spectral function for arbitrarybias voltage. It is shown that finite-bias voltage does not split the Kondo resonance in this order, and no specificstructure due to multiple leads emerges. Overall bias dependence is quite similar to finite-temperature effect fora dot with or without the particle-hole symmetry.
DOI: 10.1103/PhysRevB.90.115421 PACS number(s): 73 .63.Kv,73.23.Hk,71.27.+a
I. INTRODUCTION
Understanding strong correlation effect away from equi-
librium has been one of the most interesting yet challeng-
ing problems in condensed matter physics. A prominent
realization of such phenomena is embodied in quantumtransport through a nanostructure under finite-bias voltage.To understand the interplay of the correlation effect andnonequilibrium nature, the nonequilibrium version of thesingle-impurity Anderson model (SIAM) and its extensionshave been serving and continue to do so as a central theoretical
model. The SIAM is indeed considered to be one of the best-
studied strongly correlated models, and despite its apparentsimplicity, it exhibits rich physics already in equilibrium,such as the Coulomb blockade and the Kondo physics thathave been observed in experiments. Equilibrium propertiesof the SIAM have been well understood thanks to concertedefforts of several theoretical approaches over the years: byperturbative treatment, Fermi-liquid description, as well as
exact results by the Bethe ansatz method, and numerical
renormalization group (NRG) calculations (see, for instance,[1–3].) In contrast, the situation of the nonequilibrium SIAM is
not so satisfactory. Each of the above approaches has met somedifficulty in treating nonequilibrium phenomena. A theoreticalapproach that can deal with the strong correlation effect innonequilibrium is still called for.
Notwithstanding, a number of analytical and numerical
methods have been devised to investigate nonequilibrium sta-tionary phenomena: nonequilibrium perturbation approaches[4–8] and its modifications [ 9–11], the noncrossing approxi-
mation [ 12], the functional renormalization group treatment
[13], quantum Monte Carlo calculations on the Keldysh
contour [ 14,15], the iterative real-time path-integral method
[16], and so on. Unfortunately, those approaches fail to give a
consistent picture concerning the finite-bias effect on the dot
spectral function, particularly regarding a possible splitting ofthe Kondo resonance.
As for the equilibrium SIAM, the second-order perturbation
regarding the Coulomb interaction Uon the dot [ 17–20]
is known to capture essential features of Kondo physics
*taniguchi.n.gf@u.tsukuba.ac.jpand agrees qualitatively well with exact results obtained by
the Bethe ansatz and NRG approaches [ 1,2,20]. Such good
agreement seems to persist in nonequilibrium stationary state
at finite-bias voltage. For the two-terminal particle-hole (PH)
symmetric SIAM, a recent study by M ¨uhlbacher et al. [8]
showed that the nonequilibrium second-order perturbation
calculation of the spectral function agrees with that calcu-lated by the diagrammatic quantum Monte Carlo simulation,
excellently up to interaction strength U∼2γ(where γis the
total relaxation rate due to leads), pretty well even for U/lessorsimilar8γ
at bias voltage eV/lessorsimilar2γ. A typical magnitude of U/γ of a
semiconductor quantum dot is roughly 1 ∼10 depending on
the size and the configuration of the dot. Therefore, there is a
good chance of describing a realistic system within the validity
of nonequilibrium perturbation approach.
The great advantage of semiconductor dot systems is to
allow us to control several physical parameters. Those include
changing gate voltage as well as configuring a more involved
structure such as a multiterminal dot [ 21–26] or an interferom-
eter embedding a quantum dot. Theoretical treatments oftenlimit themselves to a system with the PH symmetry wherethe dot occupation number is fixed to be one half per spin.Although assuming the PH symmetry makes sense and comesin handy in extracting the essence of the Kondo resonance,we should bear in mind that such symmetry is not intrinsicand can be broken easily in realistic systems, by gate voltage,asymmetry of the coupling with the leads, or asymmetric dropsof bias voltage [ 27,28]. The PH asymmetry commonly appears
in a multiterminal dot or in an interferometer embeddinga quantum dot. It is also argued that the effect of the PHasymmetry might be responsible for the deviation observedin nonequilibrium transport experiments from the “universal”
behavior of the PH symmetric SIAM [ 27,28]. To work on
realistic systems, it is imperative to understand how the PHasymmetry affects nonequilibrium transport.
In this paper, we examine the second-order nonequilibrium
perturbation regarding the Coulomb interaction Uof the
multiterminal SIAM. The PH symmetry is not assumed, andmiscellaneous types of asymmetry of couplings to the leadsand/or voltage drops are incorporated as a generic multitermi-nal configuration. Our main focus is to provide solid analytical
results of the behavior of the nonequilibrium self-energy and
1098-0121/2014/90(11)/115421(12) 115421-1 ©2014 American Physical SocietyNOBUHIKO TANIGUCHI PHYSICAL REVIEW B 90, 115421 (2014)
hence the dot spectral function for the full range of frequency
and bias voltage, within the validity of the second-orderperturbation theory of U. The result encompasses Fermi-liquid
behavior as well as incoherent non-Fermi-liquid contribution,showing analytically that increasing finite-bias voltage leads toa crossover from the Kondo resonance to the Coulomb block-
ade behaviors. This work contrasts preceding perturbative
studies [ 4–7,29] whose evaluations relied on either numerical
means or a small-parameter expansion of bias voltage and fre-quency. The only notable exception, to the author’s knowledge,is a recent work by M ¨uhlbacher et al. [8], which succeeded
in evaluating analytically the second-order self-energy forthe two-terminal PH symmetric dot. Intending to apply suchanalysis to a wider range of realistic systems and examine
the effect that the two-terminal PH symmetric SIAM cannot
capture, we extend their approach to a generic multiterminaldot where the PH symmetry may not necessarily be present.
An embarrassing drawback of using the nonequilibrium
perturbation theory is that when one has it naively apply to thePH asymmetric SIAM, it may disrespect the preservation ofthe steady current [ 4]. As a result, one then needs some current-
preserving prescription, and different self-consistent schemes
have been proposed and adopted [ 9,11,30]. As will be seen,
the current-preserving condition involves all the frequencyranges, not only of the low-frequency region that validatesFermi-liquid description, but also of the incoherent non-Fermi-liquid part [see Eq. ( 6)]. Therefore, an approximation based on
the low-energy physics, particularly the Fermi-liquid picture,should be used with care. The self-energy we will construct
analytically is checked to satisfy the spectral sum rule at
finite-bias voltage, so that we regard it as giving a consistentdescription for the full range of frequency in nonequilibrium.By taking its advantage, we also demonstrate a self-consistent,current-preserving calculation of the nonequilibrium spectralfunction for a system where the PH symmetry is not present.
The paper is organized as follows. In Sec. II, we introduce
the multiterminal SIAM in nonequilibrium. We review briefly
how to obtain the exact current formula by clarifying the roleof the current conservation at finite-bias voltage. Section III
presents analytical expression of the retarded self-energy fora general multiterminal dot up to the second order of theinteraction strength. Subsequently, in Sec. IV, we examine
and discuss its various analytical behaviors including high- andlow-bias voltage limits. Section Vis devoted to constructing
a nonequilibrium spectral function using the self-energy
obtained in the previous section. We focus our attention on twoparticular situations: (1) self-consistent, current-preservingevaluation of the nonequilibrium spectral function for thetwo-terminal PH asymmetric SIAM, and (2) multiterminaleffect of the PH symmetric SIAM. Finally, we conclude inSec. VI. Mathematical details leading to our main analytical
result ( 21) as well as other necessary material regarding
dilogarithm are summarized in Appendices.
II. MULTITERMINAL ANDERSON IMPURITY MODEL
AND THE CURRENT FORMULA
A. Model
The model we consider is the single-impurity Anderson
model connecting with multiple leads a=1,..., N whosechemical potentials are sustained by μa. The total Hamiltonian
of the system consists of H=HD+HT+/summationtext
aHa, where HD,
HT, andHarepresent the dot Hamiltonian with the Coulomb
interaction, the hopping term between the dot and the leads,and the Hamiltonian of a noninteracting lead a, respectively.
They are specified by
H
D=/summationdisplay
σ/epsilon1dnσ+Un↑n↓, (1)
HT=/summationdisplay
a,σ(Vdad†
σcakσ+Vadc†
akσdσ), (2)
where nσ=d†
σdσis the dot electron number operator with
spinσandcakσare electron operators at the lead a.I nt h e
following, we consider the spin-independent transport case,but an extension to the spin-dependence situation such asin the presence of magnetic field or ferromagnetic leads isstraightforward. When applying the wide-band limit, all theeffects of the lead aare encoded in terms of its chemical
potential μ
aand relaxation rate γa=π|Vda|2ρa, where ρais
the density of states of the lead a. The dot level /epsilon1dcontrols
the average occupation number on the dot; it correspondsroughly to 2, 1, 0 for /epsilon1
d/lessorsimilar−U,−U/lessorsimilar/epsilon1d/lessorsimilar0, and 0 /lessorsimilar/epsilon1d,
respectively. The PH symmetry is realized when /epsilon1d=−U/2
and/angbracketleftnσ/angbracketright=1
2[see Eqs. ( 6) and ( 13)].
B. Multiterminal current and current conservation
We here briefly summarize how the current through the
dot is determined in a multiterminal setting. Special attentionis paid to the role of the current conservation because it hasbeen known that nonequilibrium perturbation calculation doesnot respect it in general [ 4]. We illustrate how to ensure the
current conservation by a minimum requirement. The argu-ment following is valid regardless of a specific approximationscheme chosen, whether nonequilibrium perturbation or anyother approach.
Following the standard protocol of the Keldysh formulation
[31], we start with writing the current I
aflowing from the lead
ato the dot in terms of the dot’s lesser Green’s function G−+
σ
and the retarded one GR
σ:
Ia=−e
π/planckover2pi1/summationdisplay
σ/integraldisplay
dω/bracketleftbig
iγaG−+
σ(ω)−2γafaImGR
σ(ω)/bracketrightbig
,(3)
where fa(ω)=1/(eβ(ω−μa)+1) is the Fermi distribution
function at the lead a. As the present model preserves the
total spin as well as charge, the net spin current flowing tothe dot should vanish in the steady state, which imposes theintegral relation between G
−+
σandGR
σ:
/integraldisplay∞
−∞dω/bracketleftbig
iγ G−+
σ(ω)+2γ¯f(ω)I mGR
σ(ω)/bracketrightbig
=0. (4)
Here, we have introduced the total relaxation rates γ=/summationtext
aγa
and the effective Fermi distribution ¯fweighted by the leads
¯f(ω)=/summationdisplay
aγa
γfa(ω). (5)
115421-2MULTITERMINAL ANDERSON IMPURITY MODEL IN . . . PHYSICAL REVIEW B 90, 115421 (2014)
When we ignore the energy dependence of the relaxation rates
γa, we can recast Eq. ( 4) into a more familiar form
nσ=−1
π/integraldisplay∞
−∞dω ¯f(ω)I mGR
σ(ω)( 6 )
because 2 iπnσ=/integraltext
dωG−+
σ(ω) is the definition of the exact
dot occupation number. Note the quantity −ImGR
σ(ω)/πis
nothing but the exact dot spectral function out of equilibrium.We emphasize that Eq. ( 4) [or equivalently Eq. ( 6)] is
the minimum, exact requirement that ensures the currentpreservation. It constrains the exact G
−+andGRthat depend
on the interaction as well as bias voltage in a nontrivial way.One can accordingly eliminate/integraltext
dωG
−+(ω)i nIa, to reach
the Landauer-Buttiker–type current formula at the lead a,
Ia=−e
π/planckover2pi1/summationdisplay
b,σγaγb
γ/integraldisplay
dω(fb−fa)I mGR
σ(ω). (7)
Or, the current conservation allows us to write it as
Ia=eγa
/planckover2pi1/summationdisplay
σ[nσ−Nσ(μa)], (8)
where Nσ(ε) is the exact number of states with spin σat finite
temperature in general, defined by
Nσ(μ)=−1
π/integraldisplay
dεImGR
σ(ε)
eβ(ε−μ)+1. (9)
It tells us that differential conductance ∂Ia/∂μawith fixing
all other μ’s is proportional to the nonequilibrium dot spectral
function, provided changing μadoes not affect the occupation
number [ 21–24]. Such situation is realized, for instance, when
a probe lead couples weakly to the dot.
The case of a noninteracting dot always satisfies the current-
preserving condition ( 4)a sG−+
σ(ω)=− 2i¯f(ω)I mGR
σ(ω)
holds for any ω; the distribution function of dot electrons
fdot(ω)=G−+(ω)/(2iπ) is equal to −¯f(ω)I mGR
σ(ω)/π.
This is not the case for an interacting dot, however. As forthe interacting case, not so much can be said. We only see thespecial case with the two-terminal PH symmetric dot satisfyEq. ( 6) by choosing n
σ=1
2irrespective of interaction strength.
Except for this PH symmetric case, a general connectionbetween G
−+andGRis not known so far. It is remarked that,
based on the quasiparticle picture, a noninteracting relationG
−+
σ(ω)=− 2i¯f(ω)I mGR
σ(ω) is sometimes used to deduce
an approximate form of G−+out of GRfor an interacting
dot. Such approximation is called the Ng’s ansatz [ 32,33].
Although it might be simple and handy, its validity is far fromclear. We will not rely on such additional approximation below.It is also important to distinguish in Eq. ( 6) the electron occupa-
tion number n
σfrom the quasiparticle occupation number ˜nσ,
as the two quantities are different at finite-bias voltage since theLuttinger relation holds only in equilibrium [ 34]. Contribution
to the dot occupation number comes from all ranges offrequency, including the incoherent part. One sees fulfilling thespectral weight sum rule −/integraltext
∞
−∞dωImGR(ω)/π=1 crucial
to have the dot occupation number nσnormalized correctly.
In general, one needs to determine nσappropriately to satisfy
Eq. ( 6) as a function of interaction and chemical potentials of
the leads. The applicability of quasiparticle approaches thatignores the incoherent part is unclear.
FIG. 1. The Hartree-type contribution of the self-energy
Uτ 3n¯σ=±Un ¯σ. The double line refers to the exact Green’s function.
III. ANALYTICAL EV ALUATION OF THE SELF-ENERGY
In this section, we evaluate analytically the nonequilibrium
retarded self-energy up to the second order of interactionstrength Ufor the multiterminal SIAM. We first examine
the contribution at the first order and the role of currentpreservation. Then, we present the analytical result of thesecond-order self-energy in terms of dilogarithm.
Following the standard treatment of the Keldysh formu-
lation [ 35], the nonequilibrium Green’s function and the
self-energy take a matrix structure
ˆG=/parenleftbigg
G
−−G−+
G+−G++/parenrightbigg
;ˆ/Sigma1=/parenleftbigg
/Sigma1−−/Sigma1−+
/Sigma1+−/Sigma1++/parenrightbigg
,(10)
satisfying symmetry relations G−−+G++=G−++G+−
and/Sigma1−−+/Sigma1++=−/Sigma1−+−/Sigma1+−. The retarded Green’s
function is defined by GR=G−−+G−+; the retarded self-
energy, by /Sigma1R=/Sigma1−−+/Sigma1−+.
To proceed with the evaluation, it is convenient to classify
self-energy diagrams into two types: the Hartree-type diagram(Fig. 1) that can be disconnected by cutting a single interaction
line, and the rest which we call the correlation part and reassignthe symbol /Sigma1to. The latter starts at the second order. The
resulting Green’s function (matrix) takes a form of
ˆG
σ(ω)=/bracketleftbigˆG−1
0σ(ω)−Uτ 3n¯σ−ˆ/Sigma1σ(ω)/bracketrightbig−1, (11)
where τ3represents a Pauli matrix of the Keldysh structure,
andn¯σrefers to the exact occupation number of the dot elec-
tron with the opposite spin. Accordingly, the correspondingretarded Green’s function becomes
G
R
σ(ω)=1
ω−Edσ+iγ−/Sigma1Rσ(ω), (12)
where Edσ=/epsilon1d+Un ¯σis the Hartree level of the dot.
A. Current preservation at the first order
Before starting evaluating the correlation part /Sigma1Rthat starts
contributing at the second order, it is worthwhile to examinethe current-preserving condition ( 6) at the first order. At this
order, it reduces to the self-consistent Hartree-Fock equationfor the dot occupation number n
0
σ:
n0
σ=1
2+1
π/summationdisplay
aγa
γarctan/bracketleftbiggμa−/epsilon1d−Un0
¯σ
γ/bracketrightbigg
.(13)
It shows how the two-terminal PH symmetric SIAM is special
by choosing /epsilon1d+U/2=0,γa=γ/2, and μa=±eV/2; the
115421-3NOBUHIKO TANIGUCHI PHYSICAL REVIEW B 90, 115421 (2014)
E+ , , ,
FIG. 2. The correlation part of the self-energy at the second-order
contribution.
second term of the right-hand side vanishes by having the
solution n0
σ=1
2even at finite-bias voltage. It also indicates
that the current preservation necessarily has the occupationnumber depend on asymmetry of the lead couplings as well asinteraction strength for the PH asymmetric SIAM. Indeed, fora small deviation from the PH symmetry and bias voltage, wesee the Hartree-Fock occupation number behave as
n
0
σ−1
2≈¯μ−/epsilon1d−U/2
πγ/parenleftbigg
1−U
πγ+···/parenrightbigg
, (14)
where ¯ μis the average chemical potential weighted by leads
¯μ=/summationdisplay
aγa
γμa. (15)
Note ¯ μvanishes when no bias voltage applies, as we
incorporate the overall net offset by leads into /epsilon1d.
B. Analytical evaluation of the correlation part
of the self-energy
Following the standard perturbation treatment of the
Keldysh formulation, we see there is only one diagramcontributing to /Sigma1
R
σat the second order (Fig. 2) after eliminating
the Hartree-type contribution. The contribution is written as
ˆ/Sigma1(t1,t2)=−i/planckover2pi1U2/parenleftbigg
G−−
12/Pi1−−21−G−+
12/Pi1+−21
−G+−
12/Pi1−+21G++12/Pi1++21/parenrightbigg
,(16)
where Gij
12=Gij(t1,t2) refer to to the unperturbed Green’s
functions (including the Hartree term), whose concrete ex-pressions are found in Appendix A. The polarization matrix ˆ/Pi1
is defined by /Pi1ij
12=i/planckover2pi1Gij
12Gji21(Fig. 3).1
As was shown by the current formula in the previous
section, we need only the dot spectral function to studyquantum transport, hence, /Sigma1
Rsuffices. Therefore, it is more
advantageous to work on the representation in terms ofthe retarded, advanced, and Keldysh components, where thepolarization parts become
/Pi1
R
12=i/planckover2pi1
2/bracketleftbig
GR
12GK21+GK
12GA21/bracketrightbig
, (17a)
/Pi1A
12=i/planckover2pi1
2/bracketleftbig
GA
12GK21+GK
12GR21/bracketrightbig
, (17b)
/Pi1K
12=i/planckover2pi1
2/bracketleftbig
GK
12GK21+GR
12GA21+GA
12GR21/bracketrightbig
, (17c)
1We define the polarization to satisfy the symmetric relation /Pi1−−+
/Pi1−−=/Pi1−++/Pi1+−.i j
E+ , E,
FIG. 3. The polarization part.
and their Fourier transformations are given in Appendix B.
Accordingly, we can express the retarded self-energy /Sigma1Ras
/Sigma1R
σ(ω)=−iU2
4π[I1(ω)+I2(ω)], (18)
where
I1(ω)=/integraldisplay+∞
−∞dEGR
σ(E+ω)/Pi1K
¯σ(E), (19)
I2(ω)=/integraldisplay+∞
−∞dEGK
σ(E+ω)/Pi1A
¯σ(E). (20)
The above second-order expression of /Sigma1Ris standard, but it
has so far been mainly used for numerical evaluation, quiteoften restricted for the two-terminal PH symmetric SIAM. Weintend to evaluate Eqs. ( 19) and ( 20) analytically for the generic
multiterminal SIAM, along the line employed in Ref. [ 8].
Delegating all the mathematical details to Appendices C
andD, we summarize our result of the analytical evaluation of
/Sigma1
Ras follows:
/Sigma1R
σ(ω)=iγU2
8π2(ω−Edσ+iγ)/bracketleftbigg/Xi11(ω−Edσ)
ω−Edσ−iγ
+/Xi12(ω−Edσ)
ω−Edσ+3iγ+/Xi13
2iγ/bracketrightbigg
. (21)
Here, functions /Xi1i(i=1,2,3) are found to be (using ζaσ=
μa−Edσ)
/Xi11(ε)=2π2ε
iγ+/summationdisplay
a,b,β4γaγb
γ2/bracketleftbigg
Li2/parenleftbigg−ε+ζaσ
βζb¯σ+iγ/parenrightbigg
+Li2/parenleftbigg−ε−βζb¯σ
−ζaσ+iγ/parenrightbigg
+1
2Log2/parenleftbigg−ζaσ+iγ
βζb¯σ+iγ/parenrightbigg/bracketrightbigg
+/summationdisplay
a,b,β4γaγb
γ2/bracketleftbigg
Li2/parenleftbigg−ε+βζa¯σ
βζb¯σ+iγ/parenrightbigg
+1
4Log2/parenleftbigg−ζa¯σ+iγ
ζb¯σ+iγ/parenrightbigg/bracketrightbigg
, (22a)
/Xi12(ε)=6π2−/summationdisplay
a,b,β4γaγb
γ2/bracketleftbigg
/Lambda1/parenleftbiggε−ζaσ+2iγ
βζb¯σ+iγ/parenrightbigg
+/Lambda1/parenleftbiggε−βζb¯σ+2iγ
ζaσ+iγ/parenrightbigg
+1
2Log2/parenleftbiggζaσ+iγ
βζb¯σ+iγ/parenrightbigg/bracketrightbigg
−/summationdisplay
a,b,β4γaγb
γ2/bracketleftbigg
/Lambda1/parenleftbiggε+βζa¯σ+2iγ
βζb¯σ+iγ/parenrightbigg
+1
4Log2/parenleftbigg−ζa¯σ+iγ
ζb¯σ+iγ/parenrightbigg/bracketrightbigg
, (22b)
/Xi13=/bracketleftbigg/summationdisplay
a2γa
γLog/parenleftbigg−ζa¯σ+iγ
ζa¯σ+iγ/parenrightbigg/bracketrightbigg2
, (22c)
115421-4MULTITERMINAL ANDERSON IMPURITY MODEL IN . . . PHYSICAL REVIEW B 90, 115421 (2014)
where the summations over β=± 1 as well as terminals
a,b are understood. Function Li 2(z) is dilogarithm, whose
definition as well as various useful properties are summarizedin Appendix C;/Lambda1(z) is defined by
2
/Lambda1(z)=Li2(z)+[Log(1 −z)−Log(z−1)] Log z.(23)
The analytical formula /Sigma1Rgiven in Eqs. ( 21) and ( 22)
constitutes the main result of this paper. Consequently, thenonequilibrium spectral function of the multiterminal SIAMis given analytically for a full range of frequency and biasvoltage, once one chooses n
σto satisfy Eq. ( 6). The result
also applies to a more involved structured system, such as aninterferometer embedding a quantum dot, by simply replacing/epsilon1
dandγato take account of those geometric effects.
IV . V ARIOUS ANALYTICAL BEHA VIORS
Having obtained an explicit analytical form of the second-
order self-energy /Sigma1R(ω) at arbitrary frequency and bias
voltage, we now examine its various limiting behaviors. Mostof those limiting behaviors have been known for the two-terminal PH symmetric SIAM, so it is assuring to reproducethose expressions in such a case. Simultaneously, our resultsfollowing provide multiterminal, PH asymmetric extensionsof those asymptotic results.
A. Equilibrium dot with and without the PH symmetry
We can reproduce the equilibrium result by setting all the
chemical potentials equal, μaσ=Edσ=/epsilon1d+Un ¯σ. Then, we
immediately see /Xi13=0 and
/Xi11=8/bracketleftbiggπ2
4/parenleftbiggεσ
iγ/parenrightbigg
+3L i 2/parenleftbigg−εσ
iγ/parenrightbigg/bracketrightbigg
, (24)
/Xi12=8/bracketleftbigg3π2
4−3/Lambda1/parenleftbiggεσ+2iγ
iγ/parenrightbigg/bracketrightbigg
, (25)
where εσ=ω−Edσ. As a result, the correlation part of the
self-energy in equilibrium becomes
/Sigma1R
σ(ω)=iγU2
π2(εσ+iγ)/bracketleftBiggπ2
4/parenleftbigεσ
iγ/parenrightbig
+3L i 2/parenleftbig−εσ
iγ/parenrightbig
εσ−iγ
+3π2
4−3/Lambda1/parenleftbig
2+εσ
iγ/parenrightbig
εσ+3iγ/bracketrightBigg
. (26)
The PH symmetric case in particular corresponds to εσ=ω.
It reproduces the perturbation results by Yamada and Yosida[17–19] up to the second order of U, when we expand the above
for small ω. The PH symmetric result is indeed identical with
the one obtained in Ref. [ 8] for arbitrary frequency [see also
Eq. ( 27)].
2The definition of /Lambda1(z) is equivalent to that given in Ref. [ 8],
but we prefer writing it in this form because its analyticity is more
transparent.B. Nonequilibrium PH symmetric dot connected
with two terminals
M¨uhlbacher et al. [8] have evaluated analytically the
self-energy and the spectral function for the two-terminal PHsymmetric SIAM. In our notation, it corresponds to the caseγ
L=γR=γ/2, and Edσ=0. When we parametrize the two
chemical potentials by μa=ζaσ=aeV/ 2 with a=± 1i n
Eqs. ( 22), the self-energy can be written as
/Sigma1R
σ(ω)=iγU2
8π2(ω+iγ)/bracketleftbigg/Xi11(ω)
ω−iγ+/Xi12(ω)
ω+3iγ/bracketrightbigg
, (27)
where
/Xi11=2π2ω
iγ+6/summationdisplay
a,b/bracketleftbigg
Li2/parenleftbigg−ω+aeV/ 2
beV/ 2+iγ/parenrightbigg
+1
4Log2/parenleftbigg−aeV/ 2+iγ
beV/ 2+iγ/parenrightbigg/bracketrightbigg
,
/Xi12=6π2−6/summationdisplay
a,b/bracketleftbigg
/Lambda1/parenleftbiggω−aeV/ 2+2iγ
beV/ 2+iγ/parenrightbigg
+1
4Log2/parenleftbiggaeV/ 2+iγ
beV/ 2+iγ/parenrightbigg/bracketrightbigg
.
The above results are identical with what Ref. [ 8] obtained.
C. Expansion of small bias and frequency
We now employ the small-parameter expansion of /Sigma1R
around the half-filled equilibrium system. Here, we assume
parameters ζaσ=μa−Edσandεσ=ω−Edαare much
smaller than the total relaxation rate γ. The expansion of /Xi11is
found to contain the first- and second-order terms regarding ζaσ
andεσ, while /Xi12,3do only the second-order terms. Therefore,
the result of the expansion up to the second order of thesesmall parameters is presented as
/Sigma1
R
σ(ω)≈iU2
8π2γ/bracketleftbigg
/Xi11−/Xi12
3−/Xi13
2/bracketrightbigg
. (28)
Functions /Xi1ican be expanded straightforwardly by using the
Taylor expansion of dilogarithm in Appendix C.T h e ya r e
found to behave as
/Xi11(ε)≈8/bracketleftbigg(π2−12)ε+4¯μ
4iγ+3ε2+9μ2−6ε¯μ−2¯μ2
4(iγ)2/bracketrightbigg
,
(29)
/Xi12(ε)≈− 8/bracketleftbigg3(−ε2+2ε¯μ+2¯μ2−μ2−2μ2)
4(iγ)2/bracketrightbigg
,(30)
/Xi13≈16 ¯μ2
(iγ)2, (31)
where ¯ μis defined in Eq. ( 15) and we have introduced
μ2=/summationdisplay
aγa
γμ2
a=¯μ2+(δμ)2. (32)
115421-5NOBUHIKO TANIGUCHI PHYSICAL REVIEW B 90, 115421 (2014)
Combining all of these, we reach the small-bias (-frequency)
behavior of the self-energy /Sigma1R
σas
/Sigma1R
σ(ω)≈U2
π2γ2/bracketleftbigg/parenleftbiggπ2
4−3/parenrightbigg
(ω−Edσ)+¯μ/bracketrightbigg
−iU2
2π2γ3[(ω−¯μ)2+3(δμ)2]. (33)
Small-bias expansion of Im /Sigma1Rfor the two-terminal system
has been discussed and determined by the argument basedon the Ward identity [ 36]. The dependence appearing in
Eq. ( 33) fully conforms to it (except for the presence of
the bare interaction instead of the renormalized one). Indeed,correspondence is made clear by noting the parameters ¯ μand
(δμ)
2for the two-terminal case become
¯μ=γLμL+γRμR
γ;(δμ)2=γLγR
γ2(eV)2. (34)
The presence of linear term in ωandVfor the two-terminal
PH asymmetric SIAM was also emphasized recently [ 27].
D. Large-bias-voltage behavior
One expects naively that the limit of large-bias voltage
eV→∞ corresponds to the high-temperature limit T→∞
in equilibrium; it was shown to be so for the two-terminal PHsymmetric SIAM [ 36]. We now show that the same applies to
the multiterminal SIAM where bias voltages of the leads arepairwisely large, i.e., half of them are positively large, and theothers are negatively large.
In the large-bias-voltage limit, all the arguments of dilog-
arithm functions appearing in Eqs. ( 22) become ±1, where
the values of dilogarithm are known (see Appendix C).
Accordingly, the pairwisely large-bias limit of /Xi1
iis found
to be
/Xi11(ε)≈2π2(ε−iγ)
iγ, (35)
/Xi12(ε)≈− 4π2, (36)
/Xi13≈0. (37)
Correspondingly, the retarded self-energy becomes
/Sigma1R
σ(ω)≈U2/4
ω−Edσ+3iγ. (38)
It shows that the result of the multi-terminal SIAM is the same
with that of the two-terminal PH symmetric SIAM except fora frequency shift. Accordingly, the retarded Green’s functionG
R(ω) in this limit is given by
GR
σ(ω)≈1
ω−Edσ+iγ−U2/4
ω−Edσ+3iγ. (39)
The form indicates that for sufficiently strong interaction U/greaterorsimilar
2γ, the dot spectral function has two peaks at Edσ±U/2=
/epsilon1d+U(n¯σ±1/2) with broadening 2 γ, so the system is driven
into the the Coulomb blockade regime. On the other hand,for weak interaction U< 2γ, it has only one peak with twodifferent values of broadening that reduce to γand 3γin the
U→0 limit.
What is the role of the current preservation condition ( 6)
in this limit? It just determines the dot occupation numberexplicitly. In fact, the condition becomes
n
σ=−1
π/summationdisplay
aγa
γIm/integraldisplay(μa−Edσ)/γ
−∞dx
x+i−u2
x+3i(40)
withu=U/(2γ), and nσis independent of the interaction
strength because bias voltage sets the largest scale. One canevaluate the above integral exactly to have
/integraldisplaydx
x+i−u2
x+3i=/summationdisplay
s=±1√
1−u2+s
2√
1−u2Log(x−αs),(41)
where α±=− 2i±i√
1−u2. As a result, expanding it up to
the second order of uleads to
nσ≈/summationdisplay
aγa
γθ(μa)−1
π/summationdisplay
aγa
μa. (42)
The first term corresponds to the occupation number that one
expects naturally from the effective distribution ¯f;i tc o r r e -
sponds, for instance, to γL/(γL+γR) for the two-terminal dot
withμR<0<μLwith|μR,L|→∞ . The second term is the
deviation from it, which is proportional to the average of theinverse chemical potential weighted by the leads.
V . NONEQUILIBRIUM SPECTRAL FUNCTION
We now turn our attention to the behavior of the nonequi-
librium dot spectral function, using our analytical expressionof the self-energy [Eqs. ( 21) and ( 22)]. Below we particularly
focus our attention on the two cases: the two-terminal PHasymmetric SIAM where current preservation has been anissue, and the multiterminal PH symmetric SIAM where therole of multiple leads has been raising questions. In all of thecalculations below, we have checked numerically the validityof the spectral weight sum rule at each configuration of biasvoltages.
A. Self-consistent current-preserving calculation
As was emphasized in Sec. II B, when a dot system does
not retain the PH symmetry, the stationary current is notautomatically conserved and one must impose the current-preservation condition ( 6) explicitly. As the right-hand side
of Eq. ( 6) also depends on the dot occupation number n
σ,
this requires us to determine nσself-consistently by using
the retarded Green’s function in a certain approximation; the
second-order perturbation theory in the present case.
Figure 4shows the result of nonequilibrium dot spectral
function of the two-terminal PH symmetric SIAM at biasvoltage eV=0,0.5,1.5,3.0, and 5 .0γ, which is essentially
the same result with Ref. [ 8] (of a different set of parameters).
The occupation number is fixed to be n
σ=1
2in this case,
so its self-consistent determination is unnecessary. The resultswere compared favorably with those obtained by diagrammaticquantum Monte Carlo calculations [ 8]; a relatively good
quantitative agreement was observed up to U∼8γ(where the
Bethe ansatz Kondo temperature k
BTK=0.055γ[1] while the
115421-6MULTITERMINAL ANDERSON IMPURITY MODEL IN . . . PHYSICAL REVIEW B 90, 115421 (2014)
-5 0 50.0.10.20.3
0.0.10.20.3
ω/γLDOS [1/γ]U=8.0
d= -0.5 UV=0
V=0.5
V=1.5
V=3.0
V=5.0
FIG. 4. (Color online) Nonequilibrium dot spectral function of
the two-terminal PH symmetric SIAM ( /epsilon1d=−U/2) at finite-bias
voltage eV=0,0.5,1.5,3.0,5.0γ. The interaction strength is chosen
asU=8γ. The dotted line represents the result of U=0a n dV=0.
estimated half-width of the Kondo resonance kB˜TK=0.23γ)
and bias voltage V/lessorsimilar2γ. Applying bias voltage gradually
suppresses the Kondo resonance without splitting it, and thetwo peaks at ±U/2 are developed at larger bias voltages, which
corresponds to the discussion in the previous section.
Figure 5shows the result of our self-consistent calcu-
lation of the nonequilibrium spectral function for the two-terminal PH asymmetric SIAM at (a) /epsilon1
d=− 0.625Uand
-5 0 50.0.10.20.3
0.0.10.20.3
ω/γLDOS [1/γ] U=8.0
d = -0.75UV=0
V=0.5
V=1.5
V=3.0
V=5.0(b)-5 0 50.0.10.20.3
0.0.10.20.3
ω/γLDOS [1/γ] U=8.0
d = -0.625 UV=0
V=0.5
V=1.5
V=3.0
V=5.0(a)
FIG. 5. (Color online) Nonequilibrium dot spectral function of
the PH asymmetric SIAM at (a) /epsilon1d=− 0.625Uand (b) /epsilon1d=
−0.75U. All the other parameters are the same with Fig. 4.A sa ne y e
guide, the PH symmetric result of U=0a n d V=0 is shown as a
dotted line.(b)/epsilon1d=− 0.75U. A paramagnetic-type solution is assumed
in determining nσ. As in the PH symmetric SIAM, one sees
increasing bias voltage not split but suppress the Kondoresonance while it develops a peak around E
d−U/2. The
Kondo resonance peak is suppressed more significantly at /epsilon1d=
−0.625Uthan at −0.75Ubecause the Kondo temperature
of the former ( kBTK≈0.067γ;kB˜TK≈0.49γ) is smaller
than that of the latter ( kBTK≈0.12γ;kB˜TK≈0.58γ). An
interesting feature of the PH asymmetric SIAM is that spectralweight of the Kondo resonance seems shifting graduallytoward E
d+U/2 with increasing bias voltage, without ex-
hibiting a three-peak structure in the PH symmetric case.This suggests a strong spectral mixing between the Kondoresonance and a Coulomb peak at finite-bias voltage. Becauseof it, the interval of the two peaks at finite bias is observedas roughly U/2 and gets widened up to Ufor larger eV.
The bias dependence somehow looks similar to what wasobtained by assuming equilibrium noninteracting effectivedistribution for n
σ[30] (which is hard to justify in our opinion),
although we emphasize our present calculation only relies onthe current-preservation condition without using any furtherassumption. It is remarked that the effect shown by biasvoltage is quite reminiscent of finite-temperature effect thatwas observed in the PH asymmetric SIAM in equilibrium [ 37].
More insight can be gained by examining how the spectral
structure depends on the interaction strength at finite-biasvoltage. Figures 6(a) and6(b) show a structural crossover from
5 0 50.0.10.20.3
0.0.10.20.3
ωγLDOS 1γ
d = -U/2U=2
U=4
U=8(a)
5 0 50.0.10.20.3
0.0.10.20.3
ωγLDOS 1γd = -U/2-U=2
U=4
U=8(b)
FIG. 6. (Color online) Nonequilibrium dot spectral function for
different values of interaction strength at bias voltage eV=1.5γ.
Results of the interaction strengths U=2γ,4γ,a n d8 γare shown,
while dotted lines refer to the noninteracting case as an eye guide.
(a) Spectral function of the PH symmetric SIAM at /epsilon1d=−U/2.
(b) Spectral function of the PH asymmetric SIAM at /epsilon1d=−U/2−γ.
115421-7NOBUHIKO TANIGUCHI PHYSICAL REVIEW B 90, 115421 (2014)
a noninteracting resonant peak (the dotted line) to correlation
peaks, for (a) the PH symmetric SIAM /epsilon1d=−U/2, and (b) the
PH asymmetric SIAM /epsilon1d=−U/2−γ. The PH symmetric
SIAM shows introducing Uleads to developing the correlation
two peaks as well as the Kondo peak that is suppressed byfinite-bias voltage. In contrast, the bias-voltage effect on thePH asymmetric SIAM is more involved because the Kondoresonance is apparently shifted and mixed with one of thecorrelation peaks, eventually showing the two-peak structureatE
d±U/2 in the large-bias-voltage limit.
B. Multiterminal PH symmetric SIAM
To examine finite-bias affects further and see particularly
how the presence of multiterminals affects the nonequilibriumspectral function, we configure a special setup of the multi-terminal SIAM that preserves the PH symmetry: the dot isconnected with Nidentical terminals, with bias levels being
distributed equidistantly between −V/2 and+V/2, and each
of relaxation rates is set to be γ/N . The latter ensures that
the unbiased spectral function is the same, hence the Kondotemperature. Results of the nonequilibrium spectral functionare shown in Fig. 7. Again, we confirm that no splitting of the
Kondo resonance is observed in this multiterminal setting. One
sees further that increasing the number of terminals enhances
the Kondo resonance. This can be understood by weakeningthe bias suppression effect on the Kondo resonance for a largerN. More precisely, one may estimate the suppressing effect
from small-bias behavior, Eq. ( 33). Hence, δμis a control
parameter. In the present multiterminal PH symmetric setting,the quantity δμis found to be
δμ=V/radicalBigg
N+1
12(N−1). (43)
Therefore, δμdecreases with increasing N, which results
in weakening the suppression and enhancing the Kondoresonance for a larger N.
The preceding argument also tells us that if the spectral
function bears any multiterminal signatures at all, they wouldbe more conspicuous by examining it with fixing δμrather
-5 0 50.0.10.20.3
ω/γLDOS [1/γ] N=8, V=1.0
N=4, V=1.0
N=2, V=1.0N=2, V=3.0
N=4, V=3.0
N=8, V=3.0
FIG. 7. (Color online) Nonequilibrium dot spectral function for
the PH symmetric multiterminal dot ( N=2,4, and 8). Other
parameters are chosen as the same as in Fig. 4. The dotted line
corresponds to the two-terminal noninteracting unbiased case, whilethe dashed line to the two-terminal interacting unbiased case.-5 0 50.0.10.20.3
0.0.10.20.3
ω/γLDOS [1/γ]N=2, 4, 8
2=3.0N=2, 4, 8
2=1.0(a)
-2 -1 0 1 20.00.20.40.60.81.0
ω[2δμ]f_
(ω)5 10 15 20(b)
0.00.51.0Bias levels
-1.0-0.5
Number of Terminals
FIG. 8. (Color online) (a) Nonequilibrium spectral function for
the PH symmetric multiterminal dot with fixing δμ(N=2,4,8).
Other parameters are the same as in Fig. 7. (b) The effective
Fermi distribution ¯f(ω) at zero temperature for the PH symmetric
multiterminal dot ( N=2,4,8,16). The inset shows relative locations
of bias levels with fixed δμas a function of the number of terminals.
thanV. This is done in Fig. 8(a);F i g . 8(b) shows how the
effective dot distribution ¯f(ω) and the relative locations of
bias levels (in the inset) evolve for a fixed δμwhen N
increases. No multiterminal signature in the nonequilibriumspectral function is seen in Fig. 8(a); results of different N
actually collapse, not only around zero frequency but in theentire frequency range. It suggests that the suppression ofthe Kondo resonance deeply correlates the development ofCoulomb peaks, and a mixing between those spectral weightsis important. The parameter δμcontrols a crossover from
the Kondo resonance to the Coulomb blockade structure. Wemay also understand the similarity between bias effect andtemperature effect by the connection through the large- Nlimit
of the effective Fermi distribution ¯f(ω), as shown in Fig. 8(b).
C. Finite-bias effect on the spectral function:
Issues and speculation
Although there is a consensus that bias voltage starts
suppressing the Kondo peak, and eventually destroys it withdeveloping the two Coulomb peaks when bias voltage is muchlarger than the Kondo temperature, there is a controversy as towhether the Kondo resonance peak will be split or not in theintermediate range of bias voltage. All the results obtained by
115421-8MULTITERMINAL ANDERSON IMPURITY MODEL IN . . . PHYSICAL REVIEW B 90, 115421 (2014)
the second-order perturbation consistently indicate that there
is no split of the Kondo resonance; finite-bias voltage starts tosuppress the Kondo resonance, and develops the two Coulombblockade peaks by shifting the spectral weight from the Kondoresonance. We should mention that some other approximationsdraw a different conclusion. Here, we make a few remarks onapparent discrepancy seen in various theoretical approaches aswell as experiments, as well as some speculation based on ourresults.
Typically, several approaches that rely on the infinite-
Ulimit, notably noncrossing approximation, equation of
motion method, and other approaches investigating the KondoHamiltonian, observed the splitting of the Kondo resonanceunder finite-bias voltage [ 12,25,38]. Those results, how-
ever, have to be interpreted with great care, in our view.Generally speaking, the spectral function obtained by thoseapproaches does not obey the spectral weight sum rule:ignoring the doubly occupied state typically leads to the sumrule−/integraltext
∞
−∞ImGR
σ(ω)/π=1/2[12], rather than the correct
value. Therefore, only half of the spectral weight can beaccounted for in those methods. Simultaneously, such (false)sum rule in conjugation with the bias suppression of the Kondoresonance cannot help but lead to a two-peak structure ofthe spectrum within the range of attention. Splitting of theKondo resonance might be an artifact of the approximation.Not fulfilling the correct sum rule, those approaches maynot be able to distinguish whether finite bias will split theKondo resonance or simply suppresses it with developing theCoulomb peaks. As for the two-terminal PH symmetric SIAM,fourth-order contribution regarding the Coulomb interactionUhas been evaluated numerically [ 5–7]. The results seem
unsettled, though. While Fujii and Ueda [ 5,6] suggested
the fourth-order term may yield the splitting of the Kondoresonance in the intermediate-bias region k
B˜TK/lessorsimilareV/lessorsimilarUfor
sufficiently large interaction U/γ/greaterorsimilar4, which the second-order
calculation fails to report, another numerical study indicatesthat the spectral function remains qualitatively the same withthe second-order result [ 7]. Experimental situation is not so
transparent, either. While the splitting of the Kondo resonancewas reported in a three-terminal conductance measurement ina quantum ring system [ 26], a similar spitting observed in the
differential conductance was attributed to being caused by aspontaneous formation of ferromagnetic contacts, not purelyto bias effect [ 39]. It is also pointed out that it has been recently
recognized that the Rashba spin-orbit coupling induces spinpolarization nonmagnetically in a quantum ring system witha dot when applying finite-bias voltage [ 40–42]; hence, such
spin magnetization might possibly lead to the splitting of theKondo resonance.
The Kondo resonance is a manifestation of singlet forma-
tion between the dot and the lead electrons. One may naivelythink that when several chemical potentials are connected withthe dot, such singlet formation would take place at each leadseparately , causing multiple Kondo resonances. The results
of the multiterminal PH symmetric SIAM presented in theprevious section tempt us to speculate a different picture. Letus suppose that (almost) the same dot distribution functionf
dot(ω)=G−+(ω)/(2iπ) is realized for a fixed δμwith a
different terminal number N,a sF i g . 8(a) suggests. Note the
assumption is fully consistent to the Ward identity for low bias,but it invalidates a quasiparticle ansatz −¯f(ω)I mGR(ω)/π
that explicitly depends on N. In the large- Nlimit with a fixed
δμ, the effective Fermi distribution ¯f(ω) resembles the Fermi
distribution at finite temperature kBT∼δμ. Accordingly, bias
voltage may well give effects similar to finite temperature.It is seen in the low- and large-bias limits for a dot withor without the PH symmetry. It implies that a dot electroncannot separately form a singlet with the lead at each chemicalpotential because it needs to implicate states at differentchemical potentials through coupling with other leads. Oursecond-order perturbation results seem to support this view.
VI. CONCLUSION
In summary, we have evaluated analytically the second-
order self-energy and Green’s function for a generic multi-terminal single-impurity Anderson model in nonequilibrium.Various limiting behaviors have been examined analytically.Nonequilibrium spectral function that preserves the current isconstructed and is checked to satisfy the spectral weight sumrule. The multiterminal effect is examined for the PH sym-metric SIAM, particularly. Within the validity of the presentapproach, it is shown that the Kondo peak is not split due to biasvoltage. It is found that most of the finite-bias effect is similar tothat of finite temperature in low- and high-bias limits with andwithout the PH symmetry. Such nature could be understoodby help of the Ward identity and the connection through theN/greatermuch1 terminal limit. The present analysis serves as a viable
tool that can cover a wide range of experimental situations.Although there is still a chance that high-order contributionsmight generate a new effect such as split Kondo resonances in alimited range of parameters, it is believed that the second-orderperturbation theory can capture the essence of the Kondophysics in most realistic situations. Moreover, having a con-crete analytical form that satisfies both the current conservationand the sum rule, this work provides a good, solid, workableresult that more sophisticated future treatment can base on.
ACKNOWLEDGMENTS
The author gratefully acknowledges A. Sunou for fruitful
collaboration that delivered some preliminary results in thiswork. The author also appreciates R. Sakano and A. Oguri forhelpful discussion at the early stage of the work. The work waspartially supported by Grants-in-Aid for Scientific Research(C) No. 22540324 and No. 26400382 from MEXT, Japan.
APPENDIX A: NONINTERACTING GREEN’S FUNCTIONS
WITH FINITE BIAS
We start with the nonequilibrium Green’s function G
without the Coulomb interaction on the dot. Its Keldyshstructure is specified by
G
σ(ω)=/parenleftbigg
ω−/epsilon1d+iγ(1−2¯f) +2iγ¯f
−2iγ(1−¯f)−(ω−/epsilon1d)+iγ(1−2¯f)/parenrightbigg−1
,
(A1)
where ¯fis the effective Fermi distribution defined in Eq. ( 5).
We incorporate the Hartree-type diagram into the unperturbedpart by replacing /epsilon1
dto/epsilon1d/mapsto→Edσ=/epsilon1d+Un ¯σ.N o t e n¯σis the
115421-9NOBUHIKO TANIGUCHI PHYSICAL REVIEW B 90, 115421 (2014)
exact dot occupation that needs to be determined consistently
later. Its retarded, advanced, and Keldysh components aregiven by
G
R,A
σ(ω)=1
ω−Edσ±iγ, (A2)
GK
σ(ω)=[1−2¯f(ω)]/bracketleftbig
GR
σ(ω)−GA
σ(ω)/bracketrightbig
. (A3)
T h ef u n c t i o n1 −2¯f(ω) reduces to/summationtext
a(γa/γ)s g n (ω−μa)a t
zero temperature.
APPENDIX B: NONEQUILIBRIUM POLARIZATION PART
Taking the Fourier transformation of Eqs. ( 17), using
Eq. ( A3), and making further manipulations, we can rewrite
/Pi1Rand/Pi1Kas
/Pi1R(ε)=/summationdisplay
aγa
γγBaa(ε)
πε(ε+2iγ)=[/Pi1A(ε)]∗, (B1)
/Pi1K(ε)=2i/summationdisplay
a,bγaγb
γ2cothβ(ε−μab)
2Im/bracketleftbiggγBab(ε)
πε(ε+2iγ)/bracketrightbigg
,
(B2)
where μab=μa−μb,βis the inverse temperature, and
Bab(ε)i sg i v e nb y
Bab(ε)=/integraldisplay
dε/prime[fb(ε/prime)−fa(ε/prime+ε)] [GA(ε/prime)−GR(ε/prime+ε)].
(B3)
In this work, we are interested in the zero-temperature limit,
for which coth( βx) becomes sgn( x). The function Babin this
limit is evaluated as (with ζaσ=μa−Edσ)
Bab(ε)=− log/parenleftbiggε−ζaσ+iγ
−ζbσ+iγ/parenrightbigg
−log/parenleftbiggε+ζbσ+iγ
ζaσ+iγ/parenrightbigg
.
(B4)
This corresponds to a multiterminal extension of the result
obtained for the two-terminal PH symmetric SIAM.
APPENDIX C: DILOGARITHM WITH A
COMPLEX V ARIABLE
To complete evaluating the remaining integral over Eof
Eqs. ( 19) and ( 20), we take full advantage of various properties
of dilogarithm function Li 2(z). A concrete integral formula
we have utilized will be given in Appendix D. For the sake
of completeness, we here collect its definition and propertiesnecessary to complete our evaluation.
1. Definition
Dilogarithm Li 2(z) with a complex argument z∈Cis
not so commonly found in literature. As it is a multivaluedfunction, we need to specify its branch structure properly. Oneway to define dilogarithm Li
2(z) all over the complex plane
consistently is to use the integral representation
Li2(z)=−/integraldisplayz
0dtLog(1 −t)
t. (C1)The multivaluedness of dilogarithm Li 2originates from the
logarithm in the integrand. Here, we designate the principalvalue of logarithm as Log, which is defined by
Logz=ln|z|+iArgz(for−π< Argz/lessorequalslantπ).(C2)
According to Eq. ( C1), Li
2(z) has a branch cut just above
the real axis of x> 1. Accordingly, its values just above and
below the real axis are different for x> 1: Li 2(x−iη)=
Li2(x)b u tL i 2(x+iη)=Li2(x)+2iπlnx. Some special
values are known analytically. We need Li 2(0)=0, Li 2(1)=
π2/6, Li 2(−1)=−π2/12, and Li 2(2)=π2/4−iπln 2 for
evaluation later.
2. Functional relations
Dilogarithm Li 2(z) has interesting symmetric properties
regarding its argument z; values at z,1−z,1/z,1/(1−z),
(z−1)/z, andz/(z−1) are all connected with one another.
Those points are ones generated by symmetric operations S
andTdefined by
Sz=1
z;Tz=1−z, (C3)
and{I,S,T,ST,TS,TST }forms a group. Other operations
correspond to
STz=1
1−z;TSz=z−1
z, (C4)
TSTz =STSz =z
z−1. (C5)
Applying a series of integral transformations in Eq. ( C1), one
can connect the values of dilogarithm at these values withone another [ 43]. Note, those functional relations are usually
presented only for real arguments. Extending them for complexvariables needs examining its branch-cut structure carefully.By following and extending the derivations in Ref. [ 43]
for complex z∈C, we prove that the following functional
relations are valid for any complex variable z:
Li
2(Sz)=− Li2(z)−π2
6−1
2[Log(TSz )−Log(Tz)]2,(C6)
Li2(Tz)=− Li2(z)+π2
6−Log(Tz)L o gz, (C7)
Li2(TSTz )=− Li2(z)−1
2Log2(STz )
−[Log(Tz)+Log(STz )] Log z,(C8)
Li2(TSz )=Li2(z)−π2
6
−1
2Log2(Sz)−Log(Sz)L o g (Tz),(C9)
Li2/parenleftbig
STz/parenrightbig
=Li2(z)+π2
6
+1
2Log2(Tz)+Log(Tz)L o g (TSTz ).(C10)
To our knowledge, the above form of extension of functional
relations of dilogarithm has not been found in literature.
115421-10MULTITERMINAL ANDERSON IMPURITY MODEL IN . . . PHYSICAL REVIEW B 90, 115421 (2014)
3. The Taylor expansion
To examine various limiting behaviors, we need the Taylor
expansion of dilogarithm, which is derived straightforwardlyfrom Eq. ( C1):
Li
2(z)=Li2(z0)−∞/summationdisplay
k=1(z−z0)k
k!dk−1
dzk−1Log(1 −z)
z/vextendsingle/vextendsingle/vextendsingle/vextendsingle
z=z0.
(C11)
The presence of Log(1 −z) reflects the branch-cut structure
of Li 2(z). In particular, we utilize the following expansion in
our analysis:
Li2(z)≈z+z2
4+z3
9+z4
16+··· , (C12)
/Lambda1(2+z)≈π2
4−z2
4+z3
6−5z4
48+··· . (C13)
APPENDIX D: INTEGRAL FORMULA
Here, we derive and present the central integral formula for
evaluating Eqs. ( 19) and ( 20). By performing a simple integral
transformation in Eq. ( C1), we have the integration
/integraldisplayz
−bLog/parenleftbigx+b
c/parenrightbig
x−adx=/integraldisplayz+b
a+b
0Log/parenleftbiga+b
cy/parenrightbig
y−1dy (D1)
=Log/parenleftbigz+b
c/parenrightbig
Log/parenleftbig
1−z+b
a+b/parenrightbig
+Li2/parenleftbigz+b
a+b/parenrightbig
, (D2)
where all the parameters ( a,b,c )a sw e l la s zmay be taken as
complex numbers. Combined with fractional decomposition,we see the following integral can be evaluated in terms ofdilogarithm:
/integraldisplay
z
−bLog/parenleftbigx+b
c/parenrightbig
dx
(x−a1)(x−a2)(x−a3)
=3/summationdisplay
i=1Log/parenleftbigz+b
c/parenrightbig
Log/parenleftbig
1−z+b
ai+b/parenrightbig
+Li2/parenleftbigz+b
ai+b/parenrightbig
/producttext
j/negationslash=i(ai−aj).(D3)APPENDIX E: CALCULATION OF THE CORRELATED
PART OF THE SELF-ENERGY
The remaining task to complete calculating /Sigma1Rin the form
of Eqs. ( 21) and ( 22) is to collect all the relevant formulas and
organize them in a form that conforms to Eq. ( D3). To write
concisely, we introduce the following notations:
μab=μa−μb, (E1)
ζaσ=μa−Edσ, (E2)
εσ=ω−Edσ, (E3)
where the Hartree level Edσis defined as before. We express
the terms I1andI2defined in Eqs. ( 19) and ( 20)a s
I1=−/summationdisplay
a,b/summationdisplay
α,β=±1αγaγb
πγ
×/integraldisplay+∞
−∞dEsgn(E−βμab)
(E+εσ+iγ)Log/parenleftbigE−βζa¯σ+iαγ
−βζb¯σ+iαγ/parenrightbig
(E+2iαγ)E,
(E4)
I2=−/summationdisplay
a,b/summationdisplay
α,β=±1αγaγb
πγ
×/integraldisplay+∞
−∞dEsgn(E+εσ−ζaσ)
(E+εσ+iαγ)Log/parenleftbigE+βζb¯σ−iγ
βζb¯σ−iγ/parenrightbig
E(E−2iγ).
(E5)
Here, the leads a,b inI1as well as binI2carry spin ¯ σ,
while ainI2does spin σ. Singularity on energy integration
is prescribed by the principal values. Equation ( D3) enables
us to perform and express the above integrals in terms ofdilogarithm. The resulting expressions are still complicated,but we can simplify them further using functional relations ofdilogarithm Eqs. ( C6)–(C10). These require straightforward
but rather laborious manipulations. In this way, we reach thefinal expression of /Sigma1
R
σof Eq. ( 21).
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115421-12 |
PhysRevB.20.3543.pdf | PHYSICAL REViEW B VOLUME 20,NUMBER 9 1NOVEMBER 1979
Modelsofelectronic structure ofhydrogen inmetals: Pd-H
P.Jena'andF.Y.Fradin
Argonne National Laboratory, Argonne, Illinois60439
D.E.Ellis
Northwestern University, Evanston, Illinois60201
(Received 16August1978;revised manuscript received 12June1979)
Local-density theoryisusedtostudytheelectron charge-density distribution aroundhydrogen
andhostpalladium metalatoms.Self-consistent calculations usingafinite-size molecular-cluster
modelbasedonthediscrete variational method arereported. Calculations arealsodoneina
simple"pseudojellium" modeltostudytheelectron response tohydrogen withintheframework
ofthedensity-functional formalism. Resultsofthissimpleapproach agreeverywellwiththe
molecular-cluster model. Partialdensitiesofstatesobtained intheclustermodelarecompared
withband-structure resultsandconclusions regarding theimportance ofthelocalenvironment
ontheelectronic structure aredrawn. Calculated core-level shiftsandchargetransfer frommetl-
alionstohydrogen arecompared withtheresultsofx-ray—photoelectron spectroscopy experi-
mentsinmetalhydrides andarediscussed intermsofconventional anionic, covalent, andpro-
tonicmodels. Theeffectofzero-point vibration ontheelectron chargeandspin-density distri-
butionisstudied byrepeating theabovecalculations forseveraldisplaced configurations ofhy-
drogeninsidethecl'uster. Theresultsareusedtointerpret theisotopeeffectontheelectron
distribution aroundprotonanddeuteron.
I.INTRODUCTION
Thestudyoftheelectronic structure ofhydrogen
inmetalsisatopicofgreatcurrentinterest. Apro-
tonwithnocoreelectronic structure isthesimplest
kindofanimpurity thatcanbeimplanted intoa
solid.However, theabsenceofcoreelectrons results
inaneffective electron-proton potential thatissingu-
larattheprotonsite.Consequently, thescreening of
suchastrongperturbing impurity cannotbehandled
wellbyconventional pseudopotential perturbation
'theories' orstatistical methods. Nonlinear
theories''mustbeusedtostudytheelectron
response tohydrogen. Aknowledge ofthisnonlinear
screening oftheprotonisusefulinunderstanding the
electronic properties ofhydrogen inmetals.The
motivation behindsuchamicroscopic understanding
ofmetal-hydrogen systems isnotonlyacademic, but
isalsoduetoitspractical importance inproblems
suchasembrittlement duetodissolved hydrogen
anduseofhydrogen inenergy-related technology.~
Inthispaperwehavestudiedvariouselectronic
properties associated withdissolved hydrogen in
transition-metal systems. Although. specific calcula-
tionsareperformed forthepalladium-hydrogen sys-
tem,ourdiscussions andconclusions aregeneral and
should applytoanymetal-hydrogen system. Three
common theoretical approaches havebeentaken:(i)
Thejelliummodel—inthismodel5(meaningful only
fornearly-free-electron systems) theperiodic struc-tureofthehostisneglected andthepositive charges
onthehostionsaresmeared outuniformly toforma
homogeneous background ofdensity np.Thescreen-
ingofaprotonisthentreated instandard linear'or
nonlinear screening theories.3'(ii)Theband-
structure model—mostapplications basedonthe
augmented-plane-wave (APW)method havebeen
usedtointerpret electronic properties of
stoichiometric metalhydrides. Calculations' based
onthecoherent-potential approximation" aregen-
erallyusedtostudymetalscontaining smallamounts
ofrandomly distributed hydrogen. Thesecalculations
emphasize theimportance oflatticestructure. (iii)
Themolecular-cluster model'—thismodelissome-
whatintermediate between theabovetwomodels. It
isgenerally assumed thattheelectronic properties of
theimpurity aredictated mainly byitslocalenviron-
ment.Thus,onetreatstheimpurity andnearneigh-
borsasforming amolecular cluster.Theeigenstates
andelectron chargedensities arethencalculated
self-consistently usingthelocal-density approxima-
tion.Inametallic environment, thepotentials asso-
ciatedwithbothhostandimpurity ionsareshort
rangeduetoefficient screening oftheioniccharge.
Consequently, amolecular-cluster modelmayprovide
meaningful resultsfortheelectronic structure ofim-
purities innon-free-electron-like systems. Although
theabovemodelshavebeenextensively usedinthe
past,ithasnotbeenclearwhichfeatures aremodel
dependent, andwhichareintrinsic totheimpurity
20 3543 O1979TheAmerican Physical Society
3544 P.JENA,F.Y.FRADIN, ANDD.'E.ELLIS 20
system. Aconsistent comparison oftheresultsob-
tainedinagivensystemfromthedifferent models
will,therefore, beuseful.Inaddition, wehaveex-
tendedthescopeofbothjellium andclustermodels
toobtainmoredetailed information aboutthe
hydrogen-metal interaction.
Usingtheabovetheoretical models, weshall
analyze avarietyofproblems relating totheelectron-
icstructureofhydrogen inmetals. Historically, there
arethreesimplemodels" thatareusedtodescribe
thebehaviorofhydrogen incondensed matter.The
anionic modelisbasedupontheassumption thatan
electron fromthemetalionistransferred tothehy-
drogen. Inthecovalent hydrogen model,itisassumed
thatthehydrogen iscovalently bondedtometalions.
Intheprotonic model,theelectron isassumed toleave
theprotonandtoparticipate infillingtheoccupied
metallic band.Itisnotclearwhether anyofthese
descriptions isappropriate fortheproblemofdilute
quantities ofhydrogen inmetals' wherescreening
wouldcertainly playadominant role.Weshallstudy
thepossible electron transfer fromthemetalionto
hydrogen andtheaccompanying shiftinthebinding
energyofthecorelevels.Comparison canbemade
withx-ray—photoelectron spectroscopy''measure-
mentsofthecore-level shiftsofthemetalioninthe
hydride phasecompared tothatinthepuremetallic
state.
Through nuclear-magnetic-resonance experi-
ments,"theprotonspin-lattice relaxation timeis
usedtoprovide information onthecontact spinden-
sityatthehydrogen site.Acomparison ofthiswith
thedeuteron spin-relaxation rateinmetaldeuterides
yieldsinformation ontheisotopeeffect.'Thepro-
tonanddeuteron arebothlightimpurities, andthe
effectoftheirzero-point vibration ontheelectronic
structure willbediscussed.
Theoutlineofthepaperdealing withthediscus-
sionoftheaboveproperties isasfollows: InSec.II
wediscusstheself-consistent density-functional for-
malismforaninhomogeneous electron gas.We
prescribe ahomogeneous-density schemefortreating
thescreening ofhydrogen innon-free-electron-like
metals.Thismodelcanbeviewedasapseudojellium
model.InSec.III,theessentials ofthemolecular
—clusterapproach areoutlined. Theresultsofelectron
chargedistribution around ahydrogen atomalong
different crystallographic directions obtained inthe
abovetwomodelsarecompared inSec.IV.This-sec-
tionalsocontains acomparison ofthepartialdensity
ofstatesobtained inourmolecular-cluster model
withthatoftheAPWband-structure approach. The
problemofchargetransfer frommetaliontohydro-
genisdiscussed inSec.Vinthelightofrecentexper-
imentsusingx-ray—photoelectron spectroscopy. In
Sec.VIwediscusstheeffectofzero-point vibration
ontheelectron chargeandspindistribution arounda
lightimpurity. Ourresultsaresummarized inSec.VII.II.HOMEGENEOUS-DENSITY APPROXIMATION
TOMOLECULAR CLUSTERS:
APSEUDOJELLIUM MODEL
Inthissection weprescribe ascheme tostudythe
screening ofaprotoninanon-free-electron-like me-
tal.Intheconventional jelliumapproach, theelec-
trondensityofthehomogeneous background isgiven
byadensityparameter r,where
,w(r,a—p)'=I/np .4
np(f}=Xnp(rR„)—
V
where np(rR„)is—thefree-atom chargedensitycen-
teredontheR„thlatticesiteandcanbecomputed
fromaknowledge oftheone-electron orbitals,'
P„p„(r), namely,(2)
np(r)=X(y„((r)('
nlm
=2XRJ(r) (3)
„(4m
where2(2I+1)isthespinandorbitaldegeneracy
factorandR,~(r)istheradialwavefunctionofthe
quantum statenl.Thus,thedensityparameter r,is
itselfafunctionofr,i.e.,3mr,'(r)ap=1/np(r). In
palladium (fcc)crystal,forexample, theprotonis
knowntooccupytheoctahedral site.Theambient
densityatthispointcanbeevaluated fromEq.(2).
Inpractice, however, itissufficient toconsider only
thenearest-neighbor hostionssincethesecondand
furtheroutneighbors makeanegligible contribution
totheambient electron density.
Havingdetermined theambient electron densityat
apointr;inspace,theresponse oftheelectrons toaTheconduction-electron density, no,isdetermined by
accounting forthenumberof"free"electrons, Z
(usually thevalence) peratomicvolume, Qp,i.e.,
np=Z/Qp.Theelectron distribution aroundthepro-
tonisthenstudied byembedding thepointchargein
thishomogeneous medium. Inextending this
scheme tonon-free-electron-like systems, thefirst
difficulty istoestimate thequantity, Z.Inkeeping
withthespiritofthejelliummodel,oneshouldin-
tegratethespcomponent oftheelectron densityof
statesuptotheFermienergyEFtoestimate Z.This
obviously requires apriorknowledge ofthepartial
densityofstatesobtained intheband-structure calcu-
lation.Inaddition, oneassumes thattheinteraction
between theimpurity andthehostdelectrons is
negligible.
Inthefollowing wesuggest analternate scheme.
Todetermine theambient electron chargedensity
np(r)oftheperfecthostatanypointinspacetoa
firstapproximation, weusethenoninteracting atom
model.Inthismodel,
20 MODELS OFELECTRONIC STRUCTURE OFHYDROGEN. .. 3545
protonatthatpointiscalculated byassuming thatthe
electrons respond totheprotonasiftheprotonissit-
uatedinahomogeneous electron gasofdensity
Ilp(f~).Thismodelwillbereferred toasthe"pseu-
dojellium" modelandisobviously anapproximation
toamorecomplicated molecular-cluster model(dis-
cussedinSec.III)wherehydrogen andthesurround-
ingmetalionsareallowed tointeract amongeach
otherinestablishing theground-state distribution of
theelectron density. Thejustification fortheuseof
thispseudojellium modelcanonlybemadeafter
comparing theresults(seeSec.IV)withthatob-
tainedinthemoresophisticated molecular-cluster
model.
Wehaveusedthedensity-functional formalism
ofHohenberg, Kohn,andSham(HKS)totreatthe
screening oftheprotoninthepseudojellium model.
MuchhasbeenwrittenabouttheHKStheoryandwe
referthereadertotherecentpapersbyJenaetal."
forfurtherdetails.Thenumerical workforthe
density-functional formalism hasbeencarriedoutin
amanner described earlier.'Thechargedensity
n(r)andspin-density n(r)distribution around hy-
drogenhavebeencalculated self-consistently toa-
precision ofbetterthan2%inn(r)inthevicinityof
theproton.
III.SELF;.CONSISTENT
MOLECULAR-CLUSTER MODEL
Wealsousethelocal-density formalism described
earlierincarrying outmolecular-orbital (MO)calcula-
tionsonfiniteclusters representative ofthesolid.
TheMOeigenstates areexpanded asalinearcombi-
nationofatomicorbitals,
y„(r)=Xaj(r—R~)Cq„
J(4)
isapproximately solvedbyminimizing certainerror
moments onasampling gridinr.Theeffective
Hamiltonian forstatesofspino-isgivenby
+Vcoul+ Vexch,u
wherethefirsttwotermsarethekineticenergyand
Coulomb potential. Theexchange. potential istaken
intheusualform,
V,„,„=—6n[3n(r)/4m]'~' .
Thevaluea=0.7,closetothatofKohnandSham,Thevariational coefficients (Cj„lareobtained by
solvingthesecularequationofthediscrete variation-
almethod.'Thismethod hasbeendescribed inde-
tailelsewhere.'Here,weonlynotethatthe
single-particle equation,
(h—a„)y„(r) =0wasusedinallcalculations. Thereexistmoreela-
boratelocal-density exchange andcorrelation poten-
tialswhicharefoundtoleadtosmalldifferences in
self-consistent energylevelsandchargedensities for
transition metals. Thesedifferences aretoosmall
tobeofanyconsequence forthepresentwork.
Calculations weremadefortheoctahedral Pd6and
PdqHclusters withbondlengthtakenforthebulkPd
metal.Theprotonwasplacedeitheratthe(0,0,0)
octahedral site,ordisplaced alongthe[100)direction.
Aspin-restricted (assuming n=
2n)modelwas
used,withtheiteration procedure startingfromsu-
perimposed atomicchargedensities, Interaction of
theclusterwiththecrystalline environment wasig-
nored,sinceweplantoconcentrate onproperties as-
sociated withthecenterofthecluster. However, for
anyreasonable treatment ofbulkmetalproperties, it
isnecessary toembedtheclusterinaneffective
medium. Inordertocompare theseresultswith
band-structure calculations andexperiments on
stoichiometric PdH,itisnecessary tostudythesensi-
tivityofourcalculated electron densities around hy-
drogentoitschemical environment. Wehave,there-
fore,repeated ourpseudojellium calculations bycon-
sidering thelatticeparameters andgeometrical ar-
rangements ofPdandHinPdH.Thedecrease inthe
ambient chargedensityduetothesurrounding Pd
atomsinPdHasaresultoflatticeexpansion isfound
tobesomewhat compensated bytheadditional con-
tribution ofthehydrogen atomstotheambient
chargedensity. Asaresult,thecalculated self-
consistent electron densityatthehydrogen sitein
PdHdoesnotdiffersignificantly fromthatofasingle
octahedrally coordinated hydrogen atominpurePd.
Thiscalculation wasnotrepeated fortheself-
consistent molecular-. clustermodel. However, wedo
notexpecttheresultstobequalitatively different.
Thus,thecomparison oftheelectronic properties as-
sociated withhydrogen, inSecs.IV—VI,inthepseu-
dojellium andmolecular-cluster models withband-
structure calculations andexperiments onPdHis
meaningful.
IV.COMPARISON BETWEEN PSEUDOJELLIUM,
MOLECULAR-CLUSTER, ANDBAND-STRUCTURE
MODELS
Thissection isdivided intotwoparts.Firs&,we
discusstheelectron chargedensityaroundaproton
octahedrally coordinated tosixneighboring Pdatoms
obtained self-consistently inboththepseudojellium
andmolecular-cluster model.Second, thepartial
densityofstatesobtained inthemolecular-cluster ap-
proach willbecompared withAPWband-structure
calculations.9
InFig.1wepresent acomparison oftheambient
chargedensityobtained byasuperposition ofthe
3546 P.JENA,F.Y.FRADIN, ANDD.E.ELLIS 20
O.I5-
1o
t-
CI
I—
CA
LLIC)O.IO—
4J
CK
cK
0.05—
4J
COII
III
[II
III
III
III
I
[»0]''
I''
I''
I
[»I] [I»~)
.W~.A~
I~-[IIO]
----dl~JV
0Pd-ATOM
xOCTAHEDRAL
INTERSTITIAL SITE0.3
O
0.2
0.1II
III
III
I'III.
III
III
I&II
III
III
I
[IOO] [»Ol
0IIIIIIIIIgIIIIIIIII
00,6I.2 I.800.6 l.2 I.8IIII
006II»I,
12 I8IIIIIII~ItIIIIIII IIIIIIIII
00.30.60.900.30.60.900.30.60.9
r{0,]
FIG.1.Electron charge-density distribution insidethe
unitcellofPd.Thesolidlinerepresents aself-consistent
molecular-cluster calculation basedonasix-Pd-atom cluster;
thedashedlineisobtained byalinearcombination offree-
atomchargedensities centered atindividual nuclearsitesof
theabovecluster. Theoctahedral site(equilibrium confi-
gurationofhydrogen givenby&&)definestheoriginofthe
real-space coordinate system.
free-atom chargedensities (dashed curve)withthat
calculated inthemolecular-cluster modelconsisting
ofsixinteracting Pdatomslocatedatthefacecenters
ofthecube(solidcurve). Attheoctahedral site
(takenastheorigin)thechargedensityduetothein-
teracting metalatomsisaboutafactorof2larger
thanthatduetothesimplesuperposition model.
Theanisotropy remains small,asexpected, fordis-
tancesuptolao(Bohrradius)fromtheorigin.
However, forfartherdistances, thechargedensity
alongthe[100]direction increases muchmorerapidly
thanalongthe[110]and[111]directions sincethe
nearest-neighbor Pdatomliesalongthe[100]direc-
tion.Thisanisotropy intheambient chargedistribu-
tionisalsoapparent fromthesimplenoninteracting
atommodel.
Theelectron distribution around aprotonembed-
dedattheoctahedral interstitial siteinPdmetalis
calculated self-consistently inthepseudojellium
modelandiscompared withthemolecular-cluster
(Pd6H)resultinFig.2.Theelectron densities atthe
protonsiteinthesetwocalculations differfromeach
otherbyabout17%whilethediscrepancy getsnar-
rowerasonegoesfarther awayfromtheproton. The
chargedistribution remains isotropic withinasphere
ofoneBohrradiusaroundtheproton. Thisresult
alongwiththeagreement between pseudojellium and
molecular-cluster models may,atfirst,besurprising.
Ananalysisofthedifferent angular momentum com-
ponentsofthechargedensitybasedonthejellium
modelrevealsthattheelectrons aroundtheproton
havepredominantly ssymmetry. Thisresultiscon-
sistentwiththeangular momentum resolved partial
densityofstatesforthePd6Hclusterinsidethehy-FIG.2.Comparison between theelectron chargedensities
alongthe[100],[110],and[111]directions aroundanoc-
tahedrally coordinated hydrogen atomcalculated self-
consistently inthemolecular-cluster (solidcurve)andpseu-
dojellium (dashed curve)models.
drogensphere(seebelow)aswellaswiththe
predominant s-wavescattering fromthehydrogen
determined fromdeHaas—vanAlphen experiments
incoppercontaining diluteamountsofhydrogen, If
oneweretousetheambient densityattheoctahedral
position inPdfromthemolecular-cluster calculations
forthePd6complex insteadofthatobtained fromthe
noninteracting atommodel,thepseudojellium model
forPd-Hwouldyieldanelectron densityatthepro-
tonsitethatis35%higherthanthePd6Hclustercal-
culation. However, withthisapproach thepseudojel-
liummodelloosesitsattractiveness, sincethere-
quiredPd6clustercalculation neededtodetermine
theambient density isasdifficult asthefullPd6H
calculation. Itisinteresting thatthechargedensityat
theprotonsiteinthepseudojelliurn modelishigher
thanthatobtained inthemolecular-cluster calcula-
tion.Thisresultisconsistent withone'sphysical in-
tuitionthatinthemolecular-cluster model,afraction
oftheelectrons around hydrogen willbepulledaway
toscreenthePdatomsandtoformthePd-Hbondas
well.Inaddition, thepseudojellium modeltreatsthe
ambient interstitial electrons asfree-electron-like.
Sincetheinterstitial densityincludes ad-statecontri-
butionandthedelectrons arelesspolarizable thans
electrons ofthesamedensity, thepseudojellium
modelwouldtendtooverestimate theprotonscreen-
ing.
Tocompare theenergyeigenvalues ofelectrons
between molecular-cluster andband-structure
models, weusetheconceptofpartialdensityof
states(PDOS). Wedecompose thechargedensity
intocontributions fromdifferent sitesandobtainin-
formation aboutthemetal-hydrogen bond.Inaddi-
tion,itispossible tomakeacomparison withthe
PDOSfoundinAPWband-structure calculations on
stoichiometric PdH.TheclusterPDOSisfoundasa
20 MODELS OFELECTRONIC STRUCTURE OFHYDROGEN. .. 3547
sumofLorentzian linesofwidthycentered atthe
molecular-orbital energies,
D„(E)=Xf~E—Eg2+y2(8)
I—
COa
CL
Ol
XQtJ
Ct
(b)
CAl—
CA
CODO
CLI—~CZI
CL
2eVHereywaschosenas0.4eV(consistent withthe
discrete levelstructure oftheclusteranduncertainty
of-0.1eVinclusterlevelsduetobasis-set limita-
tions),andf+weretakentobeatomicpopulations
obtained fromaMulliken population analysis ofthe
eigenvectors. TheclusterPDOSforPd4dandhy-
drogen1sstates-are showninFig.3.ThePd-Hbond-
ingbandcentered at-8eVbelowtheFermienergy
hasastrongresemblance tothatfoundfortheor-
deredcompound bytheAPWmethod. Thissug-
geststhattheseverydifferent modelsareconverginguponacommon description. Thetotaldensityof
statesforthecluster, containing sizablemetalspcon-
tributions, isalsoshowninFig.3.Withthemain
features alignedtoremove levelshiftsduetosmall
clustersize,weseethatthedensityofstatesforPd6
andPd6Hclusters differslittle,exceptforthebond-
ingPd-HpeaknotedinthePDOScurves. Wenow
turntoadiscussion oftheelectron-spin densityat
theprotonsiteinPdHasobtained fromband-
structure andpseudojellium models.
Usingthemethod inSec.II,wehavecalculated the
spin-density enhancement, [nt(0)—nf(0)]/
(not—not)atthehydrogen siteinPdtobe10.7.The
corresponding band-theory result9forPdHis6.8.A
criticalcomparison between thepseudojellium and
theband-theory resultforthespindensityisham-
peredsincetheAPWband-structure9 calculation was
notcarriedoutself-consistently. Itis,however, en-
couraging thatourresultisins~iquantitative agree-
mentwithbandcalculation. Neglectofaperiodic ar-
rangement ofPdatomsinthepseudojellium model
givesrisetoaspindensitythatislargerinmagnitude
thantheband-theory result.Thissystematic trend,
asdescribed inSec.IV,alsoexistsinthechargeden-
sityattkeprotonsite.
Thenuclear-spin-lattice relaxation rateatthehy-'
drogensitecalculated inthepseudojellium model
(withthesdensityofstatesattheFermienergytak-
enfromband-theory result)isabout57%higherthan
experiment.'7'8Itisworthmentioning -thatthe
Knightshift(whichalsomeasures thespindensity)
atthepositive muon(alightisotopeofhydrogen)
sitesinparamagnetic metalscalculated5 inthejellium
modelareconsistently higherthanthecorresponding
experimental values.'Thus,thejelliummodelis
foundtoconsistently overestimate theelectron
chargeandspindensityaithehydrogen site.Theef-
fectofintroducing theperiodic arrayofmetalions
wouldbetoreducethemagnitude oftheseelectron
densities—atrendintherightdirection forexplaining
theexperimental data.
LaJl—
cn+
X
C/yccKI—
WC5
I—C)I—(c)EF
EF
ENERGY (eV)
FIG.3.Partialdensityofstatesinarbitrary unitsfor(a)
hydrogen 1s,(b)Pd4dstates,and(c)totaldensityofstates
forPd6H(solidline),andPd6(dotted line)clusters.V.CHARGE TRANSFER ANDCORE-LEVEL
SHIFTS DUETOHYDROGENATION
Thissectiondealswithadiscussion ofmodelsof
thechemical bondbetween hydrogen andmetalions
andtheeffectsassociated withpossible charge
transfer fromthemetalionstohydrogen. Insolving
thesetofself-consistent HKSequations2 inSec.II,
wehavefoundthattheeffective potential isstrong
enough toformweaklyboundstateswithtwoelec-
tronsashavebeenfoundearlierbyseveralwork-
ers'throughout themetallic densityrange.Even
thoughsingle-particle eigenvalues havenofunda-
mentalmeaning inHKStheory,thewholeofband
theorybasedonHKSformalism restsontheirin-
3548 P.JENA,F.Y.FRADIN, ANDD.E..E.ELLIS 20
(a)
0.50—I"T~TT'tll~
0.25
0.20
Ica
0.15
t-
O.IO
0.05
-0.02—
I II I III
0 I 2
r(a)
(b)'
['[
1.0
0.8terpretation. Thespintandspin)bound-state wave
functions extendoverseverallatticesacin
droeni'
gepicturethattheelectronic strtfh ucureohy-
geninmetalsisthatofanextended H
aneuallqayextended holeinthecontinuum. Sinceeionwith
thecalculated lifetime broadening fth ningotesestates
duetoelectron-electron intert'acionislargecomparedtotheirbinding energies theg',hephysical significance of
eseboundstatesisnotwellestablish d
matterosaise.Asa
o~act,experiments usingp
oooortheseboundstateshaveb
unsuccessful.veeen
oftheInordertoprovide ammorephysical understanding
otheelectronic configuration ofhd
environment, wecompute thedifference inthe
electron densityaroundtheoceoctahedral sitebetween
e6andPd6cluster,i.e.,
hn(r)=np,,„(r)—np,,(r)
Thisdifference, indicative ofh
duetoocargereadjustment
uetohydrogenation isplotted inFi.4a
[100]direction fortheinig.'aalongthe
ionortemolecular-cluster calculation.
enegative regionofelectron de
beyond-2Bohrradiisuensityfordistances
orradiisuggests thatthechargefrom
tevicinityofthemetalionh
thehydroens'nhasbeentransferred to
eyrogensphere. Thus,acomparison ofthe
numberofelectrons, Z(R
radius8ar~,contained inasphereof
raiusaroundtheprotoninametal,
tRZ(R)=
~d3r5(nr)nr, (10)
withthatoffree-h-hydrogen atomwouldindicate the
extentofexcessscreening ofhydroen
r,=2.7)isalsoapparent fromourseudl.SiZ()ht e~astobeequaltounityinall
calculations toensureelectr' 1h
observed chargetransfer couklb ericacargeneutralit th
rcouedescribed asthe
yrogenbeingslightlyanionic andthe
ingslightlycationicicantemetalionbe-
Adirectconsequence ofthereductionofelectrons
unemetalionistoalterthe n''hecore-level ener-
naleIwecompare theenergiesofthe4
s,and31corelevelsofth 11d'epaaiumatominthe
e:-0.6TABLEI.ComariparisonofPdcore-level energies (eV)re-
lativetoFermienergy'oft
-self-consistent l1-daomandclusterinno
oca-ensitymodel.d nonrelativistic
0.4
Level Atom Pd6 Pd6H
0.2
000.40.8 l.2 I.62.02.42.84p
4s
3d46.3
75.5
328.346.7
75.9
329.247.0
76.2
329.5
R(oo)
FIG.4.a
PdHandPdcDifference intheelectron chardcargeensityin
an~clusters. Thenegative regionindicates the
zonefromwhi
hydrogenation.wichmetalchargehasbeentransf ddserreueto
gaion.bNumberofelectrons ct'd'onaineina
oraiusRaround aprotonembedded in
toZratoms)(corresponding tohydrogen tetrahedrall b
s(solidcurve)vsthataround aprotoninfree-
hydrogen atom(dashedcurve).'HereweHerewedefinetheFermienergytobetheeienv
thelastoccupied level.Bre'ieso eve. yrelating thecoreeneriesof
atomandvariousclusterth'rsoteirrespective Fermien
wecompensate forshiftsinbiienergies,
sisinindingenergies whichare
moeldependent, i.e.,depend uonclu'
conitions.Thisr co't.T'procedure makesitpossible touse
ground-state eigenvalues toestimate bindinene
xciestateortransition state(seeRef.34)
calculations neededtodetermine absoltb'd'ueiningenergies.
MODELS OFELECTRONIC STRUCTURE OFHYDROGEN. .. 3549
free-atom, andPd6Pd6Hclusterconfigurations. In
thesix-Pd-atom cluster,somechargefromeachatom
isdonated totheconduction searesulting inanin-
creaseofabout0.4eVintheioncorelevels.Thead-
ditionofhydrogen accentuates thistrend.ThePd-H
bonding chargeisbeingdrawnfromthevicinityof
themetalioncore[seeFig.4(a)],leavingcorelevels
stillmoretightlybound.
Thiseffecthasbeenseeninarecentexperiment by
Vealetal.'6involving x-ray—photoelectron spectros'-
copy.Theseauthors havecompared thecore-level
shiftsofZr4pand3dlevelsinZrH~65withthatin
pureZrandfindthatthelevelsshifttohigherbind-
ingenergies by0.7and1eV,respectively. This
resultisconsistent withourclustercalculation inthe
Pd-Hsystem. Aquantitative comparison ofthese
core-level shiftsatthisstageisunwarranted sincewe
expecttheseshiftstodependonthelocalenviron-
ment.Inthehydride phase,forexample, thecon-
centration ofhydrogen ishigh.Thus,weexpectthe
magnitude ofshiftsinTableIduetohydrogenation
tobesignificantly largerthanthepresentestimate.
Aspointedoutearlier,themolecular clusterhasto
beembedded inapotential background simulating
thecrystalline environment. Wearepresently carry-
ingoutthesecalculations forseveraltransition-metal
hydrides.
VI.ISOTOPE EFFECT ONTHEELECTRON
DISTRIBUTION AROUND ~HAND2D
Studiesofneutron inelastic scattering'"onmetals
containing hydrogen reveallocalized modesforhy-
drogenwhichinpalladium occursat56meV.As-
suming thattheprotonmovesinaharmonic poten-
tialwell,thislocalized modecorresponds toamean-
squarehydrogen vibration amplitude of0.07A2.In
thissectionwediscussbrieflytheeffectofthiszero-
pointvibration ontheelectron distribution around
thepointcharge.
Jenaetal.'haverecently analyzed theisotopeef-
fectusingasemiempirical modelbasedontheband-
structure calculation andafirstprinciples calculation
basedonthepseudojellium model. Theyhaveshown
thatthesetwodistinctly different models yieldphysi-
callysimilarresultsontheelectron-spin densityat'H
and'DsitesinPdH.Theresultssuccessfully ex-
plainedthehighernuclear spin=-lattice relaxation
rate"ofDcompared to'Hasduetolargerzero-
pointvibrational amplitude ofhydrogen. Thereader
isreferred tothepaperofJenaetal.'fordetails.In
thissection wemakeacomparison oftheelectron
chargedistribution aroundadisplaced protonob-
tainedinboththepseudojellium andmolecular-
clustermodels. Thiscomparison shouldprovide
someinsightintothequantitative significance ofthe
resultsofthepseudojellium calculation.oo
o/
1.0—L2
/:~/
/
00.60.2
ISPLACEMENT(a l/CD
LLI
-0
0.8—
CA
CD
Lalo06-9
lD
0.4—
CL
0.2O
0I I I
00.40.8 l.2 l.6
r(a&)
FIG.5.Self-consistent molecular-cluster resultforelec-
troncharge-density distribution alongthe[100jdirection
aroundahydrogen atomlocatedat(0,0,0)(curve),
(0.3,0,0)(——-curve), (0.8,0,0)(——curve), and(1.2,0.0)
(—-—-curve). Theinsetshowsacomparison between the
electron chargedensityattheprotonsiteinamolecular-
cluster(solidcurve)andpseudojel)ium (dashed curve)
models.Inordertogaugethereliability ofthepseudojelli-
ummodelininterpreting effectsassociated withthe
zero-point vibration, wehavecarriedoutthe
molecular-cluster calculation (seeSec.III)forfour
different configurations ofthehydrogen atominside
thePdoctahedron, i.e.,theequilibrium siteandcon-
figurations ofhydrogen displaced by0.3ao,0.8ao,and
1.2aaalongthe[100)axis.Theresultsareplotted in
,Fig.5.
Thefactthattheelectrons followtheprotonfaith-
fullycanbeseenfromthefigure.Twootherin-
teresting pointsareworthnoting.First,theelectron
chargedistribution aroundtheprotonisverycloseto
beingisotropic evenforaprotondisplaced byas
muchas0.8aofromtheequilibrium configuration.
Second, theelectron densityattheprotonsiteasa
functionofdisplacement (seeinsetofFig.5)in-
creases rapidlyastheprotonapproaches thenearest-
neighbor Pdatom.Whiletheambient densityata
.point1.2aofromtheequilibrium configuration along
the[1001direction increases byafactorof2(seeFig.
I)theself-consistent proton-site densityincreases by
morethanafactorof3(seeFig.5).Thisenhance-
mentcanbeattributed totheformation ofastronger
Pd-Hbondasthenearest-neighbor Pd-Hdistance is
reduced to2,4Qp.Asimilardisplacement inother
directions produces asmallerenhancement. Thisan-
isotropyoftheprotonenvironment isprimarily
responsible forthedeviation between thepseudojelli-
umandtheclusterresultsforlargeprotondisplace-
ments.
3550 P.JENA,F.Y.FRADIN, ANDD.E.ELLIS 20
Tocompare theaboveresultswiththepredictions
ofthepseudojellium model, wehavefollowed the
sameprocedure asoutlined forthespindensity. The
resultsarecompared withthemolecular-cluster
modelintheinsetofFig.5.Notethatboththecal-
culations areincloseagreement witheachotherfor
displacements upto0.5aofromtheequilibrium config,-
uration. However, forlargerdisplacements, the
pseudojellium modelfailstoaccountforthesharp
riseintheelectron chargedensityattheprotonsite.
Theconfiguration-averaged chargedensity following
theprescription ofJenaetal.'inthemolecular-
clustermodelis0.35/ao3,whereas itis0.405/ao' inthe
pseudojellium model.Thenatureofthisagreement
between twomodels issimilartothatattheequilibri-
umconfiguration discussed earlier. Thiscloseagree-
mentbetween theconfiguration-averaged chargeden-
sities(inspiteofthelargediscrepancy forlargerdis-
placements) isnotsurprising sincetheprobability of
theprotonbeingatadisplaced position becomes con-
siderably smallerasthedisplacernent increases. Itis
encouraging thatthepseudojellium modelgivesnot
onlyqualitatively thesameresultfortheconfig-
uration-averaged chargedensityasthemoresophisti-
catedmolecular-cluster model,butitisalsoinsemi-
quantitative agreement withthelatter.Itistobe
notedthatclustercalculations willbequantitatively
influenced bybothclustersizeandboundary condi-
tion.A10%deviation isareasonable estimateof
theseeffects. Calculations ofelectron-spin densityat
theprotonsiteinthemolecular-cluster model,in-
cludingeffectsduetozero-point vibration, arenot
available atthepresent timetocompare withthe
pseudojellium model. However, wedonotexpect
anymajordifferences.
VIII.CONCLUSION
Inthispaperwehaveattempted togiveacompre-
hensive discussion oftheelectronic structure ofhy-
drogen inmetals. Although specific calculations for
thePd-hydrogen systemwereperformed, thetheoret-
icalmodelsandsubsequent discussions areapplicable
toageneral metal-hydrogen system. Ourresultsare
summarized inthefollowing:
(i)Ahomogeneous densityresponse modelwithin
theframework ofdensity-functional formalism
wasusedtocalculate thenonlinear electron charge
andspindistribution around hydrogen inpalladium.
Theresultswerecompared withourself-consistent
molecular-cluster model.Thechargedensity inthe
vicinityoftheprotoninthesetwomodelsisfound
toagreetowithin12%.We,therefore, suggest that
forsemiquantitative analysis, ourpseudojelliummodelwouldserveasanefficient calculational
method. Thismodelisparticularly attractive when
onerealizes thatthenumerical effortisconsiderably
lessthanthatinvolved inaself-consistent molecular-
clustercalculation' letalonethatinaself-consistent
supercell bandcalculation.'Theelectron-spin densi-
tyattheprotonsiteinthePd-Hsystemwasfoundto
beinfairagreement withthenon-self-consistent
bandcalculation forPdH.
(ii)Acomparison between ourmolecular-cluster
calculation andthebandstructure indicates agree-
mentinthenatureofthepalladium-hydrogen bond
andinthequalitative shapeofthepartialdensityof
states.
(iii)Fromacomparison oftheelectron chargedis-
tribution around palladium initspurestatewiththat
uponhydrogenation, wefindthatthereisasignifi-
cantchargetransfer fromthevincinityofthemetal
iontothehydrogen sphere. Thisconsequently
resultsinashiftinthecore-level binding energiesof
themetalioninthehydride phasetowards higher
binding ascompared toitspurestate.Thisresultis
consistent withasimilareffectobserved' inZrH~65
fromx-ray—photoelectron spectroscopy measure-
ments.Theresulting excesselectron densityaround
hydrogen inametallic environment compared tothat
infreespacegivesrisetoaphysical picturethathy-
drogen inmetalsremains inaslightly"anionic" state.
(iv)Theelectron-spin densityattheequilibrium
protonsitewascalculated self-consistently usingthe
generalized density-functional formalism.'Combined
withtheenergy-band densityofstatesofselectrons
attheFermienergy, thiscalculation yieldedthepro-
tonspin-lattice relaxation ratethatwas57%higher
than'the experimental value."Theeffectofthefin-
itemassoftheprotonanddeuteron ontheelectron
chargeandspindistribution ofthesurrounding elec-
tronswasstudied inPdHandPdDintwodistinctly
different models. Bothcalculations yieldalarger
electron-spin densityatthe'Dsitethanatthe'H
site—aresultinagreement withrecentexperimental
data.Theeffectofzero-point vibration ontheelec-
tronicstructure wasalsostudied intheself-consistent
molecular-cluster modelforvarious displacements of
theproton. Thetime-averaged chargedensityatthe
protonsitewasfoundtobeingoodagreement with
thepseudojellium model.
ACKNOWLEDGMENT
Thisworksupported bytheU.S.Department of
Energy.D.E.Ellisisalsosupported bytheNSF
through GrantNo.DMR77-22646. Wearethankful
toDr.S.K.Sinha,B.W.VealandD.J.Lamfor
manystimulating discussions.
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|
PhysRevB.96.161403.pdf | RAPID COMMUNICATIONS
PHYSICAL REVIEW B 96, 161403(R) (2017)
Nonlocal Andreev entanglements and triplet correlations in graphene with spin-orbit coupling
Razieh Beiranvand,1Hossein Hamzehpour,1,2and Mohammad Alidoust1
1Department of Physics, K.N. Toosi University of Technology, Tehran 15875-4416, Iran
2School of Physics, Institute for Research in Fundamental Sciences (IPM), 19395-5531 Tehran, Iran
(Received 27 February 2017; published 4 October 2017)
Using a wave function Dirac Bogoliubov–de Gennes method, we demonstrate that the tunable Fermi level of a
graphene layer in the presence of Rashba spin-orbit coupling (RSOC) allows for producing an anomalous nonlocalAndreev reflection and equal spin superconducting triplet pairing. We consider a graphene nanojunction of aferromagnet-RSOC-superconductor-ferromagnet configuration and study scattering processes, the appearance ofspin triplet correlations, and charge conductance in this structure. We show that the anomalous crossed Andreevreflection is linked to the equal spin triplet pairing. Moreover, by calculating current cross-correlations, ourresults reveal that this phenomenon causes negative charge conductance at weak voltages and can be revealed in aspectroscopy experiment, and may provide a tool for detecting the entanglement of the equal spin superconductingpair correlations in hybrid structures.
DOI: 10.1103/PhysRevB.96.161403
Introduction . Superconductivity and its hybrid structures
with other phases can host a wide variety of intriguingfundamental phenomena and functional applications such asHiggs mechanism [ 1], Majorana fermions [ 2], topological
quantum computation [ 3], spintronics [ 4], and quantum entan-
glement [ 5–8]. The quantum entanglement describes quantum
states of correlated objects with nonzero distances [ 6,8] that
are expected to be employed in novel ultrafast technologiessuch as secure quantum computing [ 3,6].
From the perspective of BCS theory, s-wave singlet super-
conductivity is a bosonic phase created by the coupling of twocharged particles with opposite spins and momenta (forming
a so-called Cooper pair) through an attractive potential [ 9].
The two particles forming a Cooper pair can spatially havea distance equal or less than a coherence length ξ
S[9].
Therefore, a Cooper pair in the BCS scenario can serve asa natural source of entanglement with entangled spin andmomentum. As a consequence, one can imagine a heterostruc-ture made of a single s-wave superconductor and multiple
nonsuperconducting electrodes in which an electron and hole
excitation from different electrodes are coupled by means ofa nonlocal Andreev process [ 7,10–13]. This idea has so far
motivated numerous theoretical and experimental endeavoursto explore this entangled state in various geometries andmaterials [ 12,14–27]. Nonetheless, the nonlocal Andreev
process is accompanied by an elastic cotunneling current
that makes it practically difficult to detect unambiguously
the signatures of a nonlocal entangled state [ 10,11,13–17].
This issue, however, may be eliminated by making use of agraphene-based hybrid device that allows for locally controlledFermi level [ 26].
On the other hand, the interplay of s-wave supercon-
ductivity and an inhomogeneous magnetization can convertthe superconducting spin singlet correlations into equal spintriplets [ 28,29]. After the theoretical prediction of the spin
triplet superconducting correlations much effort has beenmade to confirm their existence [ 4,30–43]. For example, a
finite supercurrent was observed in a half-metallic junctionthat was attributed to the generation of equal spin tripletcorrelations near the superconductor–half-metal interface [ 30].
Also, it was observed that in a Josephson junction madeof a holmium–cobalt–holmium stack, the supercurrent as a
function of the cobalt layer decays exponentially withoutany sign reversals due to the presence of equal spin tripletpairings [ 36,37]. One more signature of the equal spin triplet
pairings generated in the hybrid structures may be detected insuperconducting critical temperature [ 43–46] and density of
states [ 47–50]. Nevertheless, a direct observation of the equal
spin triplet pairings in the hybrid structures is still lacking.
In this Rapid Communication, we show that the existence
of the equal spin superconducting triplet correlations canbe revealed through charge conductance spectroscopy of agraphene-based ferromagnet–Rashba SOC–superconductor–ferromagnet junction. We study all possible electron/holereflections and transmissions in such a configuration andshow that by tuning the Fermi level a regime is accessiblein which spin reversed cotunneling and usual crossed Andreevreflections are blocked while a conventional cotunneling andanomalous nonlocal Andreev channel is allowed. We justifyour findings by analyzing the band structure of the system.Moreover, we calculate various superconducting correlationsand show that, in this regime, the equal spin triplet correlationhas a finite amplitude while the unequal spin triplet componentvanishes. Our results show that the anomalous crossed Andreevreflection results in a negative charge conductance at lowvoltages applied across the junction and can be interpretedas evidence for the generation and entanglement of equalspin superconducting triplet correlations in hybrid structures[51–55].
Method and results . As seen in Fig. 1, we assume that the
ferromagnetism, superconductivity, and spin-orbit couplingare separately induced into the graphene layer through theproximity effect as reported experimentally in Refs. [ 56–58]
for isolated samples. Therefore, the low-energy behavior ofquasiparticles, quantum transport characteristics, and thermo-dynamics of such a system can be described by the DiracBogoliubov–de Gennes (DBdG) formalism [ 34,59]:
/parenleftbigg
H
D+Hi−μi/Delta1eiφ
/Delta1∗e−iφμi−T[HD−Hi]T−1/parenrightbigg/parenleftbigg
u
v/parenrightbigg
=ε/parenleftbigg
u
v/parenrightbigg
,
(1)
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in which εis the quasiparticles’ energy and Trepresents a
time-reversal operator [ 34,59]. Here HD=¯hvFs0⊗(σxkx+
σyky) with vFbeing the Fermi velocity [ 59].sx,y,z andσx,y,z
are 2×2 Pauli matrices, acting on the spin and pseudospindegrees of freedom, respectively. The superconductor region
with a macroscopic phase φis described by a gap /Delta1in the
energy spectrum. The chemical potential in a region iis shown
byμiwhile the corresponding Hamiltonians read
Hi=⎧
⎪⎨
⎪⎩HF=hl(sz⊗σ0),x /lessorequalslant0
HRSO=λ(sy⊗σx−sx⊗σy),0/lessorequalslantx/lessorequalslantLRSO
HS=−U0(s0⊗σ0),L RSO/lessorequalslantx/lessorequalslantLS+LRSO
HF=hr(sz⊗σ0),L S+LRSO/lessorequalslantx.(2)
The magnetization /vectorhl,rin the ferromagnet segments are assumed fixed along the zdirection with a finite intensity hl,r.λis the
strength of Rashba spin-orbit coupling and U0is an electrostatic potential in the superconducting region. Previous self-consistent
calculations have demonstrated that sharp interfaces between the regions can be an appropriate approximation [ 34,59–62]. The
length of the RSO and S regions are LRSOandLS, respectively.
To determine the properties of the system, we diagonalize the DBdG Hamiltonian equation ( 1) in each region and obtain
corresponding eigenvalues:
ε=⎧
⎪⎪⎪⎪⎪⎪⎪⎨
⎪⎪⎪⎪⎪⎪⎪⎩±μ
Fl±/radicalBig/parenleftbig
kFlx/parenrightbig2+q2n±hl,x /lessorequalslant0
±μRSO±/radicalBig/parenleftbig
kRSOx/parenrightbig2+q2n+λ2±λ, 0/lessorequalslantx/lessorequalslantLRSO
±/radicalbigg
/parenleftbig
μS+U0±/radicalBig/parenleftbig
kSx/parenrightbig2+q2n/parenrightbig2+|/Delta10|2,L RSO/lessorequalslantx/lessorequalslantLRSO+LS
±μFr±/radicalBig/parenleftbig
kFrx/parenrightbig2+q2n±hr,L RSO+LS/lessorequalslantx.(3)
The associated eigenfunctions are given in Ref. [ 63]. The wave
vector of a quasiparticle in region iiski=(ki
x,qn) so that its
transverse component is assumed conserved upon scattering.In what follows, we consider a heavily doped superconductorU
0/greatermuchε,/Delta1 which is an experimentally relevant regime [ 59].
We also normalize energies by the superconducting gap at zerotemperature /Delta1
0and lengths by the superconducting coherent
length ξS=¯hvF//Delta10.
Since the magnetization in F regions is directed along the
zaxis, which is the quantization axis, it allows for unam-
biguously analyzing spin-dependent processes. Therefore, weconsider a situation where an electron with spin-up (described
by wave function ψ
F,+
e,↑) hits the RSO interface at x=0 due to
a voltage bias applied. This particle can reflect back ( ψF,−
e,↑(↓))
with probability amplitude r↑(↓)
Nor enter the superconductor as
a Cooper pair and a hole ( ψF,−
h,↑(↓)) with probability amplitude
FIG. 1. Schematic of the graphene-based F-RSO-S-F hybrid. The
system resides in the xyplane and the junctions are located along the
xaxis. The length of the RSO and S regions are denoted by LRSOand
LS. The magnetization of the F regions ( /vectorhl,r) are assumed fixed along
thezaxis. We assume that the ferromagnetism, spin-orbit coupling,
and superconductivity is induced into the graphene layer by meansof the proximity effect.r↑(↓)
Areflects back, which is the so-called Andreev reflection.
Hence, the total wave function in the left F region is (seeRefs. [ 53,63])
/Psi1
Fl(x)=ψF,+
e,↑(x)+r↑
NψF,−
e,↑(x)+r↓
NψF,−
e,↓(x)
+r↓
AψF,−
h,↓(x)+r↑
AψF,−
h,↑(x). (4)
The total wave function in the RSO and S parts are su-
perpositions of right- and left-moving spinors with differentquantum states n;ψ
RSO
nandψS
n(see Ref. [ 63]):/Psi1RSO(x)=/summationtext8
n=1anψRSO
n(x) and /Psi1S(x)=/summationtext8
n=1bnψS
n(x), respectively.
The incident particle eventually can transmit into the right F
region as an electron or hole ( ψF,+
e,↑↓,ψF,+
h,↑↓) with probability
amplitudes t↑↓
eandt↑↓
h:
/Psi1Fr(x)=t↑
eψF,+
e,↑(x)+t↓
eψF,+
e,↓(x)+t↓
hψF,+
h,↓(x)+t↑
hψF,+
h,↑(x).
(5)
The transmitted hole is the so-called crossed Andreev reflec-tion (CAR). By matching the wave functions at F-RSO, RSO-
S, and S-F interfaces we obtain the probabilities described
above. Figure 2exhibits the probabilities of usual electron
cotunneling |t↑
e|2, spin-flipped electron |t↓
e|2, usual crossed
Andreev reflection |t↓
h|2, and anomalous crossed Andreev
reflection |t↑
h|2. To have a strong anomalous CAR signal, we
setLS=0.4ξSwhich is smaller than the superconducting
coherence length and LRSO=0.5ξS[11]. We also choose
μFl=μFr=hl=hr=0.8/Delta10,μRSO=2.6/Delta10,λ=/Delta10and
later clarify physical reasons behind this choice using band-structure analyses. In terms of realistic numbers, if thesuperconductor is Nb [ 62] with a gap of the order of /Delta1
0∼
1.03 meV and coherence length ξS∼10 nm, the chemical
potentials, magnetization strengths, and the RSO intensityareμ
Fl=μFr=hl=hr=0.824 meV, μRSO=2.68 meV,
161403-2RAPID COMMUNICATIONS
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FIG. 2. (a) Spin-reversed cotunneling probability |t↓
e|2.
(b) Anomalous crossed Andreev reflection probability |t↑
h|2.
(c) Conventional cotunneling |t↑
e|2. (d) Usual CAR |t↓
h|2.T h e
probabilities are plotted vs the transverse component of wave vector
qnand voltage bias across the junction eV.W es e t μFl=μFr=hl=
hr=0.8/Delta10,μRSO=2.6/Delta10,λ=/Delta10,L RSO=0.5ξS,L S=0.4ξS.
λ=1.03 meV, respectively [ 56,57], andLS=4n m , LRSO=
5 nm. We see that the anomalous CAR has a finite amplitudeand its maximum is well isolated from the other transmissionchannels in the parameter space. Therefore, by tuning the localFermi levels the system can reside in a regime that allows for astrong signal of the anomalous CAR. According to Fig. 2this
regime is accessible at low voltages eV/lessmuch/Delta1
0.
The eigenvalues, Eqs. ( 3), determine the propagation
critical angles of moving particles through the junction. Byconsidering the conservation of transverse component of wavevector throughout the system, we obtain the following criticalangles [ 59]:
α
c
e,↓=arcsin/vextendsingle/vextendsingle/vextendsingleε+μFr−hr
ε+μFl+hl/vextendsingle/vextendsingle/vextendsingle, (6a)
αc
h,↓=arcsin/vextendsingle/vextendsingle/vextendsingleε−μFr+hr
ε+μFl+hl/vextendsingle/vextendsingle/vextendsingle, (6b)
αc
e,↑=arcsin/vextendsingle/vextendsingle/vextendsingleε+μFr+hr
ε+μFl+hl/vextendsingle/vextendsingle/vextendsingle, (6c)
αc
h,↑=arcsin/vextendsingle/vextendsingle/vextendsingleε−μFr−hr
ε+μFl+hl/vextendsingle/vextendsingle/vextendsingle. (6d)
These critical angles are useful in calibrating the device
properly for a regime of interest. For the spin-reversedcotunneling, the critical angle is denoted by α
c
e,↓, while for the
conventional CAR we show this quantity by αc
h,↓. Hence, to
filter out these two transmission channels, we set μFr=hrand
choose a representative value 0 .8/Delta10. In this regime, we see that
αc
e(h),↓→0 at low energies, i.e., μFr,hr,/Delta1/greatermuchε→0 and thus,
the corresponding transmissions are eliminated. This is clearlyseen in Figs. 2(a) and2(d) ateV/lessmuch/Delta1
0. At the same time,
the critical angles to the propagation of conventional electroncotunneling and anomalous crossed Andreev reflection reachnear their maximum values α
c
e(h),↑→π/2 consistent with
Figs. 2(b) and 2(c). We have analyzed the reflection and
transmission processes using a band-structure plot, presented-0.0400.04
0.40
0.80
-0.0400.04
0.9 1.5 2 2.5-0.400.4
0.9 1.5 2 2.5-0.400.4(a) (b)
(c) (d)
FIG. 3. (a)–(d) Real and imaginary parts of opposite spin f0and
equal spin pairings f1within the Frregion x/greaterorequalslantLRSO+LSat weak
voltages eV/lessmuch/Delta10. The parameter values are the same as those of
Fig. 2except we now compare two cases where μFl=μFr=hl=
0.8/Delta10andhr=0.4/Delta10,0.8/Delta10.
in Ref. [ 63], that can provide more sense on how a particle is
scattered in this regime.
To gain better insights into the anomalous CAR, we
calculate the opposite ( f0) and equal ( f1) spin-pair correlations
in the Frregion [ 31,34]:
f0(x,t)=+1
2/summationdisplay
βξ(t)[u↑
β,Kv↓,∗
β,K/prime+u↑
β,K/primev↓∗
β,K
−u↓
β,Kv↑∗
β,K/prime−u↓
β,K/primev↑∗
β,K], (7a)
f1(x,t)=−1
2/summationdisplay
βξ(t)[u↑
β,Kv↑,∗
β,K/prime+u↑
β,K/primev↑∗
β,K
+u↓
β,Kv↓∗
β,K/prime+u↓
β,K/primev↓∗
β,K], (7b)
where KandK/primedenote different valleys and βstands
forAandBsublattices [ 34,59]. Here, ξ(t)=cos(εt)−
isin(εt) tanh( ε/2T),tis the relative time in the Heisenberg
picture, and Tis the temperature of the system [ 31,34].
Figure 3shows the real and imaginary parts of opposite
and equal spin pairings in the Frregion, extended from x=
LRSO+LSto infinity, at eV/lessmuch/Delta10. For the set of parameters
corresponding to Fig. 2, we see that f0pair correlation is
vanishingly small, while the equal spin triplet pair correlationf
1has a finite amplitude. We also plot these correlations for
a different set of parameters where μFl=μFr=hl=0.8/Delta10,
whilehr=0.4/Delta10. The opposite spin triplet pairing f0is now
nonzero too. Therefore, at low voltages and the parameterset of Fig. 2, the nonvanishing triplet correlation is f
1, which
demonstrates the direct link of f1andt↑
h. This direct connection
can be proven by looking at the total wave function in the right
161403-3RAPID COMMUNICATIONS
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0 1201
0G
G(a)
01201
(d) (c)(b)
01201hG↓hG↑
eG↓eG↑
0eVΔ01201
0eVΔ
FIG. 4. Charge conductance (top panels) and its components
(bottom panels). (a) and (c) charge conductance associated withthe probabilities presented in Figs. 2and3(h
r=0.8/Delta10) and its
components, respectively. (b) and (d) the same as panels (a) and (c)
except we now consider hr=0.4 (see Fig. 3). The conductance is
normalized by G0=G↑+G↓.
F region, Eq. ( 5), transmission probabilities shown in Fig. 2,
and the definition of triplet correlations, Eqs. ( 7). One can
show that when t↓
eandt↓
hvanish, f0disappears and f1remains
nonzero, which offers a spin triplet valve effect.
We calculate the charge conductance through the BTK
formalism:
G=/integraldisplay
dqn/summationdisplay
s=↑,↓Gs/parenleftbig/vextendsingle/vextendsinglets
e/vextendsingle/vextendsingle2−/vextendsingle/vextendsinglets
h/vextendsingle/vextendsingle2/parenrightbig
, (8)
where we define G↑↓=2e2|ε+μl±hl|W/hπ in which W
is the width of the junction. Figures 4(a) and4(b) exhibit the
charge conductance as a function of bias voltage eVacross the
junction at hr=0.8/Delta10and 0.4/Delta10, while the other parameters
are set the same as those of Figs. 2and3. As seen, the charge
conductance is negative at low voltages when hr=0.8/Delta10,
whereas this quantity becomes positive for hr=0.4/Delta10.T o
gain better insights, we separate the charge conductance into
G↑↓(↑↓)
e,(h), corresponding to the transmission coefficients t↑↓(↑↓)
e,(h)
used in Eq. ( 8). Figures 4(c)and4(d)illustrate the contribution
of different transmission coefficients into the conductance.We see in Fig. 4(c) thatG↑
hdominates the other components
and makes the conductance negative. As discussed earlier,this component corresponds to the anomalous CAR whichis linked to the equal spin triplet pairing, Fig. 3.T h i scomponent, however, suppresses when h
r=0.4/Delta10so that the
other contributions dominate, and therefore the conductanceis positive for all energies. Hence, the nonlocal anomalousAndreev reflection found in this work can be revealed ina charge conductance spectroscopy. There are also abruptchanges in the conductance curves that can be fully understoodby analyzing the band structure. We present such an analysisin Ref. [ 63].
In line with the theoretical works summarized in Ref. [ 59],
we have neglected spin-dependent and -independent impuritiesand disorders as well as substrate and interface effects inour calculations [ 64–66]. Nonetheless, a recent experiment
has shown that such a regime is accessible with today’sequipment [ 62]. Moreover, the same assumptions have already
resulted in fundamentally important predictions such as thespecular Andreev reflection [ 59] that was recently observed
in experiment [ 61]. The experimentally measured mean free
path of moving particles in a monolayer graphene depositedon top of a hexagonal boron nitride substrate is around /lscript∼
140 nm [ 67]. The coherence length of induced superconduc-
tivity into a monolayer graphene using a Nb superconductorwas reported as ξ
S∼10 nm [ 62]. In this situation, where
/lscript/greatermuchξS, the Andreev mechanism is experimentally relevant.
On the other hand, it has been demonstrated that the equal-spinpairings discussed here are long range and can survive evenin systems with numerous strong spin-independent scattering
resources [ 40–42]. Therefore, as far as the Andreev mechanism
is a relevant scenario in a graphene-based F-RSO-S-F devicecontaining spin-independent scattering resources, i.e., /lscript/greatermuchξ
S,
we expect that the negative conductance explored in this RapidCommunication is experimentally accessible.
In conclusion, motivated by recent experimental achieve-
ments in the induction of spin-orbit coupling into a graphenelayer [ 56,57], we have theoretically studied quantum trans-
port properties of a graphene-based ferromagnet-RSOC-superconductor-ferromagnet junction. Our results reveal thatby manipulating the Fermi level in each segment, one cancreate a dominated anomalous crossed Andreev reflection. Wecalculate the charge conductance of the system in this regimeand show that this phenomenon results in negative chargeconductance at low voltages. By calculating various pairingcorrelations, we demonstrate a direct link between the appear-ance of anomalous CAR and equal spin triplet correlations.Our findings suggest that a conductance spectroscopy of sucha junction can detect the signatures of the anomalous CAR andentanglement of equal spin superconducting triplet pairings inhybrid structures.
Acknowledgments . We are grateful to M. Salehi for valuable
and helpful discussions. M.A. also thanks K. Halterman foruseful conversations. M.A. is supported by Iran’s NationalElites Foundation (INEF).
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