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B.Verkin Istitute for Low Temperature Physics and Engineering of theNational Academy of Science of Ukraine,Kharkov 61103, Ukraine
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1. Introduction
To present day overwhelming majority works on theory of superconductivity were devoted to single gap superconductors. More than 50 years ago the possibility of superconductors with two superconducting order parameters were considered by V. Moskalenko
Figure 1.
a. The structure of MgB2 and the Fermi surface of MgB2 calculated by Kortus et al. (Kortus et al., 2001). b. The coexistence of two complex order parameters (in momentum space).
Two-band superconductivity proposes new interesting physics. The coexistence of two distinctive order parameters Ψ1=|Ψ1|exp(iϕ1)and Ψ2=|Ψ2|exp(iϕ2) (Fig.1.b.) renewed interest in phase coherent effects in superconductors. In the case of two order parameters we have the additional degree of freedom, and the question arises, what is the phase shift δϕ=ϕ1−ϕ2 between Ψ1 andΨ2? How this phase shift manifested in the observable effects? From the minimization of the free energy it follows that in homogeneous equilibrium state this phase shift is fixed at 0 orπ, depending on the sign of interband coupling. It does not exclude the possibility of soliton-like states δϕ(x) in the ring geometry (Tanaka, 2002). In nonequilibrium state the phases ϕ1 and ϕ2 can be decoupled as small plasmon oscillations (Leggett mode) (Legett, 1966) or due to formation of phase slips textures in strong electric field (Gurevich & Vinokur, 2006).
In this chapter we are focusing on the implication of the δϕ-shift in the coherent superconducting current states in two-band superconductors. We use a simple (and, at the same time, quite general) approach of the Ginsburg–Landau theory, generalized on the case of two superconducting order parameters (Sec.2). In Sec.3 the coherent current states and depairing curves have been studied. It is shown the possibility of phase shift switching in homogeneous current state with increasing of the superfluid velocityvs. Such switching manifests itself in the dependence j(vs)and also in the Little-Parks effect (Sec.3). The Josephson effect in superconducting junctions is the probe for research of phase coherent effects. The stationary Josephson effect in tunnel S1-I-S2 junctions (I - dielectric) between two- and one- band superconductors have been studied recently in a number of articles (Agterberg et al., 2002; Ota et al., 2009; Ng & Nagaosa, 2009). Another basic type of Josephson junctions are the junctions with direct conductivity, S-C-S contacts (C – constriction). As was shown in (Kulik & Omelyanchouk, 1975; Kulik & Omelyanchouk, 1978; Artemenko et al., 1979) the Josephson behavior of S-C-S structures qualitatively differs from the properties of tunnel junctions. A simple theory (analog of Aslamazov-Larkin theory( Aslamazov & Larkin, 1968)) of stationary Josephson effect in S-C-S point contacts for the case of two-band superconductors is described in Sec.4).
The terms F1 and F2 are conventional contributions from ψ1 andψ2, term F12 describes without the loss of generality the interband coupling of order parameters. The coefficients γ and ηdescribe the coupling of two order parameters (proximity effect) and their gradients (drag effect) (Askerzade, 2003a; Askerzade, 2003b; Doh et al., 1999), respectively. The microscopic theory for two-band superconductors (Koshelev & Golubov, 2003; Zhitomirsky & Dao, 2004; Gurevich, 2007) relates the phenomenological parameters to microscopic characteristics of superconducting state. Thus, in clean multiband systems the drag coupling term (η) is vanished. Also, on phenomenological level there is an important condition, that absolute minimum of free GL energy exist: |η|<12m1m2(see Yerin et al., 2008).
By minimization the free energy F=∫(F1+F2+F12+H28π)d3r with respect toψ1, ψ2and A→ we obtain the differential GL equations for two-band superconductor
For the case of two order parameters the question arises about the phase difference ϕ=χ1−χ2 between ψ1 andψ2. In homogeneous zero current state, by analyzing the free energy term F12 (3), one can obtain that for γ>0 phase shift ϕ=0 and for γ<0ϕ=π. The statement, that ϕ can have only values 0 or π takes place also in a current carrying state, but for coefficient η≠0 the criterion for ϕequals 0 or π depends now on the value of the current (see below).
If the interband interaction is ignored, the equations (7) are decoupled into two ordinary GL equations with two different critical temperaturesTc1andTc2. In general, independently of the sign ofγ, the superconducting phase transition results at a well-defined temperature exceeding both Tc1andTc2, which is determined from the equation:
α1(Tc)α2(Tc)=γ2.E8
Let the first order parameter is stronger then second one, i.e.Tc1>Tc2. Following (Zhitomirsky & Dao, 2004) we represent temperature dependent coefficients as
α1(T)=−a1(1−T/Tc1),α2(T)=a20−a2(1−T/Tc1).E9
Phenomenological constants a1,2,a20 and β1,2,γ can be related to microscopic parameters in two-band BCS model. From (8) and (9) we obtain for the critical temperatureTc:
Tc=Tc1(1+(a202a2)2+γ2a1a2−a202a2).E10
For arbitrary value of the interband coupling γ Eq.(6) can be solved numerically. Forγ=0, Tc=Tc1and for temperature close to Tc (hence forTc2<T≤Tc) equilibrium values of the order parameters areψ2(0)(T)=0,ψ1(0)(T)=a1(1−T/Tc)/β1. Considering in the following weak interband coupling, we have from Eqs. (6-9) corrections ∼γ2 to these values:
Considered above case (expressions (10)-(12)) corresponds to different critical temperatures Tc1>Tc2 in the absence of interband couplingγ. Order parameter in the second band ψ2(0) arises from the “proximity effect” of stronger ψ1(0) and is proportional to the value ofγ.
Consider now another situation, which we will use in the following as the model case. Suppose for simplicity that two condensates in current zero state are identical. In this case for arbitrary value of γ we have
3. Homogeneous current states and GL depairing current
In this section we will consider the homogeneous current states in thin wire or film with transverse dimensionsd≪ξ1,2(T),λ1,2(T), where ξ1,2(T)and λ1,2(T)are coherence lengths and London penetration depths for each order parameter, respectively. This condition leads to a one-dimensional problem and permits us to neglect the self-magnetic field of the system. (see Fig.2). In the absence of external magnetic field we use the calibrationA→=0.
Figure 2.
Geometry of the system.
The current density j and modules of the order parameters do not depend on the longitudinal direction x. Writing ψ1,2(x) as ψ1,2=|ψ1,2|exp(iχ1,2(x)) and introducing the difference and weighted sum phases:
The current density j in terms of phases θ and ϕ has the following form
j=2eℏ(|ψ1|2m1+|ψ2|2m2+4η|ψ1||ψ2|cosϕ)dθdx.E18
Total current j includes the partial inputs j1,2 and proportional to η the drag currentj12.
In contrast to the case of single order parameter (De Gennes, 1966), the condition divj=0does not fix the constancy of superfluid velocity. The Euler – Lagrange equations for θ(x) and ϕ(x) are complicated coupled nonlinear equations, which generally permit the soliton like solutions (in the case η=0 they were considered in (Tanaka, 2002)). The possibility of states with inhomogeneous phase ϕ(x)is needed in separate investigation. Here, we restrict our consideration by the homogeneous phase difference between order parametersϕ=const. For ϕ=const from equations it follows that θ(x)=qx(q is total superfluid momentum) andcosϕ=0, i.e. ϕequals 0 orπ. Minimization of free energy for ϕ gives
cosϕ=sign(γ−ηℏ2q2).E19
Note, that now the value ofϕ, in principle, depends on q, thus, on current density j. Finally, the expressions (16), (18) take the form:
We will parameterize the current states by the value of superfluid momentumq, which for given value of j is determined by equation (21). The dependence of the order parameter modules on q determines by GL equations:
The system of equations (21-23) describes the depairing curve j(q,T) and the dependences |ψ1| and |ψ2| on the current j and the temperature T. It can be solved numerically for given superconductor with concrete values of phenomenological parameters.
In order to study the specific effects produced by the interband coupling and dragging consider now the model case when order parameters coincide at j=0 (Eqs. (13), (14)) but gradient terms in equations (4) are different. Eqs. (21)-(23) in this case take the form
Here we normalize ψ1,2 on the value of the order parameters at j=0 (14), jis measured in units of22e|γ|+|α|β|α|m1, qis measured in units ofℏ22m1|α|, γ˜=γ|α|, η˜=2ηm1,k=m1m2. If k=1 order parameters coincides also in current-carrying state f1=f2=f and from eqs. (24, 25) we have the expressions
f2(q)=1−q2+|γ˜−η˜q2|1+|γ˜|E26
j(q)=2f2(1+η˜sign(γ˜−η˜q2))q,E27
which for γ˜=η˜=0 are conventional dependences for one-band superconductor (De Gennes, 1966) (see Fig. 3 a,b).
Figure 3.
Depairing current curve (a) and the graph of the order parameter modules versus current (b) for coincident order parameters. The unstable branches are shown as dashed lines.
For k≠1 depairing curve j(q) can contain two increasing with q stable branches, which corresponds to possibility of bistable state. In Fig. 4 the numerically calculated from equations (24,25) curve j(q)is shown for k=5 andγ˜=η˜=0.
The interband scattering (γ˜≠0) smears the second peak inj(q), see Fig.5.
If dragging effect (η˜≠0) is taking into account the depairing curve j(q) can contain the jump at definite value of q (for k=1 see eq. 34), see Fig.6. This jump corresponds to the switching of relative phase difference from 0 toπ.
Figure 4.
Dependence of the current j on the superfluid momentum q for two band superconductor. For the value of the current j=j0 the stable (∘) and unstable (·) states are depicted. The ratio of effective massesk=5, andγ˜=η˜=0.
Figure 5.
Depairing current curves for different values of interband interaction: γ˜=0(solid line), γ˜=0.1(dotted line) and γ˜=1 (dashed line). The ratio of effective massesk=5, andη˜=0.
Figure 6.
Depairing current curves for different values of the effective masses ratio k=1 (solid line), k=1.5(dotted line) and k=5 (dashed line). The interband interaction coefficient γ˜=0.1 and drag effect coefficientη˜=0.5.
4. Little-Parks effect for two-band superconductors
In the present section we briefly consider the Little–Parks effect for two-band superconductors. The detailed rigorous theory can be found in the article (Yerin et al., 2008). It is pertinent to recall that the classical Little–Parks effect for single-band superconductors is well-known as one of the most striking demonstrations of the macroscopic phase coherence of the superconducting order parameter (De Gennes, 1966; Tinkham, 1996). It is observed in open thin-wall superconducting cylinders in the presence of a constant external magnetic field oriented along the axis of the cylinder. Under conditions where the field is essentially unscreened the superconducting transition temperature TcΦ(Φis the magnetic flux through the cylinder) undergoes strictly periodic oscillations (Little–Parks oscillations)
Tc−TcΦTc∝min(ΦΦ0−n)2,(n=0,±1,±2,...),E28
where TcΦ≡TcΦ|Φ=0and Φ0=πℏc/e is the quantum of magnetic flux.
How the Little–Parks oscillations (28) will be modified in the case of two order parameters with taking into account the proximity (γ) and dragging (η) coupling? Let us consider a superconducting film in the form of a hollow thin cylinder in an external magnetic field H (see Fig.6).
We proceed with free energy density (20), but now the momentum q is not determined by the fixed current density j as in Sec.3. At given magnetic flux ∮A→⋅dl→=∫H→⋅dσ→=Φthe superfluid momentum q is related to the applied magnetic field
q=1R(n−ΦΦ0).E29
At fixed flux Φthe value of q take on the infinite discrete set of values forn=0,±1,±2,.... The possible values of n are determined from the minimization of free energyF[|ψ1|,|ψ2|,q]. As a result the critical temperature of superconducting film depends on the magnetic field. The dependencies of the relative shift of the critical temperature Δtc≡(Tc−TcΦ)/Tc for different values of parameters γ,β,R were calculated in (Yerin et al., 2008). The dependence of Δtc(Φ) as in the conventional case is strict periodic function of Φwith the period Φ0(contrary to the assertions made in Askerzade, 2006). The main qualitative difference from the classical case is the nonparabolic character of the flux dependence Δtc(Φ) in regions with the fixed optimal value ofn. More than that, the term (γ−ηℏ2q2)sign(γ−ηℏ2q2) in the free energy (19) engenders possibility of observable singularities in the functionΔtc(Φ), which are completely absent in the classical case (see Fig.8.).
Figure 7.
Geometry of the problem.
Figure 8.
Formula: Eqn199.wmf>for the case where the bands 1 and 2 have identical parameters and values of Δtc(Φ) are indicated.
5. Josephson effect in two-band superconducting microconstriction
In the Sec.3 GL-theory of two-band superconductors was applied for filament’s lengthη˜. Opposite case of the strongly inhomogeneous current state is the Josephson microbridge or point contact geometry (Superconductor-Constriction-Superconductor contact), which we model as narrow channel connecting two massive superconductors (banks). The length L→∞ and the diameterL of the channel (see Fig. 9) are assumed to be small as compared to the order parameters coherence lengthsd.
Figure 9.
Geometry of S-C-S contact as narrow superconducting channel in contact with bulk two-band superconductors. The values of the order parameters at the left (L) and right (R) banks are indicated
For ξ1,ξ2 we can solve one-dimensional GL equations (5) inside the channel with the rigid boundary conditions for order parameters at the ends of the channel.
In the cased≪L we can neglect in equations (5) all terms except the gradient ones and solve equations:
L≪ξ1,ξ2E30
with the boundary conditions:
{d2ψ1dx2=0,d2ψ2dx2=0E31
Calculating the current density ψ1(0)=ψ01exp(iχ1L),ψ2(0)=ψ02exp(iχ1R),ψ1(L)=ψ01exp(iχ2L),ψ2(L)=ψ02exp(iχ1R). in the channel we obtain:
jE32
j=j11+j22+j12+j21E33
j11=2eℏLm1ψ012sin(χ1R−χ1L),E34
j22=2eℏLm1ψ012sin(χ2R−χ2L),E35
j12=η4eℏLψ01ψ02sin(χ1R−χ2L),E36
The current density j21=η4eℏLψ02ψ01sin(χ2R−χ1L). (32) consists of four partials inputs produced by transitions from left bank to right bank between different bands. The relative directions of components j depend on the intrinsic phase shifts in the banks jik and δϕL=χ1L−χ2L (Fig.10).
Figure 10.
Current directions in S-C-S contact between two-band superconductors. (a) – there is no shift between phases of order parameters in the left and right superconductors; (b) - there is the δϕR=χ1R−χ2R-shift of order parameters phases at the both banks ; (c) –π-shift is present in the right superconductor and is absent in the left superconductor; (d) –π-shift is present in the left superconductor and is absent in the right superconductor.
Introducing the phase difference on the contact π we have the current-phase relation φ=χ1R−χ1L for different cases of phase shifts j(ϕ) in the banks:
δϕR,LE37
j≡jcsinϕ=2eℏL(ψ012m1+ψ022m2+4ηψ01ψ02)sinϕE38
δϕR=δϕL=πE39
j≡jcsinϕ=2eℏL(ψ012m1+ψ022m2−4ηψ01ψ02)sinϕE40
δϕR=π,δϕL=0E41
j≡jcsinϕ=2eℏL(ψ012m1−ψ022m2)sin(ϕ)E42
δϕR=0,δϕL=πE43
The critical current j≡jcsinϕ=2eℏL(−ψ012m1+ψ022m2)sin(ϕ) in cases a) and b) is positively defined quadratic form of jc and ψ01forψ02. In cases c) and d) the value of |η|<12m1m2 can be negative. It corresponds to the so-called jcjunction (see e.g. (Golubov et. al, 2004)) (see illustration at Fig.11).
Figure 11.
Current-phase relations for different phase shifts in the banks.
This phenomenological theory, which is valid for temperatures near critical temperatureπ−, is the generalization of Aslamazov-Larkin theory (Aslamazov & Larkin, 1968) for the case of two superconducting order parameters. The microscopic theory of Josephson effect in S-C-S junctions (KO theory) was developed in (Kulik & Omelyanchouk, 1975; Kulik & Omelyanchouk, 1978;) by solving the Usadel and Eilenberger equations (for dirty and clean limits). In papers (Omelyanchouk & Yerin, 2009; Yerin & Omelyanchouk, 2010) we generalized KO theory for the contact of two-band superconductors. Within the microscopic Usadel equations we calculate the Josephson current and study its dependence on the mixing of order parameters due to interband scattering and phase shifts in the contacting two-band superconductors. These results extend the phenomenological theory presented in this Section on the range of all temperaturesTc. The qualitative feature is the possibility of intermediate between 0<T<Tc and sinϕ behavior −sinϕ at low temperatures (Fig.12).
Figure 12.
The possible current-phase relations j(ϕ) for hetero-contact withj(ϕ).
In this chapter the current carrying states in two-band superconductors are described in the frame of phenomenological Ginzburg-Landau theory. The qualitative new feature, as compared with conventional superconductors, consists in coexistence of two distinct complex order parameters δϕR=0,δϕL=π andΨ1. It means the appearing of an additional internal degree of freedom, the phase shift between order parameters. We have studied the implications of the Ψ2-shift in homogeneous current state in long films or channels, Little-Parks oscillations in magnetic field, Josephson effect in microconstrictions. The observable effects are predicted. Along with fundamental problems, the application of two band superconductors with internal phase shift in SQUIDS represents significant interest (see review (Brinkman & Rowell, 2007).
The author highly appreciates S. Kuplevakhskii and Y.Yerin for fruitful collaborations and discussions. The research is partially supported by the Grant 04/10-N of NAS of Ukraine.
References
1.AgterbergD. F.DemlerE.JankoB.2002 Josephson effects between multigap and single-gap superconductors, Phys. Rev. B, 66 Iss.21, 214507
2.ArtemenkoS. N.VolkovA. F.ZaitsevA. V.1979 Theory of nonstationary Josephson effect in short superconducting junctions, Zh. Eksp. Teor. Fiz., 76518161833 .
3.AshcroftN. W.2000 The Hydrogen Liquids. J. Phys.: Condens. Matter, 128AA129A137 .
4.AskerzadeI. N.2003 Temperature dependence of the London penetration depth of YNi2B2C borocarbids using two-band Ginzburg-Landau theory. Acta Physica Slovaca, 534321327 .
5.AskerzadeI. N.2003 Ginzburg-Landau theory for two-band s-wave superconductors: application to non-magnetic borocarbides LuNi2B2C, YNi2B2C and magnesium diboride MgB2. Physica C, 397 Iss.3-4, 99111 .
6.AskerzadeI. N.2006 Ginzburg-Landau theory: the case of two-band superconductors. Usp. Fiz. Nauk, 49 Iss.10, 10031016 .
7.Aslamazov L.G. & Larkin A.I.1969 The Josephson effect in point superconducting junctions. Pis’ma Zh. Eksp. Teor. Fiz., 92150154 .
8.BabaevE.2002 Vortices with Fractional Flux in Two-Gap Superconductors and in Extended Faddeev Model. Phys. Rev. Lett., 89 Iss. 89, 067001
9.BabaevE.FaddeevL. D.NiemiA. J.2002 Hidden symmetry and knot solitons in a charged two-condensate Bose system. Phys. Rev. B, 65 Iss.10, 100512 R).
10.BabaevE.SudboA.AshcroftN. W.2004 A superconductor to superfluid phase transition in liquid metallic hydrogen. Nature, 4317009666668 .
11.BrinkmanA.GolubovA. A.RogallaH.DolgovO. V.KortusJ.KongY.JepsenO.AndersenO. K.2002 Multiband model for tunneling in MgB2 junctions. Phys. Rev.B, 65 Iss.18, 180517 R).
13.DahmT.GraserS.SchopohlN.2004 Fermi surface topology and vortex state in MgB2. Physica C, 408-410 , 336337 .
14.DahmT.SchopohlN.2003 Fermi Surface Topology and the Upper Critical Field in Two-Band Superconductors: Application to MgB2. Phys. Rev. Lett., 91 Iss. 1, 017001
15.De GennesP. G.1966Superconductivity of Metals and Alloys, Benjamin, 0-73820-101-4 York.
16.DohH.SigristM.ChoB. K.LeeS. I.1999 Phenomenological Theory of Superconductivity and Magnetism in Ho1-xDyxNi2B2C. Phys. Rev. Lett., 83 Iss.25, 53505353 .
17.GiubileoF.RoditchevD.SacksW.LamyR.ThanhD. X.KleinJ.MiragliaS.FruchartD.MarcusJ.MonodP.2001 Two-Gap State Density in MgB2: A True Bulk Property Or A Proximity Effect? Phys. Rev. Lett., 87 Iss.17, 177008
18.GolubovA. A.KortusJ.DolgovO. V.JepsenO.KongY.AndersenO. K.GibsonB. J.AhnK.KremerR. K.2002 Specific heat of MgB2 in a one- and a two-band model from first-principles calculations. J. Phys.: Condens. Matter, 14613531361 .
19.GolubovA. A.KoshelevA. E.2003 Upper critical field in dirty two-band superconductors: Breakdown of the anisotropic Ginzburg-Landau theory. Phys. Rev. B, 68 Iss.10, 104503
20.GolubovA. A.KupriyanovM.YuIl’ichevE.2004 The current-phase relation in Josephson junctions. Rev. Mod. Phys., 76 Iss.2, 411469 .
21.GolubovA. A.MazinI. I.1995 Sign reversal of the order parameter in s wave superconductors. Physica C, 243 Iss.1-2, 153159 .
22.GurevichA.2003 Enhancement of the upper critical field by nonmagnetic impurities in dirty two-gap superconductors, Phys. Rev. B, 67 Iss.18, 184515
23.GurevichA.2007 Limits of the upper critical field in dirty two-gap superconductors. Physica C, 456 Iss. 1-2, 160169 .
24.GurevichA.VinokurV. M.2003 Interband Phase Modes and Nonequilibrium Soliton Structures in Two-Gap Superconductors. Phys. Rev. Lett., 90 Iss.4, 047004
25.GurevichA.VinokurV. M.2006 Phase textures induced by dc-current pair breaking in weakly coupled multilayer structures and two-gap superconductors, Phys. Rev. Lett., 97 Iss.13, 137003
27.JourdanM.ZakharovA.FoersterM.AdrianH.2004 Evidence for Multiband Superconductivity in the Heavy Fermion Compound UNi2Al3. Phys. Rev. Lett., 93 Iss.9, 097001
28.KamiharaY.WatanabeT.HiranoM.HosonoH.2008 Iron-based layered superconductor La[O(1-x)F(x)]FeAs (x = 0.05-0.12) with T(c) = 26 K. J. Am. Chem. Soc., 130 Iss.11, 32963297 .
29.KortusJ.MazinI. I.BelashchenkoK. D.AntropovV. P.BoyerL. L.2001 Superconductivity of Metallic Boron in MgB2. Phys. Rev. Lett., 86 Iss.20, 4656
30.KoshelevA. E.GolubovA. A.2003 Mixed state of a dirty two-band superconductor: pplication to MgB2, Phys. Rev. Lett., 90 Iss.17, 177002
32.KulikI. О.OmelyanchoukA. N.1975 Microscopic theory of Josephson effect in superconducting microbridges, Pis’ma Zh. Eksp. Teor. Fiz., 214216219 .Kulik I. О. & Omelyanchouk A. N. (1978). Josephson effect in superconducting bridges: microscopic theory, Fiz. Nizk. Temp., V.4, No.3, p.296-311.
34.MazinI. I.AndersenO. K.JepsenO.DolgovO. V.KortusJ.GolubovA. A.Kuz’menkoA. B.van der MarelD.2002 Superconductivity in MgB2: Clean or Dirty? Phys. Rev. Lett., 89 Iss.10, 107002
35.MintsR. G.PapiashviliI.KirtleyJ. R.HilgenkampH.HammerlG.MannhartJ.2002 Observation of Splintered Josephson Vortices at Grain Boundaries in YBa2Cu3O7-δ. Phys. Rev. Lett., 89 Iss.6, 067004
36.MiranovicP.MachidaK.KoganV. G.2003Anisotropy of the Upper Critical Field in Superconductors with Anisotropic Gaps: Anisotropy Parameters of MgB2.J. Phys. Soc. Jpn., 722221224 .
37.Moskalenko V.A.1959 Superconductivity of metals within overlapping energy bands. Fiz. Met. Metallov., 8503513 .
38.NagamatsuJ.NakagawaN.MuranakaT.ZenitaniY.AkimitsuJ.2001Superconductivity at 39 K in magnesium diboride.Nature, 41068246364 .
39.NakaiA.IchiokaM.MachidaK.2002Field Dependence of Electronic Specific Heat in Two-Band Superconductors. J. Phys. Soc. Jpn., 7112326 .
41.Omelyanchouk A.N. & Yerin Y.S.2010Josephson effect in point contacts between two-band superconductors. In: Physical Properties of Nanosystems, Bonca J. & Kruchinin S., 111119 , Springer, 978-9-40070-043-7 Berlin.
42.OtaY.MachidaM.KoyamaT.MatsumotoH.2009Theory of heterotic superconductor-insulator-superconductor Josephson junctions between single- and multiple-gap superconductors,Phys. Rev. Lett., 102 Iss.23, 237003
43.SchmidtH.ZasadzinskiJ. F.GrayK. E.HinksD. G.2001Evidence for Two-Band Superconductivity from Break-Junction Tunneling on MgB2.Phys. Rev. Lett., 88 Iss.12, 127002
44.SeyfarthG.BrisonJ. P.MéassonM.A.FlouquetJ.IzawaK.MatsudaY.SugawaraH.SatoH.2005Multiband Superconductivity in the Heavy Fermion Compound PrOs4Sb12.Phys. Rev. Lett., 95 Iss. 10, 107004
45.ShulgaS. V.DrechslerS.L.FuchsG.MüllerK.H.WinzerK.HeineckeM.KrugK.1998Upper Critical Field Peculiarities of Superconducting YNi2B2C and LuNi2B2C. Phys. Rev. Lett., 80 Iss.8, 17301733 .
46.SuhlH.MatthiasB. T.WalkerL. R.1959 Bardeen-Cooper-Schrieffer Theory of Superconductivity in the Case of Overlapping Bands. Phys. Rev. Lett., 3 Iss.12, 552554 .
47.SzaboP.SamuelyP.KacmarcikJ.KleinT.MarcusJ.FruchartD.MiragliaS.MercenatC.JansenA. G. M.2001Evidence for Two Superconducting Energy Gaps in MgB2 by Point-Contact Spectroscopy. Phys. Rev. Lett., 87 Iss.13, 137005
48.TanakaY.2002Soliton in Two-Band Superconductor.Phys. Rev. Lett., 88 Iss.1, 017002 Tinkham M. (1996). Introduction to Superconductivity, McGraw-Hill, 0-07064-878-6 York.
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