Abstract
We investigate theoretically thermal and electrical conductances for the system consisting of a quantum dot (QD) connected both to a pair of Majorana fermions residing at the edges of a Kitaev wire and two metallic leads. We demonstrate that both quantities reveal pronounced resonances, whose positions can be controlled by tuning of an asymmetry of the couplings of the QD and a pair of MFs. Similar behavior is revealed for the thermopower, WiedemannFranz law and dimensionless thermoelectric figure of merit. The considered geometry can thus be used as a tuner of heat and charge transport assisted by MFs.
Introduction
Majorana fermions (MFs) are particles that are equivalent to their antiparticles. The corresponding concept was first proposed in the domain of highenergy physics, but later on existence of the elementary excitations of this type was predicted for certain condensed matter systems. Particularly, MFs emerge as quasiparticle excitations characterized by zeroenergy modes^{1,2} appearing at the edges of the 1D Kitaev wire^{3,4,5,6,7}. Kitaev model is used to describe the emerging phenomena of pwave and spinless topological superconductivity.
Kitaev topological phase can be experimentally achieved in the geometry consisting of a semiconducting nanowire with spinorbit interaction put in contact with swave superconducting material and placed in external magnetic field^{8,9}. Other condensed matter systems were also proposed as candidates for the observation of MFs. They include ferromagnetic chains placed on top of superconductors with spinorbit interaction^{10,11}, fractional quantum Hall state with filling factor ν = 5/2^{12}, threedimensional topological insulators^{13} and superconducting vortices^{14,15,16}.
MFs residing at the opposite edges of a Kitaev wire are elements of a robust nonlocal qubit which appears to be immune to the environment decoherence. This attracted the interest of the researchers working in the domain of quantum information and transport, as systems with MFs^{17,18,19} can be in principle used as building blocks for the next generation of nanodevices^{20,21}, including current switches^{20} and quantum memory elements^{21}. At the same time, similar systems were proposed as thermoelectric nanodevices^{22,23,24,25}.
In this work, following the proposals of thermoelectric detection of MF states^{22,23,24,25}, we explore theoretically zerobias thermal and electrical transport through one particular geometry consisting of an individual QD coupled both to a pair of MFs and metallic leads as shown in the Fig. 1(a). The MFs reside at the edges of a topological Ushaped Kitaev wire, similar to the case of ref.^{19}. The QD coupling to the MFs is considered to be asymmetric, while coupling to the metallic leads is symmetric, and MFs are supposed to overlap with each other. The results of our calculations clearly show that thermoelectric conductance, thermopower, WiedemannFranz law^{26} and dimensionless thermoelectric figure of merit (ZT) as function of the QD electron energy demonstrate resonant behavior. Moreover, the position of the resonance can be tuned by changing the coupling amplitudes between the QD and the MFs, which allows the system to operate as a tuner of heat and charge assisted by MFs.
Model
For theoretical treatment of the setup depicted in the Fig. 1(a), we use the Hamiltonian proposed by Liu and Baranger^{27}:
where the electrons in the leads α = H, C (for hot and cold reservoirs, respectively) are described by the operators \({c}_{\alpha k}^{\dagger }\) (c_{ αk }) for the creation (annihilation) of an electron in a quantum state labeled by the wave number k and energy ε_{ k }. For the QD \({d}_{1}^{\dagger }\) (d_{1}) creates (annihilates) an electron in the state with the energy ε_{1}. The energies of both electrons in the leads and QD are counted from the chemical potential μ (we consider only the limit of small sourcedrain bias, thus assuming that chemical potential is the same everywhere). V stands for the hybridization between the QD and the leads. The asymmetric coupling between the QD and MFs at the edges of the topological Ushaped Kitaev wire is described by the complex tunneling amplitudes λ_{ A } and λ_{ B }. Introduction of an asymmetry in the couplings can account for the presence of the magnetic flux which can be introduced via Peierls phase shift^{27}. ε_{2} stands for the overlap between the MFs.
Without loss of generality, we can put: \({\lambda }_{A}=\frac{(t+{\rm{\Delta }})}{\sqrt{2}}\) and \({\lambda }_{B}=i\frac{({\rm{\Delta }}t)}{\sqrt{2}}\), respectively for the left \(({\eta }_{A}={\eta }_{A}^{\dagger })\) and right \(({\eta }_{B}={\eta }_{B}^{\dagger })\) MFs, and introduce an auxiliary nonlocal fermion \({d}_{2}=\tfrac{1}{\sqrt{2}}({\eta }_{A}+i{\eta }_{B})\)^{20,21}. The expressions for \({\lambda }_{A}={\lambda }_{A}{e}^{i{\varphi }_{A}}\) and \({\lambda }_{B}={\lambda }_{B}{e}^{i{\varphi }_{B}}\) constitute a convenient gauge for our problem. We put ϕ_{ A } = 0 and \({\varphi }_{B}=(n+\tfrac{1}{2})\pi \) with integer n = 0, 1, 2, … corresponding to the total flux through the ring of Fig. 1. This parameter is experimentally tunable by changing the external magnetic field. This fact gives certain advantages to our proposal with respect to the previous works with asymmetric couplings between a single QD and a pair of MFs at the ends of a topological Kitaev wire^{28,29,30,31}. According to ref.^{32} the parameter ε_{2} describing the overlap between the MFs depends on magnetic field in an oscillatory manner, the amplitudes \({\lambda }_{A}=\frac{t+{\rm{\Delta }}}{\sqrt{2}}\) and \({\lambda }_{B}=\frac{{\rm{\Delta }}t}{\sqrt{2}}\) demonstrate the same behavior (see Sec. IIIA of ref.^{30}) and thus external magnetic field affects not only the relative phase between λ_{ A } and λ_{ B } but their absolute values as well. To fulfill the condition λ_{ B } < λ_{ A } one should place the QD closer the MF η_{ A } than to the MF η_{ B }.
We map the original Hamiltonian into one where the electronic states d_{1} and d_{2} are connected via normal tunneling t and bounded as delocalized Cooper pair, with binding energy Δ:
This expression represents a shortened version of the microscopic model for the Kitaev wire corresponding to the Kitaev dimer (see Fig. 1(b)). As it was shown in the refs^{33} and^{34} this model allows clear distinguishing between topologically trivial and Majoranainduced zerobias peak in the conductance.
In what follows, we use the LandauerBüttiker formula for the zerobias thermoelectric quantities \({ {\mathcal L} }_{n}\)^{22,23}:
where h is Planck’s constant, \({\rm{\Gamma }}=2\pi {V}^{2}\,{\sum }_{k}\,\delta (\varepsilon {\varepsilon }_{k})\) is Anderson broadening^{35} and f_{ F } stands for FermiDirac distribution. The quantity
is electronic transmittance through the QD, with \({\tilde{{\mathscr{G}}}}_{{d}_{1}{d}_{1}}\) being retarded Green’s function for the QD in the energy domain ε, obtained from the Fourier transform \({\tilde{{\mathscr{G}}}}_{{\mathscr{A}} {\mathcal B} }=\int \,d\tau {\tilde{{\mathscr{G}}}}_{{\mathscr{A}} {\mathcal B} }{e}^{\frac{i}{\hslash }(\varepsilon +i{0}^{+})\tau }\), where
corresponds to the Green’s function in time domain τ, expressed in terms of the Heaviside function θ(τ) and thermal density matrix ρ for Eq. (1).
Experimentally measurable thermoelectric coefficients can be expressed via \({ {\mathcal L} }_{0}\), \({ {\mathcal L} }_{1}\) and \({ {\mathcal L} }_{2}\) as:
and
for the electrical and thermal conductances and thermopower, respectively (T denotes the temperature of the system).
We also investigate the violation of WiedemannFranz law, given by
in units of Lorenz number L_{0} = (π^{2}/3) (k_{ B }/e)^{2} and corresponding behavior of the dimensionless figure of merit^{22,23}
For Eq. (4), we use equationofmotion (EOM) method^{36} summarized as follows:
with \({\mathscr{A}}= {\mathcal B} ={d}_{1}\).
As our Hamiltonian given by Eqs (1) and (2) is quadratic, the set of the EOM for the single particle Green’s functions can be closed without any truncation procedure^{37}. We find the following four coupled linear algebraic equations:
where Σ = −iΓ is the selfenergy of the coupling with the metallic leads
and
with
and
This gives the Green’s function of the QD:
where the part of selfenergy
describes the hybridization between MFs and QD.
Importantly, for the low temperatures regime, the substitution of Eq. (19) into Eq. (3) and its decomposition into Sommerfeld series^{23,26} allows to get analytical expressions for thermoelectric coefficients:
where
with
Comparison of the Eqs (21) and (22) allows us to conclude that the peak values of the electric conductance are reached when S = 0 for which \(d\,{\mathscr{T}}/d\varepsilon =0\) which happens when
As we will see below, fulfillment of this condition corresponds to the presence of an electronhole symmetry in the system. Note that as ε_{2} enters in the denominator of the Eq. (25), even slight differences between t and Δ will be enough to change drastically the position of the resonance if hybridization between the MFs is small.
Results and Discussion
In our further calculations, we scale the energy in units of the Anderson broadening \({\rm{\Gamma }}=2\pi {V}^{2}\,{\sum }_{k}\,\delta (\varepsilon {\varepsilon }_{k})\)^{35} and take the temperature of the system k_{ B }T = 10^{−4}Γ. The Anderson broadening Γ defines the coupling between the QD and the metallic leads, which is assumed to be symmetrical for a sake of simplicity.
We start our analysis from the case when only a single MF (η_{ A }) is coupled to the QD. In terms of the amplitudes t,Δ this corresponds to t = Δ. To be specific, we fix t = Δ = 4Γ. Looking at Eq. (2), we see that the terms \({d}_{1}{d}_{2}^{\dagger }+{\rm{H}}.{\rm{c}}.\) and \({d}_{2}^{\dagger }{d}_{1}^{\dagger }+{\rm{H}}.{\rm{c}}.\) enter into Hamiltonian with equal weights, and thus we are in the superconducting (SC)metallic boundary phase.
Figure 2(a) shows the electrical conductance \(G={e}^{2}\,{ {\mathcal L} }_{0}\) scaled in units of the conductance quantum G_{0} = e^{2}/h as a function of the QD energy level ε_{1}, for several coupling amplitudes ε_{2} between the MFs. Note that, if MFs are completely isolated from each other (ε_{2} = 0), the conductance reveals a plateau with G = G_{0}/2 whatever the value of ε_{1} (black line), and similar trend is observed in the thermal conductance shown in the Fig. 2(b). The effect is due to the leaking of the Majorana fermion state into the QD^{38}. The MF zeromode becomes pinned at the Fermi level of the metallic leads, but within the QD electronicstructure. With increase of the coupling between the wire and the QD, the MF state of the Kitaev wire leaks into the QD. As a result, a peak at the Fermi energy emerges in the QD density of states (DOS), while in the DOS corresponding to the edge of the wire the corresponding peak becomes gradually suppressed. Consequently, the QD effectively becomes the new edge of the Kitaev wire. This scenario was reported experimentally in the ref.^{9}.
To get resonant response of the thermoelectric conductances one should consider the case ε_{2} ≠ 0, corresponding to the splitting of the MF zerobias peak. The resonant behavior of G and K can be understood as arising from the presence of an auxiliary fermion d_{2}, in the Hamiltonian [Eq. (2)], whose energy ε_{2} is now detuned from the Fermi level (see inset of Fig. 2(b)). In this case, the regular fermion state instead of the corresponding halffermion provided by MF η_{ A } gives the main contribution to the charge and heat current. In this scenario, filtering of the electricity and heat emerges: the maximal transmission occurs at ε_{1} = 0. Our Fig. 2(a,b) recover the findings of Fig. 5(a) in ref.^{23}. Our work, however, have an important novel dimension: we demonstrate that even small deviations of the system from the SCmetallic boundary phase which can be achieved by the control of the asymmetry of the couplings allows realization of the efficient tuners of electricity and heat. This effect is shown in the Fig. 3(a,b). As one can see, even small detuning of the coefficient t from the value t = Δ leads to substantial blueshift (for the case t > Δ) or redshift (for the case t < Δ) of the conductance resonances. Such sensitivity is a direct consequence of the Eq. (25) defining the position of the resonances.
To shed more light on the effect of the tuning of charge and heat transport in the system, we make a plot of the quantity \({\mathscr{T}}={\rm{\Gamma }}\text{Im}({\tilde{{\mathscr{G}}}}_{{d}_{1}{d}_{1}})\) appearing in the Eqs (3) and (4), as function of ε_{1} and ε, see Fig. 4(a–d). Figure 4(a) corresponds to the case t = Δ, ε_{2} = 0. One can recognize a “cat eye”shaped central structure, corresponding to the vertical line at ε = 0. Everywhere along this line \({\mathscr{T}}={\rm{constant}}\), which according to the Eq. (21) means that changes in ε_{1} do not affect the conductance. This corresponds well to the conductance plateau in the Fig. 2. If ε_{2} is finite, the “cat eye” structure transforms into a doublefork profile as it is shown in the Fig. 4(b). Note that in this case, movement along the vertical line corresponding to ε = 0 lead to the change of the function \({\mathscr{T}}\), which according to the Eq. (21) leads to the modulation of the conductance. The maximal value is achieved at the point ε_{1} = 0, which corresponds well to the resonant character of the curves shown in the Fig. 2. The introduction of the finite value of ε_{2} and the asymmetry of the coupling between the QD and MFs (t ≠ Δ) leads to the shifts of the doublefork structure either upwards by ε_{1} scale for t > Δ (panel (c), blueshift of the resonant curves in the Fig. 3) or downwards by ε_{1} scale for t < Δ (panel (d), redshift of the resonant curves in the Fig. 3). It should be noted that similar results to the transmittance were reported both theoretically (ref.^{30}) and experimentally (ref.^{31}) for the geometry of a linear Kitaev wire with a QD attached to one of its ends placed between source and drain metallic leads. Differently from the case considered in our work, the authors account for the spin degree of freedom and particularly for ref.^{31}, they evaluate the dependence of the conductance on the energy level of the QD and magnetic field, while we further analyze ε and asymmetry of couplings dependencies relevant for the understanding of the tuner regime. Despite the distinct geometry and spinless regime, our results and those reported in refs^{30,31} are in good correspondence with each other, thus validating the mechanism pointed out in refs^{30,32} of fieldassisted overlapping between MFs and tunnelcouplings with the QD.
The possibility to tune electric and thermal conductances opens a way for tuning the thermopower (S), WiedemannFranz law (WF) and dimensionless figure of merit (ZT) as it is shown in the Fig. 5(a–c). In the Fig. 5(a) the dependence of the thermopower on ε_{1} is demonstrated. If t > Δ, at ε_{1} = 0, S > 0 and the setup behaves as a tuner of holes. On the contrary, for t < Δ, at ε_{1} = 0, S < 0 and the setup behaves as a tuner of electrons. Figure 5(b,c) illustrate the violation of WF law and the behavior of the dimensionless thermoelectric ZT, respectively. Note that ZT does not reach pronounced amplitudes, i.e., ZT < 1^{26}, even for finite values of G and K as dependence on S^{2} prevails if we take into account Eq. (21) into Eq. (10).
Conclusions
In summary, we considered theoretically thermoelectric conductances for the device consisting of an individual QD coupled to both pair of MFs and metallic leads. The charge and heat conductances of this system as functions of an electron energy in the QD reveal resonant character. The position of the resonance can be tuned by changing the degree of asymmetry between the QD and the MFs, which allows us to propose the scheme of the tuner of heat and charge. Thermopower, WiedemannFranz law and the figure of merit are found to be sensitive to the asymmetry of the coupling as well. Our findings will pave way for the development of thermoelectric nanodevices based on MFs.
References
Alicea, J. Rep. Prog. Phys. 75, 076501 (2012).
Elliott, S. R. & Franz, M. Rev. Mod. Phys. 87, 137 (2015).
Kitaev, A. Y. Phys. Usp. 44, 131 (2001).
Zyuzin, A. A., Rainis, D., Klinovaja, J. & Loss, D. Phys. Rev. Lett. 111, 056802 (2013).
Rainis, D., Klinovaja, J., Trifunovic, L. & Loss, D. Phys. Rev. B 87, 024515 (2013).
Zazunov, A., Sodano, P. & Egger, R. New J. Phys 15, 035033 (2013).
Roy, D., Bolech, C. J. & Shah, N. Phys. Rev. B 86, 094503 (2012).
Mourik, V. et al. Science 336, 1003 (2012).
Deng, M. T. et al. Science 354, 6319 (2016).
Perge, S. N. et al. Science 346, 602 (2014).
Pawlak, R. et al. Nature Partner Journals Quantum Information 2, 16035 (2016).
Moore, G. & Read, N. Nucl. Phys. B 360, 362 (1991).
Fu, L., Kane, C. L. & Mele, E. J. Phys. Rev. Lett. 98, 106803 (2007).
Fu, L. & Kane, C. L. Phys. Rev. Lett. 100, 096407 (2008).
Sau, J. D., Lutchyn, R. M., Tewari, S. & Das Sarma, S. Phys. Rev. Lett. 104, 040502 (2010).
Kawakami, T. & Hu, X. Phys. Rev. Lett. 115, 177001 (2015).
Flensberg, K. Phys. Rev. Lett. 106, 090503 (2011).
Leijnse, M. & Flensberg, K. Phys. Rev. Lett. 107, 210502 (2011).
Chiu, C.K., Sau, J. D. & Das Sarma, S. arXiv:1709.04475 (2017).
Dessotti, F. A. et al. Phys. Rev. B 94, 125426 (2016).
Ricco, L. S. et al. Phys. Rev. B 93, 165116 (2016).
Andrade, J. P. R., Ovando, O. Á., Orellana, P. A. & Ulloa, S. E. Phys. Rev. B 94, 155436 (2016).
López, R., Lee, M., Serra, L. & Lim, J. S. Phys. Rev. B 89, 205418 (2014).
Leijnse, M. New J. Phys. 16, 015029 (2014).
Valentini, S., Fazio, R., Giovannetti, V. & Taddei, F. Phys. Rev. B 91, 045430 (2015).
Dubi, Y. & Di Ventra, M. Rev. Mod. Phys. 83, 131 (2011).
Liu, D. E. & Baranger, H. U. Phys. Rev. B 84, 201308(R) (2011).
Clarke, D. J. Phys. Rev. B 96, 201109(R) (2017).
Schuray, A., Weithofer, L. & Recher, P. Phys. Rev. B 96, 085417 (2017).
Prada, E., Aguado, R. & Jose, P. S. Phys. Rev. B 96, 085418 (2017).
Deng, M. T. et al. arXiv:1712.03536v1.
Danon, J., Hansen, E. B. & Flensberg, K. Phys. Rev. B 96, 125420 (2017).
Stanescu, T. D. & Tewari, S. Phys. Rev. B 89, 220507(R) (2014).
Roy, D., Bondyopadhaya, N. & Tewari, S. Phys. Rev. B 88, 020502(R) (2013).
Anderson, P. W. Phys. Rev. 124, 41 (1961).
Haug, H. & Jauho, A. P. Quantum Kinetics in Transport and Optics of Semiconductors, Springer Series in SolidState Sciences. (Springer, New York, 1996; 123.
Ricco, L. S., Marques, Y., Dessotti, F. A., de Souza, M. & Seridonio, A. C. Phys. E 78, 25 (2016).
Vernek, E., Penteado, P. H., Seridonio, A. C. & Egues, J. C. Phys. Rev. B 89, 165314 (2014).
Acknowledgements
This work was supported by the Brazilian funding agencies CNPq Grant No. 307573/20150, CAPES and São Paulo Research Foundation (FAPESP) Grant No. 2015/235398. I.A.S. acknowledges support from Horizon2020 RISE project CoExAN and the project No. 3.8884.2017/8.9 of the Ministry of Education and Science of the Russian Federation.
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A.C.S., M.S.F. and I.A.S. formulated the problem and wrote the manuscript. L.S.R. and A.C.S. derived the expressions and M.S.F. performed their numerical computing. F.A.D. and L.S.R. plotted the figures. All coauthors taken part in the discussions and reviewed the manuscript as well.
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Ricco, L.S., Dessotti, F.A., Shelykh, I.A. et al. Tuning of heat and charge transport by Majorana fermions. Sci Rep 8, 2790 (2018). https://doi.org/10.1038/s41598018211809
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DOI: https://doi.org/10.1038/s41598018211809
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