Abstract
The Anderson-Holstein model with Caldeira-Leggett coupling with environment is considered to describe the damping effect in a single molecular transistor (SMT) which comprises a molecular quantum dot (with electron-phonon interaction) mounted on a substrate (environment) and coupled to metallic electrodes. The electron-phonon interaction is first eliminated using the Lang-Firsov transformation and the spectral density function, charge current and differential conductance are then calculated using the non-equilibrium Keldysh Green function technique. The effects of damping rate and electron-electron and electron-phonon interactions on the transport properties of SMT are studied at zero temperature.
Similar content being viewed by others
Introduction
The subject of transport in single molecular transistors has attracted considerable attention in recent years primarily for their potential applications in nano-technology. A single molecular transistor (SMT) is an electronic device in which a central molecule or quantum dot (QD) connected by metal leads (source and drain), plays an important role in transport. The central molecule or the QD is characterized by its discrete energy levels with coulomb interaction. These SMTs can be used as single-electron transistors1 by controlling the charge transport using Coulomb blocked effect. The charging effects like Coulomb blockade and Kondo effect due to electron-electron (el-el) interaction in such systems is well understood2,3,4,5,6,7,8,9. Of late, the phononic effects on molecular devices have been studied by many research groups. Each electron-transfer from the lead to the molecule creates a distortion in the molecule. Quanta of this distortion, called phonons, interact with a local electron of the molecule through the electron-phonon (el-ph) interaction giving rise to what is known as the polaronic effect. Particularly in organic conjugated molecules and quantum dots, quasiparticles that take part in transport mechanism are polarons10,11,12. The transport properties of such systems are actually affected by both el-el and el-ph interactions. Much effort, therefore, has gone into understanding the quantum transport in SMT theoretically incorporating both el-ph and el-el interactions in different regimes. Many experimental and theoretical groups13,14,15,16 have demonstrated that el-ph interaction is the cause for the existence of the vibrational side bands. In Ref.16 Braig et al. have studied the effect of dissipative surroundings around the molecule using Rate equation approach in weak coupling limit. They have suggested that the effect of dissipative surroundings around the molecule is to provide an additional broadening of the vibrational side bands. Other theoretical methods applied in this field include the Kinetic equation method17,18, the rate equation approach19, non-equilibrium Green’s function approaches20,21,22 and numerical renormalization group method23,24. In the present work we study the damping effect in SMT device using the Keldysh mechanism. Our study is valid for the entire range of the coupling constant. We restrict ourselves only to zero temperature.
The paper is organized as follows: In the section immediately following, we introduce the model and the relevant Hamiltonian for the problem. To be more specific, we consider the Anderson-Holstein (AH) model with the Caldeira-Leggett term. In the next section i.e., in “Polaron Transformation” section, we apply the celebrated Lang-Firsov canonical transformation to eliminate the el-ph interaction in the first order. In the “Tunneling Current” section we determine the tunneling current, spectral function and the differential conductance using the Keldysh formalism. In the “Results and Discussion” section we discuss the numerical results and finally present our concluding remarks in the “Conclusion” section.
The Model
Figure 1 shows the schematic description of an SMT system. A typical SMT device consists of a single-level molecule or a QD coupled to two metal leads. The molecule is assumed to have a single vibrational mode interacting with its charge by el-ph interaction. The system is embedded on an insulating substrate (yellow colour part in Fig. 1) that can be approximated as a bath of independent harmonic oscillators in the spirit of the Caldeira-Leggett model. The substrate can cause a damping effect that can be described by a linear coupling term between the local phonon field of the molecule and a set of independent harmonic oscillators of the substrate bath. For the sake of simplicity, we neglect the effects of spin on the properties of the SMT. The model Hamiltonian for the system is given by
The first term Hl describes the Hamiltonian for the source (l = S) and the drain and is given by
where is the number operator for conduction electrons in the continuum states of the source and drain with wave vector k, spin σ, energy εkσ and density of states gS(D)(ε), being the electron creation (annihilation) operator in the state (k,). The second term Hm describes the Hamiltonian of the molecule and is given by
where Hm0 is the Hamiltonian for the electronic part of the molecule and reads as
with ndσ as the number operator corresponding to the electrons on the molecule with εd as the onsite energy (that can be varied experimentally by tuning the gate voltage (VG) and U is the local coulomb correlation strength. Hvib describes the vibrational degree of freedom of the molecule of mass m0 and frequency ω0 and can be written as,
and Hvib−e represents the el-ph interaction on the molecule and is given by
with λ as the el-ph coupling constant. The leads-molecule hybridization term with hybridization strength Vk is given by,
Finally, the damping effect is incorporated in (1) by introducing the term
where x0 and {xj} are the molecular and the bath oscillator degrees of freedom and βj is the coupling strength between the molecular oscillator and the jth bath oscillator. The oscillator bath is fully characterized by a spectral function J(ω) given by
Eliminating the linear oscillator-bath interaction, we can write
where
where Δω2 is the shift in the square of the molecular oscillator frequency caused by the linear oscillator-bath coupling. For very large N we can replace the summation over j by an integration over ωj. Δω2 can be written as
where J(ω) is the spectral function for which we choose the Lorentz-Drude form:
where is the cutoff frequency which is much larger than the other frequencies in the system and is the damping rate. The shift in the molecular frequency turns out be, The total Hamiltonian finally reduces to
where, b†(b) is the creation (annihilation) operator for a molecular phonon of frequency . It may be noted that we have neglected the decoupled bath-oscillator Hamiltonian because that merely contributes a constant to the energy.
Polaron Transformation
To investigate the effects of the polaronic interactions in the system, a Lang-Firsov transformation25 with the generator S = λ(b† − b)∑σndσ, is applied to the Hamiltonian. The transformed Hamiltonian reads
with
where the phonon is mediated hybridization strength, is the renormalized molecular energy level due to the polaronic effect and εp is the polaron binding energy.
Tunneling Current
In this section, we shall employ the method of Chen et al.26. The current expression through the interacting region coupled to two metallic leads can be expressed as27,28,
Similarly, the occupation number of the molecule are given by,
where fS,D(ε) are the Fermi distribution functions of the source and drain whose chemical potentials are related to the bias voltage (VB) and mid-voltage (Vm) as (μS − μD) = eVB and (μS + μD)/2 = eVm. For symmetric coupling,
where,
where is the coupling strength between the molecule and the source (drain), ρS(D) being the density of states in the source (drain) channel. Here we have considered constant density of states in the source and drain. The possible excitation energy spectrum is described by the quantity called Spectral (SP) function, which is defined as
where,
where the superscript ‘>’ (‘<’) refers to greater (lesser), ‘r’ (‘a’) refers to retarded (advanced) and represents the true electronic ground state of the system. Where Gr(a)(ε) and G>(<)(ε) are the energy-dependent retarded (advanced) and lesser (greater) electron Green’s functions of the molecule respectively. The retarded and advanced Green functions can be easily calculated using the equation of motion approach. One obtains
where the retarded (advanced) self-energy Sr(a)(ε) due to hybridization interaction is given by
where the real part of the self-energy can be absorbed into the molecular energy level. We assume that and are constants within the flat band limit. The phonon operator X in the Hamiltonian Eq. (18) can be absorbed into a renormalized electron annihilation and creation operators in the molecule region. So the Hamiltonian Eq. (18) is the usual resonant tunneling Hamiltonian with the dressed molecule electron operators. The interacting lesser Green’s function for the electrons on the molecule can be written as,
where the factors which arise from the phonon averages are given by29
with By using the relation, where, .
with
where In(z) is the nth order Bessel function of complex argument. The lesser and greater Green functions can be expanded as
From Eq. (26) the SP function can be written as,
Using Keldysh formalism we can write lesser and greater Green’s functions as
with
After calculating the lesser and greater Green functions we can obtain the SP function of the molecule electron using Eq. (37).
Results and Discussion
In the present calculation, all energies are measured in units of phonon energy ω0 which is set equal to 1. Furthermore, the coupling of the molecule with the source and that with the drain are considered symmetric. In our calculation we have taken and eVm = 0.1. Our main aim is to study the damping effect of the substrate on the properties of the SMT system. In Fig. 2, we show the variation of the SP function A(ε) of a SMT with ε for different values of the damping rate γ and a given value of the el-ph coupling constant λ (λ = 0.6). The inset shows the A(ε) vs. ε behavior for the case: λ = γ = 0, which is a simple Lorentzian with a single resonant peak at εd = 0. The el-ph interaction induces polaronic effects that renormalize the SMT parameters and shift the εd = 0 peak of the SP function towards red and also make them sharper. Most importantly, the SP function also develops side peaks at in the presence of the el-ph interaction. These, so called, phonon side bands in the SP function at zero temperature represent the phononic excitation energy levels created by the electrons tunneling on to the molecule by absorbing or emitting phonons. Due to the damping effect of the substrate the phonon frequency gets renormalized to . As the damping rate increases, the heights of the phonon side bands decrease and broaden. This suggests that as the damping rate increases, the occupation probability of the phonon side bands decreases.
In Fig. 3 we present the results for the normalized tunneling current J(eVB, eVm) of the SMT system as a function of bias voltage for different values of γ in the presence of the el-ph interaction. The normalized tunneling current for the case: λ = γ = 0 is shown in the inset for comparison. As the damping rate increases the current also increases. To see the effect of el-ph interaction on current, we plot, in Fig. 4, the current as a function of λ for different values of γ at constant bias voltage VB. As λ increases, the current decreases smoothly but rapidly and becomes zero at a critical value of λ, say λc. This is easy to understand physically, though mathematically, Eq. (25) explicitly shows that the current decreases exponentially with λ. At the same time as λ increases, the separation between the molecule energy level and the chemical potential of source increases. As γ increases, λc is also found to increase.
In Fig. 5, we present the results for the differential conductance G(eVB, eVm)(=dJ/dVB) as a function of the bias voltage. In Fig. 5(a) we show the behaviour of G in the absence of the el-ph interaction and the damping effect. The symmetry in the conductivity peaks is clearly visible. In Fig. 5(b) we show the behavior of G in the presence of el-ph interaction (λ = 0.6) for different values of γ. The el-ph interaction and damping have visible independent effects on G. The effect of the el-ph interaction is two-fold. First, it sharpens the conductivity peaks and secondly and more importantly it gives rise to new satellite peaks that originate because of phonon-assisted tunneling transport. To show the effect of el-ph interaction on the differential conductance explicitly, we plot in Fig. 6, G/G0 as a function of λ for different values of γ. For a given γ, the differential conductance has a peak at a certain value of λ and as γ increases the peak reduces in height and also shifts towards right. Both shifting and reduction in height of the conductance peaks are the expected behavior.
In Fig. 7(a,b) we plot J and G respectively as a function of the el-el interaction strength U. As U increases, both J and G decrease, while they increase with increasing γ. These variations can be explained in the following way. Due to the Coulomb blockade effect the onsite coulomb correlation opposes the double occupancy on the molecule as a result of which the current decreases with increasing U, while as γ increases, the effective phonon frequency decreases leading to an increase in the current and the conductance.
Finally, we make a three-dimensional plot for J as a function of both γ and λ in Fig. 8(a) and for G as a function of γ and λ in Fig. 8(b).
Conclusion
In this work we have considered a SMT system in which a molecule or a quantum dot is placed on a substrate coupled to two metal leads acting as a source and a drain. The system is modeled by the AH Hamiltonian with a linear Caldeira-Leggett term to include the linear coupling between the substrate and the molecule which describes the damping effect. We have calculated the spectral function, tunneling current and differential conductance of the SMT system using the Keldysh Green function method. We have also analyzed the effect of el-ph interaction and the damping effect due to the substrate. We have shown that the el-ph interaction induces polaronic effects that renormalize the SMT parameters and shift the peak of the spectral function towards red and also make them sharper. The spectral function also develops side bands whose heights decrease and the widths broaden with increasing damping rate. As λ increases, the tunneling current is found to decrease smoothly but rapidly to zero at a critical value of λ. The el-ph interaction also sharpens the conductivity peaks and gives rise to new satellite peaks that originate because of phonon-assisted tunneling transport. It is also shown that the local el-el interaction causes a reduction in both the tunneling current and the differential conductance. Due to the damping effect of the substrate, the effective phonon frequency of the molecule oscillator decreases as a result of which the tunneling current increases. In the presence of el-ph and el-el interactions and damping, the differential conductance exhibits an interesting behavior. The spin-orbit interaction may also have an interesting effect on the tunneling current and the differential conductance. This issue is presently under investigation and the results will be published in due course. Which will be the subject matter of a future investigated.
Additional Information
How to cite this article: Raju, C. N. and Chatterjee, A. Quantum dissipative effects on non-equilibrium transport through a single-molecular transistor: The Anderson-Holstein-Caldeira-Leggett model. Sci. Rep. 6, 18511; doi: 10.1038/srep18511 (2016).
References
Stokbro, K. First-principles modeling of molecular single-electron transistors. J. Phys. Chem. C 114, 20461–20465 (2010).
Park, J. et al. Coulomb blockade and the kondo effect in single-atom transistors. Nature 417, 722–725 (2002).
Kubatkin, S. et al. Single-electron transistor of a single organic molecule with access to several redox states. Nature 425, 698–701 (2003).
Liang, W., Shores, M. P., Bockrath, M., Long, J. R. & Park, H. Kondo resonance in a single-molecule transistor. Nature 417, 725–729 (2002).
González, G., Leuenberger, M. N. & Mucciolo, E. R. Kondo effect in single-molecule magnet transistors. Phys. Rev. B 78, 054445–12 (2008).
Klein, D. L., Roth, R., Lim, A. K. L., Alivisatos, A. P. & McEuen, P. L. A single-electron transistor made from a cadmium selenide nanocrystal. Nature 389, 699–701 (1997).
Goldhaber-Gordon, D. et al. Kondo effect in a single-electron transistor. Nature 391, 156–159 (1998).
Yu, L. H. & Natelson, D. The Kondo effect in C60 single-molecule transistors. Nano Lett. 4, 79–83 (2003).
Ho, W. Single-molecule chemistry. J. Chem. Phys. 117, 11033–11061 (2002).
Heeger, A. J., Kivelson, S., Schrieffer, J. R. & Su, W. P. Solitons in conducting polymers. Rev. Mod. Phys. 60, 781–850 (1988).
Koch, T., Loos, J., Alvermann, A., Bishop, A. R. & Fehske, H. Transport through a vibrating quantum dot: Polaronic effects. J. Phys.: Conf. Ser. 220, 012014–9 (2010).
Loos, J., Koch, T., Alvermann, A., Bishop, A. R. & Fehske, H. Phonon affected transport through molecular quantum dots. J. Phys.: Condens. Matter. 21, 395601–18 (2009).
Paaske, J. & Flensberg, K. Vibrational sidebands and the kondo effect in molecular transistors. Phys. Rev. Lett, 94, 176801–4 (2005).
Park, H. et al. Nanomechanical oscillations in a single-C60 transistor. Nature 407, 57–60 (2000).
Lüffe, M. C., Koch, J. & von Oppen, F. Theory of vibrational absorption sidebands in the Coulomb-blocked regime of single-molecular transistors. Phys. Rev. B 77, 125306–7 (2008).
Braig, S. & Flensberg, K. Vibrational sidebands and dissipative tunneling in molecular transistors. Phys. Rev. B 68, 205324–10 (2003).
Boese, D. & Schoeller, H. Influence of nanomechanical properties on single-electron tunneling: a vibrating single-electron transistor Europhys. Lett. 54, 668 (2001).
McCarthy, K. D., Prokof’ev, N. & Tuominen, M. T. Incoherent dynamics of vibrating single-molecular transistor. Phys. Rev. B 67, 245415–6 (2003).
Mitra, A., Aleiner, I. & Millis, A. J. Phonon effects in molecular transistors: quantal and classical treatment. Phys. Rev. B 69, 245302–21 (2004).
Keldysh, L. V. Diagram technique for nonequilibrium processes. Sov. Phys. JETP 20, 1018–1026 (1965).
Datta, S. in Electronic Transport in Mesoscopic Systems, (Cambridge University Press, 1997); Datta, S. in Quantum Transport: Atom to Transistor, (Cambridge University Press, 2005).
Haug, H. & Jauho, A.-P. in Quantum Kinetics in Transport and Optics of Semiconductors, (Springer, 1996).
Cornaglia, P. S. & Grempel, D. R. Magnetoconductance through a vibrating molecule in the kondo regime. Phys. Rev. B 71, 245326–6 (2005).
Costi, T. A. Magnetotransport through a strongly interacting quantum dot. Phys. Rev. B 64, 241310–4 (2001).
Lang, I. G. & Firsov, Yu. A. Title of the paper. Zh. Eksp. Teor. Fiz. 43, 1843 (1962) [Sov. Phys. JETP16, 1301 (1963)]; Takada, Y. & Chatterjee, A. Possibility of a metallic phase in the charge-density-wave-spin-density-wave crossover region in the one-dimensional hubbard-holstein model at half filling. Phys. Rev. B67, 081102–4 (R) (2003).
Chen, Z. Z., Lü, R. & Zhu, B. F. Effects of electron-phonon interaction on nonequilibrium transport through a single-molecule transistor. Phys. Rev. B 71, 165324–9 (2005).
Jauho, A.-P., Wingreen, N. S. & Meir, Y. Time-dependent transport in interacting and noninteracting resonant-tunneling systems. Phys. Rev. B 50, 5528–5544 (1994).
Meir, Y. & Wingreen, N. S. Landauer formula for the current through an interacting electron region. Phys. Rev. Lett. 68, 2512–2515 (1992).
Mahan, G. D. in Many-Particle Physics, (Plenum Press, 1990).
Acknowledgements
One of the authors (C.N.R.) gratefully acknowledges the financial support from UGC, India through its BSR Fellowship scheme F.5-123/2007(BSR).
Author information
Authors and Affiliations
Contributions
A.C. gave the idea. C.N.R. had carried out analytical calculation, numerical computation and wrote the manuscript. A.C. reviewed the manuscript.
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Raju, C., Chatterjee, A. Quantum dissipative effects on non-equilibrium transport through a single-molecular transistor: The Anderson-Holstein-Caldeira-Leggett model. Sci Rep 6, 18511 (2016). https://doi.org/10.1038/srep18511
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep18511
- Springer Nature Limited