Your search keyword '"Baranger, Harold U."' showing total 130 results

1. Conductance of a Dissipative Quantum Dot: Nonequilibrium Crossover Near a Non-Fermi-Liquid Quantum Critical Point

Author

Zhang, Gu, Novais, E., and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We find the nonlinear conductance of a dissipative resonant level in the nonequilibrium steady state near its quantum critical point. The system consists of a spin-polarized quantum dot connected to two resistive leads that provide ohmic dissipation. We focus on the crossover from the strong-coupling, non-Fermi-liquid regime to the weak-coupling, Fermi-liquid ground state, a crossover driven by the instability of the quantum critical point to hybridization asymmetry or detuning of the level in the dot. We show that the crossover properties are given by tunneling through an effective single barrier described by the boundary sine-Gordon model. The nonlinear conductance is then obtained from thermodynamic Bethe ansatz results in the literature, which were developed to treat tunneling in a Luttinger liquid. The current-voltage characteristics are thus found for any value of the resistance of the leads. For the special case of lead resistance equal to the quantum resistance, we find mappings onto, first, the two-channel Kondo model and, second, an effectively noninteracting model from which the nonlinear conductance is found analytically. A key feature of the general crossover function is that the nonequilibrium crossover driven by applied bias is different from the crossover driven by temperature -- we find that the nonequilibrium crossover is substantially sharper. Finally, we compare to experimental results for both the bias and temperature crossovers: the agreement is excellent., Comment: 18 pages. Accepted version: small corrections and improvements from v1

Published

2021

2. Quantum critical region of a two-dimensional spin-half XXZ model

Author

Lee, Ji-Woo and Baranger, Harold U.

Published

2023

3. Driven-dissipative phase transition in a Kerr oscillator: From semiclassical $\mathcal{PT}$ symmetry to quantum fluctuations

Author

Zhang, Xin H. H. and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study a minimal model that has a driven-dissipative quantum phase transition, namely a Kerr non-linear oscillator subject to driving and dissipation. Using mean-field theory, exact diagonalization, and the Keldysh formalism, we analyze the critical phenomena in this system, showing which aspects can be captured by each approach and how the approaches complement each other. Then critical scaling and finite-size scaling are calculated analytically using the quantum Langevin equation. The physics contained in this simple model is surprisingly rich: it includes a continuous phase transition, $Z_{2}$ symmetry breaking, $\mathcal{PT}$ symmetry, state squeezing, and critical fluctuations. Due to its simplicity and solvability, this model can serve as a paradigm for exploration of open quantum many-body physics., Comment: published version, 12 pages

Published

2020

4. Stabilization of a Majorana Zero Mode through Quantum Frustration

Author

Zhang, Gu and Baranger, Harold U.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We analyze a system in which a topological Majorana zero mode (tMZM) combines with a Majorana produced by quantum frustration (fMZM) to produce a novel ground state. The system that we study combines two parts, a grounded topological superconducting wire that hosts two tMZMs at its ends, and an on-resonant quantum dot connected to two dissipative leads. The quantum dot with dissipative leads creates an effective two-channel Kondo (2CK) state in which quantum frustration yields an isolated fMZM at the dot. We find that coupling the dot to one end of the topological wire stabilizes the tMZM at the other end. Three routes are used to obtain these results: (i) calculation of the conductance through an auxiliary detector quantum dot, (ii) renormalization group (RG) arguments and the g-theorem, and (iii) a fully non-equilibrium calculation of the I(V ) curve and shot noise S(V ) through the detector dot. In addition to providing a route to achieving an unpaired Majorana zero mode, this scheme provides a clear signature of the presence of the 2CK frustration-induced Majorana., Comment: 9 pages, 2 figures

Published

2019

5. Interference of chiral Andreev edge states

Author

Zhao, Lingfei, Arnault, Ethan G., Bondarev, Alexey, Seredinski, Andrew, Larson, Trevyn, Draelos, Anne W., Li, Hengming, Watanabe, Kenji, Taniguchi, Takashi, Amet, François, Baranger, Harold U., and Finkelstein, Gleb

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity, Quantum Physics

Abstract

The search for topological excitations such as Majorana fermions has spurred interest in the boundaries between distinct quantum states. Here, we explore an interface between two prototypical phases of electrons with conceptually different ground states: the integer quantum Hall insulator and the s-wave superconductor. We find clear signatures of hybridized electron and hole states similar to chiral Majorana fermions, to which we refer as chiral Andreev edge states (CAES). They propagate along the interface in the direction determined by magnetic field and their interference can turn an incoming electron into an outgoing electron or a hole, depending on the phase accumulated by the CAES along their path. Our results demonstrate that these excitations can propagate and interfere over a significant length, opening future possibilities for their coherent manipulation., Comment: Main: 3 figures; Supplementary: 12 figures

Published

2019

6. Exciting a Bound State in the Continuum through Multi-Photon Scattering plus Delayed Quantum Feedback

Author

Calajò, Giuseppe, Fang, Yao-Lung L., Baranger, Harold U., and Ciccarello, Francesco

Subjects

Quantum Physics, Physics - Optics

Abstract

Excitation of a bound state in the continuum (BIC) through scattering is problematic since it is by definition uncoupled. Here, we consider a type of dressed BIC and show that it can be excited in a nonlinear system through multi-photon scattering and delayed quantum feedback. The system is a semi-infinite waveguide with linear dispersion coupled to a qubit, in which a single-photon, dressed BIC is known to exist. We show that this BIC can be populated via multi-photon scattering in the non-Markovian regime, where the photon delay time (due to the qubit-mirror distance) is comparable with the qubit's decay. A similar process excites the BIC existing in an infinite waveguide coupled to two distant qubits, thus yielding stationary entanglement between the qubits. This shows, in particular, that single-photon trapping via multi-photon scattering can occur without band-edge effects or cavities, the essential resource being instead the {\it delayed} quantum feedback provided by a single mirror or the emitters themselves., Comment: 5 pages, 5 figures, supplementary material

Published

2018

7. Heralded Bell State of Dissipative Qubits Using Classical Light in a Waveguide

Author

Zhang, Xin H. H. and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Maximally entangled two-qubit states (Bell states) are of central importance in quantum technologies. We show that heralded generation of a maximally entangled state of two intrinsically open qubits can be realized in a one-dimensional (1d) system through strong coherent driving and continuous monitoring. In contrast to the natural idea that dissipation leads to decoherence and so destroys quantum effects, continuous measurement and strong interference in our 1d system generate a pure state with perfect quantum correlation between the two open qubits. Though the steady state is a trivial product state which has zero coherence or concurrence, we show that, with carefully tuned parameters, a Bell state can be generated in the system's quantum jump trajectories, heralded by a reflected photon. Surprisingly, this maximally entangled state survives the strong coherent state input---a classical state that overwhelms the system. This simple method to generate maximally entangled states using classical coherent light and photon detection may, since our qubits are in a 1d continuum, find application as a building block of quantum networks., Comment: 6+4 pages; Published version. Typos corrected. More contents added (single detector case, suppression of effective qubit-qubit interaction, brief discussion of detuned parameters)

Published

2018

8. Particle Production in Ultra-Strong Coupling Waveguide QED

Author

Gheeraert, Nicolas, Zhang, Xin H. H., Sépulcre, Théo, Bera, Soumya, Roch, Nicolas, Baranger, Harold U., and Florens, Serge

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Understanding large-scale interacting quantum matter requires dealing with the huge number of quanta that are produced by scattering even a few particles against a complex quantum object. Prominent examples are found from high energy cosmic ray showers to the optical or electrical driving of degenerate Fermi gases. We tackle this challenge in the context of many-body quantum optics, as motivated by the recent developments of circuit quantum electrodynamics at ultrastrong coupling. The issue of particle production is addressed quantitatively with a simple yet powerful concept rooted in the quantum superposition principle. This key idea is illustrated by the study of multi-photon emission from a single two-level artificial atom coupled to a high impedance waveguide. We find surprisingly that the off-resonant inelastic emission lineshape is dominated by broadband particle production, due to the large phase space associated with contributions that do not conserve the number of excitations. Such frequency conversion processes produce striking signatures in time correlation measurements, which can be tested experimentally in quantum waveguides. These ideas open new directions for the simulation of a variety of physical systems, from polaron dynamics in solids to complex superconducting quantum architectures., Comment: 19 pages, 12 figures. New algorithm presented in v3

Published

2018

9. Non-Markovian Dynamics of a Qubit Due to Single-Photon Scattering in a Waveguide

Author

Fang, Yao-Lung L., Ciccarello, Francesco, and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

We investigate the open dynamics of a qubit due to scattering of a single photon in an infinite or semi-infinite waveguide. Through an exact solution of the time-dependent multi-photon scattering problem, we find the qubit's dynamical map. Tools of open quantum systems theory allow us then to discuss the general features of this map, find the corresponding non-Linbladian master equation, and assess in a rigorous way its non-Markovian nature. The qubit dynamics has distinctive features that, in particular, do not occur in emission processes. Two fundamental sources of non-Markovianity are present: the finite width of the photon wavepacket and the time delay for propagation between the qubit and the end of the semi-infinite waveguide., Comment: Integrated the supplementary material into main text and added the discussion on P-/CP-divisibility. To appear in New Journal of Physics

Published

2017

10. Multiple Emitters in a Waveguide: Non-Reciprocity and Correlated Photons at Perfect Elastic Transmission

Author

Fang, Yao-Lung L. and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate interference and correlation effects when several detuned emitters are placed along a one-dimensional photonic waveguide. Such a setup allows multiple interactions between the photons and the strongly coupled emitters, and underlies proposed devices for quantum information processing. We show, first, that a pair of detuned two-level systems (2LS) separated by a half wavelength mimic a driven {\Lambda}-type three-level system (3LS) in both the single- and two- photon sectors. There is an interference-induced transparency peak at which the fluorescence is quenched, leaving the transmitted photons completely uncorrelated. Slightly away from this separation, we find that the inelastic scattering (fluorescence) is large, leading to nonlinear effects such as non-reciprocity (rectification). We connect this non-reciprocity to inelastic scattering caused by driving a dark pole and so derive a condition for maximum rectification. Finally, by placing a true 3LS midway between the two 2LS, we show that elastic scattering produces only transmission, but inelastic scattering nevertheless occurs (the fluorescence is not quenched) causing substantial photon correlations., Comment: Published version with minor changes in title, text, and Fig.9. A Mathematica notebook is uploaded as the supplementary material

Published

2016

11. Rescuing a Quantum Phase Transition with Quantum Noise

Author

Zhang, Gu, Novais, Eduardo, and Baranger, Harold U.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We show that placing a quantum system in contact with an environment can enhance non-Fermi-liquid correlations, rather than destroy quantum effects as is typical. The system consists of two quantum dots in series with two leads; the highly resistive leads couple charge flow through the dots to the electromagnetic environment, the source of quantum noise. While the charge transport inhibits a quantum phase transition, the quantum noise reduces charge transport and restores the transition. We find a non-Fermi-liquid intermediate fixed point for all strengths of the noise. For strong noise, it is similar to the intermediate fixed point of the two-impurity Kondo model., Comment: Published version: shortened, several points clarified, references added. 6 pages + 6 supplementary

Published

2016

12. Dynamics of a Qubit in a High-Impedance Transmission Line from a Bath Perspective

Author

Bera, Soumya, Baranger, Harold U., and Florens, Serge

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We investigate quantum dynamics of a generic model of light-matter interaction in the context of high impedance waveguides, focusing on the behavior of the emitted photonic states, in the framework of the spin-boson model Quantum quenches as well as scattering of an incident coherent pulse are studied using two complementary methods. First, we develop an approximate ansatz for the electromagnetic waves based on a single multimode coherent state wavefunction; formally, this approach combines ideas from adiabatic renormalization, the Born-Markov approximation, and input-output theory. Second, we present numerically exact results for scattering of a weak intensity pulse by using NRG calculations. NRG provides a benchmark for any linear response property throughout the ultra-strong coupling regime. We find that in a sudden quantum quench, the coherent state approach produces physical artifacts, such as improper relaxation to the steady state. These previously unnoticed problems are related to the simplified form of the ansatz that generates spurious correlations within the bath. In the scattering problem, NRG is used to find the transmission and reflection of a single photon, as well as the inelastic scattering of that single photon. Simple analytical formulas are established and tested against the NRG data that predict quantitatively the transport coefficients for up to moderate environmental impedance. These formulas resolve pending issues regarding the presence of inelastic losses in the spin-boson model near absorption resonances, and could be used for comparison to experiments in Josephson waveguide QED. Finally, the scattering results using the coherent state wavefunction approach are compared favorably to the NRG results for very weak incident intensity. We end our study by presenting results at higher power where the response of the system is nonlinear., Comment: 11 pages, 11 figures. Minor changes in V2

Published

2016

13. Photon Correlations Generated by Inelastic Scattering in a One-Dimensional Waveguide Coupled to Three-Level Systems

Author

Fang, Yao-Lung L. and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

We study photon correlations generated by scattering from three-level systems (3LS) in one dimension. The two systems studied are a 3LS in a semi-infinite waveguide (3LS plus a mirror) and two 3LS in an infinite waveguide (double 3LS). Our two-photon scattering approach naturally connects photon correlation effects with inelastically scattered photons; it corresponds to input-output theory in the weak-probe limit. At the resonance where electromagnetically induced transparency (EIT) occurs, we find that no photons are scattered inelastically and hence there are no induced correlations. Slightly away from EIT, the total inelastically scattered flux is large, being substantially enhanced due to the additional interference paths. This enhancement carries over to the two-photon correlation function, which exhibits non-classical behavior such as strong bunching with a very long time-scale. The long time scale originates from the slow-light effect associated with EIT., Comment: Published version, in memory of M. B\"uttiker

Published

2015

14. Detecting Photon-Photon Interactions in a Superconducting Circuit

Author

Jin, Li-Jing, Houzet, Manuel, Meyer, Julia S., Baranger, Harold U., and Hekking, Frank W. J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A local interaction between photons can be engineered by coupling a nonlinear system to a transmission line. The required high impedance transmission line can be conveniently formed from a chain of Josephson junctions. The nonlinearity is generated by side-coupling this chain to a Cooper pair box. We propose to probe the resulting photon-photon interactions via their effect on the current-voltage characteristic of a voltage-biased Josephson junction connected to the transmission line. Considering the Cooper pair box to be in the weakly anharmonic regime, we find that the dc current through the probe junction yields features around the voltages $2eV=n\hbar\omega_s$, where $\omega_s$ is the plasma frequency of the superconducting circuit. The features at $n\ge 2$ are a direct signature of the photon-photon interaction in the system., Comment: 10 pages, 7 figures

Published

2015

15. Waveguide QED: Power Spectra and Correlations of Two Photons Scattered Off Multiple Distant Qubits and a Mirror

Author

Fang, Yao-Lung L. and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study two-level systems (2LS) coupled at different points to a one-dimensional waveguide in which one end is open and the other is either open (infinite waveguide) or closed by a mirror (semi-infinite). Upon injection of two photons (corresponding to weak coherent driving), the resonance fluorescence and photon correlations are shaped by the effective qubit transition frequencies and decay rates, which are substantially modified by interference effects. In contrast to the well-known result in an infinite waveguide, photons reflected by a single 2LS coupled to a semi-infinite waveguide are initially bunched, a result that can be simply explained by stimulated emission. As the number of 2LS increases (up to 10 are considered here), rapid oscillations build up in the correlations that persist for a very long time. For instance, when the incoming photons are slightly detuned, the transmitted photons in the infinite waveguide are highly antibunched. On the other hand, upon resonant driving, incoherently reflected photons are mostly distributed within the photonic band gap and several sharp side peaks. These features can be explained by considering the poles of the single particle Green function in the Markovian regime combined with the time delay. Our calculation is not restricted to the Markovian regime, and we obtain several fully non-Markovian results. We show that a single 2LS in a semi-infinite waveguide can not be decoupled by placing it at the node of the photonic field, in contrast to recent results in the Markovian regime. Our results illustrate the complexities that ensue when several qubits are strongly coupled to a bus (the waveguide) as might happen in quantum information processing., Comment: Published version with minor revision. Originally titled as "Waveguide QED: Two Photons, Many Qubits, and a Mirror"

Published

2015

16. A generalized multi-polaron expansion for the spin-boson model: Environmental entanglement and the biased two-state system

Author

Bera, Soumya, Nazir, Ahsan, Chin, Alex W., Baranger, Harold U., and Florens, Serge

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We develop a systematic variational coherent state expansion for the many-body ground state of the spin-boson model, in which a quantum two-level system is coupled to a continuum of harmonic oscillators. Energetic constraints at the heart of this technique are rationalized in terms of polarons (displacements of the bath states in agreement with classical expectations) and antipolarons (counter-displacements due to quantum tunneling effects). We present a comprehensive study of the ground state two-level system population and coherence as a function of tunneling amplitude, dissipation strength, and bias (akin to asymmetry of the double well potential defining the two-state system). The entanglement among the different environmental modes is investigated by looking at spectroscopic signatures of the bipartite entanglement entropy between a given environmental mode and all the other modes. We observe a drastic change in behavior of this entropy for increasing dissipation, indicative of the entangled nature of the environmental states. In addition, the entropy spreads over a large energy range at strong dissipation, a testimony to the wide entanglement window characterizing the underlying Kondo state. Finally, comparisons to accurate numerical renormalization group calculations and to the exact Bethe Ansatz solution of the model demonstrate the rapid convergence of our variationally-optimized multi-polaron expansion, suggesting that it should also be a useful tool for dissipative models of greater complexity, as relevant for numerous systems of interest in quantum physics and chemistry., Comment: 17 pages, 14 figures

Published

2014

17. Transport Signatures of Majorana Quantum Criticality Realized by Dissipative Resonant Tunneling

Author

Zheng, Huaixiu, Florens, Serge, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We consider theoretically the transport properties of a spinless resonant electronic level coupled to strongly dissipative leads, in the regime of circuit impedance near the resistance quantum. Using the Luttinger liquid analogy, one obtains an effective Hamiltonian expressed in terms of interacting Majorana fermions, in which all environmental degrees of freedom (leads and electromagnetic modes) are encapsulated in a single fermionic bath. General transport equations for this system are then derived in terms of the Majorana T-matrix. Perturbative treatment of the Majorana interaction term yields the appearance of a marginal, linear dependence of the conductance on temperature when the system is tuned to its quantum critical point, in agreement with recent experimental observations. We investigate in detail the different crossovers involved in the problem, and analyze the role of the interaction terms in the transport scaling functions. In particular, we show that single barrier scaling applies when the system is slightly tuned away from its Majorana critical point, strengthening the general picture of dynamical Coulomb blockade., Comment: 10 pages, 4 figures

Published

2014

18. Tunable Quantum Phase Transitions in a Resonant Level Coupled to Two Dissipative Baths

Author

Liu, Dong E., Zheng, Huaixiu, Finkelstein, Gleb, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We study tunneling through a resonant level connected to two dissipative bosonic baths: one is the resistive environment of the source and drain leads, while the second comes from coupling to potential fluctuations on a resistive gate. We show that several quantum phase transitions (QPT) occur in such a model, transitions which emulate those found in interacting systems such as Luttinger liquids or Kondo systems. We first use bosonization to map this dissipative resonant level model to a resonant level in a Luttinger liquid, one with, curiously, two interaction parameters. Drawing on methods for analyzing Luttinger liquids at both weak and strong coupling, we obtain the phase diagram. For strong dissipation, a Berezinsky-Kosterlitz-Thouless QPT separates strong-coupling and weak-coupling (charge localized) phases. In the source-drain symmetric case, all relevant backscattering processes disappear at strong coupling, leading to perfect transmission at zero temperature. In fact, a QPT occurs as a function of the coupling asymmetry or energy of the resonant level: the two phases are (i) the system is cut into two disconnected pieces (zero transmission), or (ii) the system is a single connected piece with perfect transmission, except for a disconnected fractional degree of freedom. The latter arises from the competition between the two fermionic leads (source and drain), as in the two-channel Kondo effect., Comment: 11 pages. Published version: clarifications and added references

Published

2013

19. One-Dimensional Waveguide Coupled to Multiple Qubits: Photon-Photon Correlations

Author

Fang, Yao-Lung L., Zheng, Huaixiu, and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

For a one-dimensional (1D) waveguide coupled to two or three qubits, we show that the photon-photon correlations have a wide variety of behavior, with structure that depends sensitively on the frequency and on the qubit-qubit separation $L$. We study the correlations by calculating the second-order correlation function $g_2(t)$ in which the interference among the photons multiply scattered from the qubits causes rich structure. In one case, for example, transmitted and reflected photons are both bunched initially, but then become strongly anti-bunched for a long time interval. We first calculate the correlation function $g_2(t)$ including non-Markovian effects and then show that a much simpler Markovian treatment, which can be solved analytically, is accurate for small qubit separation. As a result, the non-classical properties of microwaves in a 1D waveguide coupled to many superconducting qubits with experimentally accessible separation $L$ could be readily explored with our approach., Comment: 11 pages, 6 figures. Journal version. Added one plot and the associated discussions and expanded the method in Appendix A

Published

2013

20. Stabilizing Spin Coherence Through Environmental Entanglement in Strongly Dissipative Quantum Systems

Author

Bera, Soumya, Florens, Serge, Baranger, Harold U., Roch, Nicolas, Nazir, Ahsan, and Chin, Alex W.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

The key feature of a quantum spin coupled to a harmonic bath---a model dissipative quantum system---is competition between oscillator potential energy and spin tunneling rate. We show that these opposing tendencies cause environmental entanglement through superpositions of adiabatic and antiadiabatic oscillator states, which then stabilizes the spin coherence against strong dissipation. This insight motivates a fast-converging variational coherent-state expansion for the many-body ground state of the spin-boson model, which we substantiate via numerical quantum tomography., Comment: 5 pages, 3 figures, supplementary file attached. This article supersedes arXiv:1301.7430

Published

2013

21. Zigzag Phase Transition in Quantum Wires

Author

Mehta, Abhijit C., Umrigar, C. J., Meyer, Julia S., and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study the quantum phase transition of interacting electrons in quantum wires from a one-dimensional (1D) linear configuration to a quasi-1D zigzag arrangement using quantum Monte Carlo methods. As the density increases from its lowest values, first, the electrons form a linear Wigner crystal; then, the symmetry about the axis of the wire is broken as the electrons order in a quasi-1D zigzag phase; and, finally, the electrons form a disordered liquid-like phase. We show that the linear to zigzag phase transition is not destroyed by the strong quantum fluctuations present in narrow wires; it has characteristics which are qualitatively different from the classical transition., Comment: 5 pages, 5 figures. Published version: several clarifications, such as comment on finite size effects

Published

2013

22. Waveguide-QED-Based Photonic Quantum Computation

Author

Zheng, Huaixiu, Gauthier, Daniel J., and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We propose a new scheme for quantum computation using flying qubits--propagating photons in a one-dimensional waveguide--interacting with matter qubits. Photon-photon interactions are mediated by the coupling to a three- or four-level system, based on which photon-photon \pi-phase gates (Controlled-NOT) can be implemented for universal quantum computation. We show that high gate fidelity is possible given recent dramatic experimental progress in superconducting circuits and photonic-crystal waveguides. The proposed system can be an important building block for future on-chip quantum networks., Comment: Published version, extensively revised main text and supplemental material compared to v1

Published

2012

23. Floquet Majorana Fermions for Topological Qubits

Author

Liu, Dong E., Levchenko, Alex, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We introduce and develop an approach to realizing a topological phase transition and non-Abelian statistics with dynamically induced Floquet Majorana Fermions (FMFs). When the periodic driving potential does not break fermion parity conservation, FMFs can encode quantum information. Quasi-energy analysis shows that a stable FMF zero mode and two other satellite modes exist in a wide parameter space with large quasi-energy gaps, which prevents transitions to other Floquet states under adiabatic driving. We also show that in the asymptotic limit FMFs preserve non-Abelian statistics and, thus, behave like their equilibrium counterparts., Comment: 4 pages, 2 figures; supplementary information: 5 pages, 4 figures

Published

2012

24. Fermi-liquid regime of the mesoscopic Kondo problem

Author

Ullmo, Denis, Liu, Dong E., Burdin, Sébastien, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We consider the low temperature regime of the mesoscopic Kondo problem, and in particular the relevance of a Fermi-liquid description of this regime. Using two complementary approaches -- a mean field slave fermion approximation on the one hand and a Fermi-liquid description "\`a la Nozi\`eres" supplemented by an argument of separation of scale on the other hand -- we show that they both lead to (essentially) the same quasi-particle spectra, providing in this way a strong indication that they both give the correct physics of this regime.

Published

2012

25. Decoy-State Quantum Key Distribution with Nonclassical Light Generated in a One-dimensional Waveguide

Author

Zheng, Huaixiu, Gauthier, Daniel J., and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate a decoy-state quantum key distribution (QKD) scheme with a sub-Poissonian single-photon source, which is generated on demand by scattering a coherent state off a two-level system in a one-dimensional waveguide. We show that, compared to coherent state decoy-state QKD, there is a two-fold increase of the key generation rate. Furthermore, the performance is shown to be robust against both parameter variations and loss effects of the system., Comment: 3 pages, 3 figures

Published

2012

26. Quantum Phase Transition in a Resonant Level Coupled to Interacting Leads

Author

Mebrahtu, Henok T., Borzenets, Ivan V., Liu, Dong E., Zheng, Huaixiu, Bomze, Yuriy V., Smirnov, Alex I., Baranger, Harold U., and Finkelstein, Gleb

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

An interacting one-dimensional electron system, the Luttinger liquid, is distinct from the "conventional" Fermi liquids formed by interacting electrons in two and three dimensions. Some of its most spectacular properties are revealed in the process of electron tunneling: as a function of the applied bias or temperature the tunneling current demonstrates a non-trivial power-law suppression. Here, we create a system which emulates tunneling in a Luttinger liquid, by controlling the interaction of the tunneling electron with its environment. We further replace a single tunneling barrier with a double-barrier resonant level structure and investigate resonant tunneling between Luttinger liquids. For the first time, we observe perfect transparency of the resonant level embedded in the interacting environment, while the width of the resonance tends to zero. We argue that this unique behavior results from many-body physics of interacting electrons and signals the presence of a quantum phase transition (QPT). In our samples many parameters, including the interaction strength, can be precisely controlled; thus, we have created an attractive model system for studying quantum critical phenomena in general. Our work therefore has broadly reaching implications for understanding QPTs in more complex systems, such as cold atoms and strongly correlated bulk materials., Comment: 11 pages total (main text + supplementary)

Published

2012

27. Persistent Quantum Beats and Long-Distance Entanglement from Waveguide-Mediated Interactions

Author

Zheng, Huaixiu and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study photon-photon correlations and entanglement generation in a one-dimensional waveguide coupled to two qubits with an arbitrary spatial separation. We develop a novel Green function method to study vacuum-mediated qubit-qubit interactions, including both spontaneous and coherent couplings. As a result of these interactions, quantum beats appear in the second-order correlation function. We go beyond the Markovian regime and observe that such quantum beats persist much longer than the qubit life time. Using these non-Markovian processes, a high degree of long-distance entanglement can be generated, making waveguide-QED systems promising candidates for scalable quantum networking., Comment: 5 pages main text + 5 pages supplementary material; substantial rewriting of the discussion about effective qubit lifetime, loss effects, and experimental relevance

Published

2012

28. Strongly correlated photons generated by coupling a three- or four-level system to a waveguide

Author

Zheng, Huaixiu, Gauthier, Daniel J., and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics

Abstract

We study the generation of strongly correlated photons by coupling an atom to photonic quantum fields in a one-dimensional waveguide. Specifically, we consider a three-level or four-level system for the atom. Photon-photon bound states emerge as a manifestation of the strong photon-photon correlation mediated by the atom. Effective repulsive or attractive interaction between photons can be produced, causing either suppressed multiphoton transmission (photon blockade) or enhanced multiphoton transmission (photon-induced tunneling). As a result, nonclassical light sources can be generated on demand by sending coherent states into the proposed system. We calculate the second-order correlation function of the transmitted field and observe bunching and antibunching caused by the bound states. Furthermore, we demonstrate that the proposed system can produce photon pairs with a high degree of spectral entanglement, which have a large capacity for carrying information and are important for large-alphabet quantum communication., Comment: 13+ pages, 7 figures

Published

2012

29. Mesoscopic Anderson Box: Connecting Weak to Strong Coupling

Author

Liu, Dong E., Burdin, Sébastien, Baranger, Harold U., and Ullmo, Denis

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

Both the weakly coupled and strong coupling Anderson impurity problems are characterized by a Fermi-liquid theory with weakly interacting quasiparticles. In an Anderson box, mesoscopic fluctuations of the effective single particle properties will be large. We study how the statistical fluctuations at low temperature in these two problems are connected, using random matrix theory and the slave boson mean field approximation (SBMFA). First, for a resonant level model such as results from the SBMFA, we find the joint distribution of energy levels with and without the resonant level present. Second, if only energy levels within the Kondo resonance are considered, the distributions of perturbed levels collapse to universal forms for both orthogonal and unitary ensembles for all values of the coupling. These universal curves are described well by a simple Wigner-surmise type toy model. Third, we study the fluctuations of the mean field parameters in the SBMFA, finding that they are small. Finally, the change in the intensity of an eigenfunction at an arbitrary point is studied, such as is relevant in conductance measurements: we find that the introduction of the strongly-coupled impurity considerably changes the wave function but that a substantial correlation remains., Comment: 17 pages, 7 figures

Published

2012

30. Detecting a Majorana-Fermion Zero Mode Using a Quantum Dot

Author

Liu, Dong E. and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

We propose an experimental setup for detecting a Majorana zero mode consisting of a spinless quantum dot coupled to the end of a p-wave superconducting nanowire. The Majorana bound state at the end of the wire strongly influences the conductance through the quantum dot: Driving the wire through the topological phase transition causes a sharp jump in the conductance by a factor of 1/2. In the topological phase, the zero temperature peak value of the dot conductance (i.e. when the dot is on resonance and symmetrically coupled to the leads) is e^2/2h. In contrast, if the wire is in its trivial phase, the conductance peak value is e^2/h, or if a regular fermionic zero mode occurs on the end of the wire, the conductance is 0. The system can also be used to tune Flensberg's qubit system [PRL 106, 090503 (2011)] to the required degeneracy point., Comment: 5 pages, 4 figures

Published

2011

31. Cavity-free Photon Blockade Induced by Many-body Bound States

Author

Zheng, Huaixiu, Gauthier, Daniel J., and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics, Quantum Physics

Abstract

The manipulation of individual, mobile quanta is a key goal of quantum communication; to achieve this, nonlinear phenomena in open systems can play a critical role. We show theoretically that a variety of strong quantum nonlinear phenomena occur in a completely open one-dimensional waveguide coupled to an N-type four-level system (4LS). We focus on photon blockade and the creation of single photon states in the absence of a cavity. Many-body bound states appear due to the strong photon-photon correlation mediated by the 4LS. These bound states cause photon blockade which can generate a sub-Poissonian single photon source., Comment: 4 pages main text + 4 pages supplementary material

Published

2011

32. From Weak- to Strong-Coupling Mesoscopic Fermi Liquids

Author

Liu, Dong E., Burdin, Sébastien, Baranger, Harold U., and Ullmo, Denis

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study mesoscopic fluctuations in a system in which there is a continuous connection between two distinct Fermi liquids, asking whether the mesoscopic variation in the two limits is correlated. The particular system studied is an Anderson impurity coupled to a finite mesoscopic reservoir described by random matrix theory, a structure which can be realized using quantum dots. We use the slave boson mean field approach to connect the levels of the uncoupled system to those of the strong coupling Nozi\`eres Fermi liquid. We find strong but not complete correlation between the mesoscopic properties in the two limits and several universal features., Comment: 6 pages, 3 figures

Published

2011

33. Waveguide QED: Many-Body Bound State Effects on Coherent and Fock State Scattering from a Two-Level System

Author

Zheng, Huaixiu, Gauthier, Daniel J., and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics

Abstract

Strong coupling between a two-level system (TLS) and bosonic modes produces dramatic quantum optics effects. We consider a one-dimensional continuum of bosons coupled to a single localized TLS, a system which may be realized in a variety of plasmonic, photonic, or electronic contexts. We present the exact many-body scattering eigenstate obtained by imposing open boundary conditions. Multi-photon bound states appear in the scattering of two or more photons due to the coupling between the photons and the TLS. Such bound states are shown to have a large effect on scattering of both Fock and coherent state wavepackets, especially in the intermediate coupling strength regime. We compare the statistics of the transmitted light with a coherent state having the same mean photon number: as the interaction strength increases, the one-photon probability is suppressed rapidly, and the two- and three-photon probabilities are greatly enhanced due to the many-body bound states. This results in non-Poissonian light., Comment: 10 pages

Published

2010

34. Quantum Phase Transition and Dynamically Enhanced Symmetry in Quadruple Quantum Dot System

Author

Liu, Dong E., Chandrasekharan, Shailesh, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We propose a system of four quantum dots designed to study the competition between three types of interactions: Heisenberg, Kondo and Ising. We find a rich phase diagram containing two sharp features: a quantum phase transition (QPT) between charge-ordered and charge-liquid phases, and a dramatic resonance in the charge liquid visible in the conductance. The QPT is of the Kosterlitz-Thouless type with a discontinuous jump in the conductance at the transition. We connect the resonance phenomenon with the degeneracy of three levels in the isolated quadruple dot and argue that this leads to a Kondo-like dynamical enhancement of symmetry from U(1) x Z_2 to U(1) x U(1)., Comment: 4 pages main text + 4 pages supplementary material

Published

2010

35. Conductance of Quantum Impurity Models from Quantum Monte Carlo

Author

Liu, Dong E., Chandrasekharan, Shailesh, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

The conductance of two Anderson impurity models, one with two-fold and another with four-fold degeneracy, representing two types of quantum dots, is calculated using a world-line quantum Monte Carlo (QMC) method. Extrapolation of the imaginary time QMC data to zero frequency yields the linear conductance, which is then compared to numerical renormalization group results in order to assess its accuracy. We find that the method gives excellent results at low temperature (T

Published

2010

36. Bound on quantum computation time: Quantum error correction in a critical environment

Author

Novais, E., Mucciolo, Eduardo R., and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We obtain an upper bound on the time available for quantum computation for a given quantum computer and decohering environment with quantum error correction implemented. First, we derive an explicit quantum evolution operator for the logical qubits and show that it has the same form as that for the physical qubits but with a reduced coupling strength to the environment. Using this evolution operator, we find the trace distance between the real and ideal states of the logical qubits in two cases. For a super-Ohmic bath, the trace distance saturates, while for Ohmic or sub-Ohmic baths, there is a finite time before the trace distance exceeds a value set by the user., Comment: 4 pages (revised title, following PRA request)

Published

2010

37. Time-Dependent Transport Through Molecular Junctions

Author

Ke, San-Huang, Liu, Rui, Yang, Weitao, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

We investigate transport properties of molecular junctions under two types of bias--a short time pulse or an AC bias--by combining a solution for the Green functions in the time domain with electronic structure information coming from ab initio density functional calculations. We find that the short time response depends on lead structure, bias voltage, and barrier heights both at the molecule-lead contacts and within molecules. Under a low frequency AC bias, the electron flow either tracks or leads the bias signal (capacitive or resistive response) depending on whether the junction is perfectly conducting or not. For high frequency, the current lags the bias signal due to the kinetic inductance. The transition frequency is an intrinsic property of the junctions., Comment: 5 pages, 9 figures

Published

2010

38. Quantum Interference Controlled Molecular Electronics

Author

Ke, San-Huang, Yang, Weitao, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum interference in coherent transport through single molecular rings may provide a mechanism to control current in molecular electronics. We investigate its applicability by using a single-particle Green function method combined with ab initio electronic structure calculations. We find that the quantum interference effect (QIE) depends strongly on the interaction between molecular pi states and contact sigma states. It is absent in small molecular rings with Au leads, such as benzene, due to strong pi-sigma hybridization, while it is preserved in large rings, such as [18]annulene, which then could be used to realize QIE transistors., Comment: 5 pages, published version, small revisions

Published

2008

39. Hamiltonian Formulation of Quantum Error Correction and Correlated Noise: The Effects Of Syndrome Extraction in the Long Time Limit

Author

Novais, E., Mucciolo, Eduardo R., and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Computer Science - Information Theory

Abstract

We analyze the long time behavior of a quantum computer running a quantum error correction (QEC) code in the presence of a correlated environment. Starting from a Hamiltonian formulation of realistic noise models, and assuming that QEC is indeed possible, we find formal expressions for the probability of a faulty path and the residual decoherence encoded in the reduced density matrix. Systems with non-zero gate times (``long gates'') are included in our analysis by using an upper bound on the noise. In order to introduce the local error probability for a qubit, we assume that propagation of signals through the environment is slower than the QEC period (hypercube assumption). This allows an explicit calculation in the case of a generalized spin-boson model and a quantum frustration model. The key result is a dimensional criterion: If the correlations decay sufficiently fast, the system evolves toward a stochastic error model for which the threshold theorem of fault-tolerant quantum computation has been proven. On the other hand, if the correlations decay slowly, the traditional proof of this threshold theorem does not hold. This dimensional criterion bears many similarities to criteria that occur in the theory of quantum phase transitions., Comment: 19 pages, 5 figures. Includes response to arXiv:quant-ph/0702050. New title and an additional example

Published

2007

40. Improving Intrinsic Decoherence in Multi-Quantum-Dot Charge Qubits

Author

Hentschel, Martina, Valente, Diego C. B., Mucciolo, Eduardo R., and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We discuss decoherence in charge qubits formed by multiple lateral quantum dots in the framework of the spin-boson model and the Born-Markov approximation. We consider the intrinsic decoherence caused by the coupling to bulk phonon modes. Two distinct quantum dot configurations are studied: (i) Three quantum dots in a ring geometry with one excess electron in total and (ii) arrays of quantum dots where the computational basis states form multipole charge configurations. For the three-dot qubit, we demonstrate the possibility of performing one- and two-qubit operations by solely tuning gate voltages. Compared to the proposal by DiVincenzo {\it et al.} involving a linear three-dot spin qubit, the three-dot charge qubit allows for less overhead on two-qubit operations. For small interdot tunnel amplitudes, the three-dot qubits have $Q$ factors much higher than those obtained for double dot systems. The high-multipole dot configurations also show a substantial decrease in decoherence at low operation frequencies when compared to the double-dot qubit., Comment: 11 pages, 6 figures, submitted to Phys. Rev. B

Published

2007

41. Electron transport through single conjugated organic molecules: Basis set effects in ab initio calculations

Author

Ke, San-Huang, Baranger, Harold U., and Yang, Weitao

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

We investigate electron transport through single conjugated molecules - including benzenedithiol, oligo-phenylene-ethynylenes of different lengths, and a ferrocene-containing molecule sandwiched between two gold electrodes with different contact structures - by using a single-particle Green function method combined with density functional theory calculation. We focus on the effect of the basis set in the ab initio calculation. It is shown that the position of the Fermi energy in the transport gap is sensitive to the molecule-lead charge transfer which is affected by the size of basis set. This can dramatically change, by orders of magnitude, the conductance for long molecules, though the effect is only minor for short ones. A resonance around the Fermi energy tends to pin the position of the Fermi energy and suppress this effect. The result is discussed in comparison with experimental data., Comment: 6 pages, 7 figures

Published

2007

42. Incipient Wigner Localization in Circular Quantum Dots

Author

Ghosal, Amit, Guclu, A. D., Umrigar, C. J., Ullmo, Denis, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We study the development of electron-electron correlations in circular quantum dots as the density is decreased. We consider a wide range of both electron number, N<=20, and electron gas parameter, r_s<18, using the diffusion quantum Monte Carlo technique. Features associated with correlation appear to develop very differently in quantum dots than in bulk. The main reason is that translational symmetry is necessarily broken in a dot, leading to density modulation and inhomogeneity. Electron-electron interactions act to enhance this modulation ultimately leading to localization. This process appears to be completely smooth and occurs over a wide range of density. Thus there is a broad regime of ``incipient'' Wigner crystallization in these quantum dots. Our specific conclusions are: (i) The density develops sharp rings while the pair density shows both radial and angular inhomogeneity. (ii) The spin of the ground state is consistent with Hund's (first) rule throughout our entire range of r_s for all 4

Published

2007

43. Disorder-Induced Superfluidity in Hardcore Bosons in Two Dimensions

Author

Lee, Ji-Woo, Chandrasekharan, Shailesh, and Baranger, Harold U.

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Superconductivity

Abstract

We study the effect of disorder on hardcore bosons in two dimensions at the SU(2) symmetric ``Heisenberg point''. We obtain our results with quantum Monte Carlo simulations using the directed loop algorithm. In the absence of disorder, the system has no long-range order at finite temperature due to the enhanced symmetry. However, the introduction of a disordered potential, uniformly distributed from -D to D, induces a finite-temperature superfluid phase. In particular the diagonal correlation length \xi decreases but the superfluid order-parameter correlation function becomes a power-law. A non-monotonic finite-size behavior is noted and explained as arising due to \xi. We provide evidence that at long distances the effects of a weak disordered potential can be mimicked by an effective uniform potential with a root-mean-square value: mu_eff = D/sqrt{3}. For strong disorder, the system becomes a Bose glass insulator., Comment: 6 pages, 6 figures

Published

2006

44. The Role of the Exchange-Correlation Potential in ab initio Electron Transport Calculations

Author

Ke, San-Huang, Baranger, Harold U., and Yang, Weitao

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

The effect of the exchange-correlation potential in ab initio electron transport calculations is investigated by constructing optimized effective potentials (OEP) using different energy functionals or the electron density from second-order perturbation theory. We calculate electron transmission through two atomic chain systems, one with charge transfer and one without. Dramatic effects are caused by two factors: changes in the energy gap and the self-interaction error. The error in conductance caused by the former is about one order of magnitude while that caused by the latter ranges from several times to two orders of magnitude, depending on the coupling strength and charge transfer. The implications for accurate quantum transport calculations are discussed., Comment: 4 pages, published version, substantially revised discussion and revisions for clarity

Published

2006

45. Resilient Quantum Computation in Correlated Environments: A Quantum Phase Transition Perspective

Author

Novais, E., Mucciolo, Eduardo R., and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

We analyze the problem of a quantum computer in a correlated environment protected from decoherence by QEC using a perturbative renormalization group approach. The scaling equation obtained reflects the competition between the dimension of the computer and the scaling dimension of the correlations. For an irrelevant flow, the error probability is reduced to a stochastic form for long time and/or large number of qubits; thus, the traditional derivation of the threshold theorem holds for these error models. In this way, the ``threshold theorem'' of quantum computing is rephrased as a dimensional criterion., Comment: 4.1 pages, minor correction and an improved discussion of Eqs. (4) and (14)

Published

2006

46. Quantum Phase Transitions of Hard-Core Bosons in Background Potentials

Author

Priyadarshee, Anand, Chandrasekharan, Shailesh, Lee, Ji-Woo, and Baranger, Harold U.

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Superconductivity

Abstract

We study the zero temperature phase diagram of hard core bosons in two dimensions subjected to three types of background potentials: staggered, uniform, and random. In all three cases there is a quantum phase transition from a superfluid (at small potential) to a normal phase (at large potential), but with different universality classes. As expected, the staggered case belongs to the XY universality, while the uniform potential induces a mean field transition. The disorder driven transition is clearly different from both; in particular, we find z~1.4, \nu~1, and \beta~0.6., Comment: 4 pages (6 figures); published version-- 2 references added, minor clarifications

Published

2006

47. Spectroscopy of the Kondo Problem in a Box

Author

Kaul, Ribhu K., Zaránd, Gergely, Chandrasekharan, Shailesh, Ullmo, Denis, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Motivated by experiments on double quantum dots, we study the problem of a single magnetic impurity confined in a finite metallic host. We prove an exact theorem for the ground state spin, and use analytic and numerical arguments to map out the spin structure of the excitation spectrum of the many-body Kondo-correlated state, throughout the weak to strong coupling crossover. These excitations can be probed in a simple tunneling-spectroscopy transport experiment; for that situation we solve rate equations for the conductance., Comment: 4 pages, 4 figures

Published

2006

48. Correlation Induced Inhomogeneity in Circular Quantum Dots

Author

Ghosal, Amit, Guclu, A. D., Umrigar, C. J., Ullmo, Denis, and Baranger, Harold U.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

Properties of the "electron gas" - in which conduction electrons interact by means of Coulomb forces but ionic potentials are neglected - change dramatically depending on the balance between kinetic energy and Coulomb repulsion. The limits are well understood. For very weak interactions (high density), the system behaves as a Fermi liquid, with delocalized electrons. In contrast, in the strongly interacting limit (low density), the electrons localize and order into a Wigner crystal phase. The physics at intermediate densities, however, remains a subject of fundamental research. Here, we study the intermediate-density electron gas confined to a circular disc, where the degree of confinement can be tuned to control the density. Using accurate quantum Monte Carlo techniques, we show that the electron-electron correlation induced by an increase of the interaction first smoothly causes rings, and then angular modulation, without any signature of a sharp transition in this density range. This suggests that inhomogeneities in a confined system, which exist even without interactions, are significantly enhanced by correlations., Comment: final version, modified introduction and clarifications, 4 pages

Published

2006

49. Nanotube-Metal Junctions: 2- and 3- Terminal Electrical Transport

Author

Ke, San-Huang, Yang, Weitao, and Baranger, Harold U.

Subjects

Condensed Matter - Materials Science

Abstract

We address the quality of electrical contact between carbon nanotubes and metallic electrodes by performing first-principles calculations for the electron transmission through ideal 2- and 3-terminal junctions, thus revealing the physical limit of tube-metal conduction. The structural model constructed involves surrounding the tube by the metal atoms of the electrode as in most experiments; we consider metallic (5,5) and n-doped semiconducting (10,0) tubes surrounded by Au or Pd. In the case of metallic tubes, the contact conductance is shown to approach the ideal 4e^2/h in the limit of large contact area. For three-terminals, the division of flux among the different transmission channels depends strongly on the metal material. A Pd electrode has nearly perfect tube-electrode transmission and therefore turns off the straight transport along the tube. Our results are in good agreement with some recent experimental reports and clarify a fundamental discrepancy between theory and experiment., Comment: 5 pages, 5 figures, published version: some modified figures and clarifications in the text

Published

2005

50. Decoherence by Correlated Noise and Quantum Error Correction

Author

Novais, E. and Baranger, Harold U.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study the decoherence of a quantum computer in an environment which is inherently correlated in time and space. We first derive the nonunitary time evolution of the computer and environment in the presence of a stabilizer error correction code, providing a general way to quantify decoherence for a quantum computer. The general theory is then applied to the spin-boson model. Our results demonstrate that effects of long-range correlations can be systematically reduced by small changes in the error correction codes., Comment: 4 pages, 1 figure, Phys. Rev. Lett. in press

Published

2005