Publications from 2013

13. Bose–Hubbard models with photon pairing in circuit-QED
Benjamín Villalonga Correa, Andreas Kurcz, Juan José García-Ripoll
arXiv:1304.7196, Journal of Physics B: Atomic, Molecular and Optical Physics 46 (22), 224024 (2013)
In this work we study a family of bosonic lattice models that combine an on-site repulsion term with a nearest-neighbor pairing term, $\sum_{< i,j>} a^\dagger_i a^\dagger_j + \mathrm{H.c.}$ Like the original Bose-Hubbard model, the nearest-neighbor term is responsible for the mobility of bosons and it competes with the local interaction, inducing two-mode squeezing. However, unlike a trivial hopping, the counter-rotating terms form pairing cannot be studied with a simple mean-field theory and does not present a quantum phase transition in phase space. Instead, we show that there is a cross-over from a pure insulator to long-range correlations that start up as soon as the two-mode squeezing is switched on. We also show how this model can be naturally implemented using coupled microwave resonators and superconducting qubits.
12. Circuit QED Bright Source for Chiral Entangled Light Based on Dissipation
Fernando Quijandría, Diego Porras, Juan José García-Ripoll, David Zueco
arXiv:1212.3623, Physical Review Letters 111 (7), 073602 (2013)
Based on a circuit QED qubit-cavity array a source of two-mode entangled microwave radiation is designed. Our scheme is rooted in the combination of external driving, collective phenomena and dissipation. On top of that the reflexion symmetry is broken via external driving permitting the appearance of chiral emission. Our findings go beyond the applications and are relevant for fundamental physics, since we show how to implement quantum lattice models exhibiting criticality driven by dissipation.
11. Collective modes of a trapped ion–dipole system
Jordi Mur-Petit, Juan José García-Ripoll
arXiv:1306.2773, Applied Physics B 114 (1-2), 283-294 (2013)
We study a simple model consisting of an atomic ion and a polar molecule trapped in a single setup, taking into consideration their electrostatic interaction. We determine analytically their collective modes of excitation as a function of their masses, trapping frequencies, distance, and the molecule’s electric dipole moment. We then discuss the application of these collective excitations to cool molecules, to entangle molecules and ions, and to realize two-qubit gates between them. We finally present a numerical analysis of the possibility of applying these tools to study magnetically ordered phases of two-dimensional arrays of polar molecules, a setup proposed to quantum-simulate some strongly-correlated models of condensed matter.
10. Coupling single-molecule magnets to quantum circuits
Mark Jenkins, Thomas Hümmer, María José Martínez-Pérez, Juanjo García-Ripoll, David Zueco, Fernando Luis
arXiv:1306.4276, New Journal of Physics 15 (9), 095007 (2013)
In this work we study theoretically the coupling of single molecule magnets (SMMs) to a variety of quantum circuits, including microwave resonators with and without constrictions and flux qubits. The main results of this study is that it is possible to achieve strong and ultrastrong coupling regimes between SMM crystals and the superconducting circuit, with strong hints that such a coupling could also be reached for individual molecules close to constrictions. Building on the resulting coupling strengths and the typical coherence times of these molecules (of the order of microseconds), we conclude that SMMs can be used for coherent storage and manipulation of quantum information, either in the context of quantum computing or in quantum simulations. Throughout the work we also discuss in detail the family of molecules that are most suitable for such operations, based not only on the coupling strength, but also on the typical energy gaps and the simplicity with which they can be tuned and oriented. Finally, we also discuss practical advantages of SMMs, such as the possibility to fabricate the SMMs ensembles on the chip through the deposition of small droplets.
9. From Josephson junction metamaterials to tunable pseudo-cavities
D Zueco, C Fernández-Juez, J Yago, U Naether, B Peropadre, J J García-Ripoll, J J Mazo
arXiv:1305.4844, Superconductor Science and Technology 26 (7), 074006 (2013)
The scattering through a Josephson junction interrupting a superconducting line is revisited including power leakage. We discuss also how to make tunable and broadband resonant mirrors by concatenating junctions. As an application, we show how to construct cavities using these mirrors, thus connecting two research fields: JJ quantum metamaterials and coupled cavity arrays. We finish by discussing the first non-linear corrections to the scattering and their measurable effects.
8. Generating and verifying graph states for fault-tolerant topological measurement-based quantum computing in two-dimensional optical lattices
Jaewoo Joo, Emilio Alba, Juan José García-Ripoll, Timothy P. Spiller
arXiv:1207.0253, Physical Review A 88 (1), 012328 (2013)
We propose two schemes for implementing graph states useful for fault-tolerant topological measurement-based quantum computation in 2D optical lattices. We show that bilayer cluster and surface code states can be created by global single-row and controlled-Z operations. The schemes benefit from the accessibility of atom addressing on 2D optical lattices and the existence of an efficient verification protocol which allows us to ensure the experimental feasibility of measuring the fidelity of the system against the ideal graph state. The simulation results show potential for a physical realization toward fault-tolerant measurement-based quantum computation against dephasing and unitary phase errors in optical lattices.
7. Hall response of interacting bosonic atoms in strong gauge fields: From condensed to fractional-quantum-Hall states
H. Pino, E. Alba, J. Taron, J. J. Garcia-Ripoll, N. Barberán
Physical Review A 87 (5), 053611 (2013)
6. Lieb-Robinson Bounds for Spin-Boson Lattice Models and Trapped Ions
J. Jünemann, A. Cadarso, D. Pérez-García, A. Bermudez, J. J. García-Ripoll
arXiv:1307.1992, Physical Review Letters 111 (23), 230404 (2013)
We derive a Lieb-Robinson bound for the propagation of spin correlations in a model of spins interacting through a bosonic lattice field, which satisfies itself a Lieb-Robinson bound in the absence of spin-boson couplings. We apply these bounds to a system of trapped ions, and find that the propagation of spin correlations, as mediated by the phonons of the ion crystal, can be faster than the regimes currently explored in experiments. We propose a scheme to test the bounds by measuring retarded correlation functions via the crystal fluorescence.
5. Nonequilibrium and Nonperturbative Dynamics of Ultrastrong Coupling in Open Lines
B. Peropadre, D. Zueco, D. Porras, J. J. García-Ripoll
arXiv:1307.3870, Physical Review Letters 111 (24), 243602 (2013)
We study the time and space resolved dynamics of a qubit with an Ohmic coupling to propagating 1D photons, from weak coupling to the ultrastrong coupling regime. A nonperturbative study based on Matrix Product States (MPS) shows the following results: (i) The ground state of the combined systems contains excitations of both the qubit and the surrounding bosonic field. (ii) An initially excited qubit equilibrates through spontaneous emission to a state, which under certain conditions, is locally close to that ground state, both in the qubit and the field. (iii) The resonances of the combined qubit-photon system match those of the spontaneous emission process and also the predictions of the adiabatic renormalization [A. J. Leggett et al., Rev. Mod. Phys. 59, 1, (1987)]. Finally, a non-perturbative ab-initio calculations show that this physics can be studied using a flux qubit galvanically coupled to a superconducting transmission line.
4. Scattering of coherent states on a single artificial atom
B Peropadre, J Lindkvist, I-C Hoi, C M Wilson, J J Garcia-Ripoll, P Delsing, G Johansson
arXiv:1210.2264, New Journal of Physics 15 (3), 035009 (2013)
In this work we theoretically analyze a circuit QED design where propagating quantum microwaves interact with a single artificial atom, a single Cooper pair box. In particular, we derive a master equation in the so-called transmon regime, including coherent drives. Inspired by recent experiments, we then apply the master equation to describe the dynamics in both a two-level and a three-level approximation of the atom. In the two-level case, we also discuss how to measure photon antibunching in the reflected field and how it is affected by finite temperature and finite detection bandwidth.
3. Seeing Majorana fermions in time-of-flight images of staggered spinless fermions coupled bys-wave pairing
Jiannis K. Pachos, Emilio Alba, Ville Lahtinen, Juan J. Garcia-Ripoll
arXiv:1209.5115, Physical Review A 88 (1), 013622 (2013)
The Chern number, nu, as a topological invariant that identifies the winding of the ground state in the particle-hole space, is a definitive theoretical signature that determines whether a given superconducting system can support Majorana zero modes. Here we show that such a winding can be faithfully identified for any superconducting system (p-wave or s-wave with spin-orbit coupling) through a set of time-of-flight measurements, making it a diagnostic tool also in actual cold atom experiments. As an application, we specialize the measurement scheme for a chiral topological model of spinless fermions. The proposed model only requires the experimentally accessible s-wave pairing and staggered tunnelling that mimics spin-orbit coupling. By adiabatically connecting this model to Kitaev’s honeycomb lattice model, we show that it gives rise to nu = \pm 1 phases, where vortices bind Majorana fermions, and nu=\pm 2 phases that emerge as the unique collective state of such vortices. Hence, the preparation of these phases and the detection of their Chern numbers provide an unambiguous signature for the presence of Majorana modes. Finally, we demonstrate that our detection procedure is resilient against most inaccuracies in experimental control parameters as well as finite temperature.
2. Toward a Molecular Ion Qubit
J. Mur-Petit, J. Pérez-Ríos, J. Campos-Martínez, M. I. Hernández, S. Willitsch, J. J. García-Ripoll
Advances in Atom and Single Molecule Machines , 267-277 (2013)
1. Tunable coupling engineering between superconducting resonators: From sidebands to effective gauge fields
Borja Peropadre, David Zueco, Friedrich Wulschner, Frank Deppe, Achim Marx, Rudolf Gross, Juan José García-Ripoll
arXiv:1207.3408, Physical Review B 87 (13), 134504 (2013)
In this work we show that a tunable coupling between microwave resonators can be engineered by means of simple Josephson junctions circuits, such as dc- and rf-SQUIDs. We show that by controlling the time dependence of the coupling it is possible to switch on and off and modulate the cross-talk, boost the interaction towards the ultrastrong regime, as well as to engineer red and blue sideband couplings, nonlinear photon hopping and classical gauge fields. We discuss how these dynamically tunable superconducting circuits enable key applications in the fields of all optical quantum computing, continuous variable quantum information and quantum simulation – all within the reach of state of the art in circuit-QED experiments.