7. Coherent manipulation of three-qubit states in a molecular single-ion magnet
M. D. Jenkins, Y. Duan, B. Diosdado, J. J. García-Ripoll, A. Gaita-Ariño, C. Giménez-Saiz, P. J. Alonso, E. Coronado, F. Luis
Physical Review B 95 (6), 064423 (2017)
6. Dynamical signatures of bound states in waveguide QED
E. Sánchez-Burillo, D. Zueco, L. Martín-Moreno, J. J. García-Ripoll
arXiv:1603.09408, Physical Review A 96 (2), 023831 (2017)
We study the spontaneous decay of an impurity coupled to a linear array of bosonic cavities forming a single-band photonic waveguide. The average frequency of the emitted photon is different from the frequency for single-photon resonant scattering, which perfectly matches the bare frequency of the excited state of the impurity. We study how the energy of the excited state of the impurity influences the spatial profile of the emitted photon. The farther the energy is from the middle of the photonic band, the farther the wave packet is from the causal limit. In particular, if the energy lies in the middle of the band, the wave packet is localized around the causal limit. Besides, the occupation of the excited state of the impurity presents a rich dynamics: it shows an exponential decay up to intermediate times, this is followed by a power-law tail in the long-time regime, and it finally reaches an oscillatory stationary regime. Finally, we show that this phenomenology is robust under the presence of losses, both in the impurity and the cavities.
5. Emergent causality and theN-photon scattering matrix in waveguide QED
E Sánchez-Burillo, A Cadarso, L Martín-Moreno, J J García-Ripoll, D Zueco
arXiv:1705.09094, New Journal of Physics 20 (1), 013017 (2017)
In this work we discuss the emergence of approximate causality in a general setup from waveguide QED -i.e. a one-dimensional propagating field interacting with a scatterer. We prove that this emergent causality translates into a structure for the N-photon scattering matrix. Our work builds on the derivation of a Lieb-Robinson-type bound for continuous models and for all coupling strengths, as well as on several intermediate results, of which we highlight (i) the asymptotic independence of space-like separated wave packets, (ii) the proper definition of input and output scattering states, and (iii) the characterization of the ground state and correlations in the model. We illustrate our formal results by analyzing the two-photon scattering from a quantum impurity in the ultrastrong coupling regime, verifying the cluster decomposition and ground-state nature. Besides, we generalize the cluster decomposition if inelastic or Raman scattering occurs, finding the structure of the S-matrix in momentum space for linear dispersion relations. In this case, we compute the decay of the fluorescence (photon-photon correlations) caused by this S-matrix.
4. Equivalence between spin Hamiltonians and boson sampling
Borja Peropadre, Alán Aspuru-Guzik, Juan José García-Ripoll
Physical Review A 95 (3), 032327 (2017)
3. Multiphoton Scattering Tomography with Coherent States
Tomás Ramos, Juan José García-Ripoll
arXiv:1705.10211, Physical Review Letters 119 (15), 153601 (2017)
In this work we develop an experimental procedure to interrogate the single- and multiphoton scattering matrices of an unknown quantum system interacting with propagating photons. Our proposal requires coherent state laser or microwave inputs and homodyne detection at the scatterer’s output, and provides simultaneous information about multiple —elastic and inelastic— segments of the scattering matrix. The method is resilient to detector noise and its errors can be made arbitrarily small by combining experiments at various laser powers. Finally, we show that the tomography of scattering has to be performed using pulsed lasers to efficiently gather information about the nonlinear processes in the scatterer.
2. Quantum Emulation of Molecular Force Fields: A Blueprint for a Superconducting Architecture
Diego González Olivares, Borja Peropadre, Joonsuk Huh, Juan José García-Ripoll
arXiv:1611.08101, Physical Review Applied 8 (6), 064008 (2017)
In this work, we propose a flexible architecture of microwave resonators with tunable couplings to perform quantum simulations of problems from the field of molecular chemistry. The architecture builds on the experience of the D-Wave design, working with nearly harmonic circuits instead of qubits. This architecture, or modifications of it, can be used to emulate molecular processes such as vibronic transitions. Furthermore, we discuss several aspects of these emulations, such as dynamical ranges of the physical parameters, quenching times necessary for diabaticity, and, finally, the possibility of implementing anharmonic corrections to the force fields by exploiting certain nonlinear features of superconducting devices.
1. Quantum Estimation Methods for Quantum Illumination
M. Sanz, U. Las Heras, J. J. García-Ripoll, E. Solano, R. Di Candia
arXiv:1606.06656, Physical Review Letters 118 (7), 070803 (2017)
Quantum illumination consists in shining quantum light on a target region immersed in a bright thermal bath, with the aim of detecting the presence of a possible low-reflective object. If the signal is entangled with the receiver, then a suitable choice of the measurement offers a gain with respect to the optimal classical protocol employing coherent states. Here, we tackle this detection problem by using quantum estimation techniques to measure the reflectivity parameter of the object, showing an enhancement in the signal-to-noise ratio up to 3 dB with respect to the classical case when implementing only local measurements. Our approach employs the quantum Fisher information to provide an upper bound for the error probability, supplies the concrete estimator saturating the bound, and extends the quantum illumination protocol to non-Gaussian states. As an example, we show how Schrodinger’s cat states may be used for quantum illumination.