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23 results on '"Gambetta, Filippo Maria"'

1. Unveiling quantum phase transitions from traps in variational quantum algorithms

Author

Cao, Chenfeng, Gambetta, Filippo Maria, Montanaro, Ashley, and Santos, Raul A.

Subjects
Quantum Physics
Abstract

Understanding quantum phase transitions in physical systems is fundamental to characterize their behaviour at small temperatures. Achieving this requires both accessing good approximations to the ground state and identifying order parameters to distinguish different phases. Addressing these challenges, our work introduces a hybrid algorithm that combines quantum optimization with classical machine learning. This approach leverages the capability of near-term quantum computers to prepare locally trapped states through finite optimization. Specifically, we utilize LASSO for identifying conventional phase transitions and the Transformer model for topological transitions, applying these with a sliding window of Hamiltonian parameters to learn appropriate order parameters and estimate the critical points accurately. We verified the effectiveness of our method with numerical simulation and real-hardware experiments on Rigetti's Ankaa 9Q-1 quantum computer. Our protocol not only provides a robust framework for investigating quantum phase transitions using shallow quantum circuits but also significantly enhances efficiency and precision, opening new avenues in the integration of quantum computing and machine learning., Comment: 19 pages, 9 figures

Published
2024

2. Efficient and practical Hamiltonian simulation from time-dependent product formulas

Author

Bosse, Jan Lukas, Childs, Andrew M., Derby, Charles, Gambetta, Filippo Maria, Montanaro, Ashley, and Santos, Raul A.

Subjects
Quantum Physics
Abstract

In this work we propose an approach for implementing time-evolution of a quantum system using product formulas. The quantum algorithms we develop have provably better scaling (in terms of gate complexity and circuit depth) than a naive application of well-known Trotter formulas, for systems where the evolution is determined by a Hamiltonian with different energy scales (i.e., one part is "large" and another part is "small"). Our algorithms generate a decomposition of the evolution operator into a product of simple unitaries that are directly implementable on a quantum computer. Although the theoretical scaling is suboptimal compared with state-of-the-art algorithms (e.g., quantum signal processing), the performance of the algorithms we propose is highly competitive in practice. We illustrate this via extensive numerical simulations for several models. For instance, in the strong-field regime of the 1D transverse-field Ising model, our algorithms achieve an improvement of one order of magnitude in both the system size and evolution time that can be simulated with a fixed budget of 1000 arbitrary 2-qubit gates, compared with standard Trotter formulas., Comment: 39 pages, 14 figures, 4 tables

Published
2024

4. Towards near-term quantum simulation of materials

Author

Clinton, Laura, Cubitt, Toby, Flynn, Brian, Gambetta, Filippo Maria, Klassen, Joel, Montanaro, Ashley, Piddock, Stephen, Santos, Raul A., and Sheridan, Evan

Subjects
Quantum Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

Simulation of materials is one of the most promising applications of quantum computers. On near-term hardware the crucial constraint on these simulations is circuit depth. Many quantum simulation algorithms rely on a layer of unitary evolutions generated by each term in a Hamiltonian. This appears in time-dynamics as a single Trotter step, and in variational quantum eigensolvers under the Hamiltonian variational ansatz as a single ansatz layer. We present a new quantum algorithm design for materials modelling where the depth of a layer is independent of the system size. This design takes advantage of the locality of materials in the Wannier basis and employs a tailored fermionic encoding that preserves locality. We analyse the circuit costs of this approach and present a compiler that transforms density functional theory data into quantum circuit instructions -- connecting the physics of the material to the simulation circuit. The compiler automatically optimises circuits at multiple levels, from the base gate level to optimisations derived from the physics of the specific target material. We present numerical results for materials spanning a wide structural and technological range. Our results demonstrate a reduction of many orders of magnitude in circuit depth over standard prior methods that do not consider the structure of the Hamiltonian. For example our results improve resource requirements for Strontium Vanadate (SrVO$_3$) from 864 to 180 qubits for a $3\times3\times3$ lattice, and the circuit depth of a single Trotter or variational layer from $7.5\times 10^8$ to depth $884$. Although this is still beyond current hardware, our results show that materials simulation may be feasible on quantum computers without necessarily requiring scalable, fault-tolerant quantum computers, provided quantum algorithm design incorporates understanding of the materials and applications., Comment: 94 pages, 38 figures, 13 tables

Published
2022
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5. Observing ground-state properties of the Fermi-Hubbard model using a scalable algorithm on a quantum computer

Author

Stanisic, Stasja, Bosse, Jan Lukas, Gambetta, Filippo Maria, Santos, Raul A., Mruczkiewicz, Wojciech, O'Brien, Thomas E., Ostby, Eric, and Montanaro, Ashley

Subjects
Quantum Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

The famous, yet unsolved, Fermi-Hubbard model for strongly-correlated electronic systems is a prominent target for quantum computers. However, accurately representing the Fermi-Hubbard ground state for large instances may be beyond the reach of near-term quantum hardware. Here we show experimentally that an efficient, low-depth variational quantum algorithm with few parameters can reproduce important qualitative features of medium-size instances of the Fermi-Hubbard model. We address 1x8 and 2x4 instances on 16 qubits on a superconducting quantum processor, substantially larger than previous work based on less scalable compression techniques, and going beyond the family of 1D Fermi-Hubbard instances, which are solvable classically. Consistent with predictions for the ground state, we observe the onset of the metal-insulator transition and Friedel oscillations in 1D, and antiferromagnetic order in both 1D and 2D. We use a variety of error-mitigation techniques, including symmetries of the Fermi-Hubbard model and a recently developed technique tailored to simulating fermionic systems. We also introduce a new variational optimisation algorithm based on iterative Bayesian updates of a local surrogate model. Our scalable approach is a first step to using near-term quantum computers to determine low-energy properties of strongly-correlated electronic systems that cannot be solved exactly by classical computers., Comment: 26 pages, 13 figures

Published
2021
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6. Exploring the many-body dynamics near a conical intersection with trapped Rydberg ions

Author

Gambetta, Filippo Maria, Zhang, Chi, Hennrich, Markus, Lesanovsky, Igor, and Li, Weibin

Subjects
Physics - Atomic Physics, Quantum Physics
Abstract

Conical intersections between electronic potential energy surfaces are paradigmatic for the study of non-adiabatic processes in the excited states of large molecules. However, since the corresponding dynamics occurs on a femtosecond timescale, their investigation remains challenging and requires ultrafast spectroscopy techniques. We demonstrate that trapped Rydberg ions are a platform to engineer conical intersections and to simulate their ensuing dynamics on larger length and time scales of the order of nanometers and microseconds, respectively; all this in a highly controllable system. Here, the shape of the potential energy surfaces and the position of the conical intersection can be tuned thanks to the interplay between the high polarizability and the strong dipolar exchange interactions of Rydberg ions. We study how the presence of a conical intersection affects both the nuclear and electronic dynamics demonstrating, in particular, how it results in the inhibition of the nuclear motion. These effects can be monitored in real-time via a direct spectroscopic measurement of the electronic populations in a state-of-the-art experimental setup., Comment: Main: 6 pages, 3 figures. Supplemental Material: 8 pages, 3 figures

Published
2020
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7. Long-range multi-body interactions and three-body anti-blockade in a trapped Rydberg ion chain

Author

Gambetta, Filippo Maria, Zhang, Chi, Hennrich, Markus, Lesanovsky, Igor, and Li, Weibin

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

Trapped Rydberg ions represent a flexible platform for quantum simulation and information processing which combines a high degree of control over electronic and vibrational degrees of freedom. The possibility to individually excite ions to high-lying Rydberg levels provides a system where strong and long-range interactions between pairs of excited ions can be engineered and tuned via external laser fields. We show that the coupling between Rydberg pair interactions and collective motional modes gives rise to effective long-range multi-body interactions, consisting of two, three, and four-body terms. Their shape, strength, and range can be controlled via the ion trap parameters and strongly depends on both the equilibrium configuration and vibrational modes of the ion crystal. By focusing on an experimentally feasible quasi one-dimensional setup of $ {}^{88}\mathrm{Sr}^+ $ Rydberg ions, we demonstrate that multi-body interactions are enhanced by the emergence of a soft mode associated, e.g., with a structural phase transition. This has a striking impact on many-body electronic states and results, for example, in a three-body anti-blockade effect. Our study shows that trapped Rydberg ions offer new opportunities to study exotic many-body quantum dynamics driven by enhanced multi-body interactions., Comment: Main text: 6 pages, 4 figures; Supplemental Material: 4 pages, 1 figure

Published
2020
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8. Engineering non-binary Rydberg interactions via phonons in an optical lattice

Author

Gambetta, Filippo Maria, Li, Weibin, Schmidt-Kaler, Ferdinand, and Lesanovsky, Igor

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics
Abstract

Coupling electronic and vibrational degrees of freedom of Rydberg atoms held in optical tweezer arrays offers a flexible mechanism for creating and controlling atom-atom interactions. We find that the state-dependent coupling between Rydberg atoms and local oscillator modes gives rise to two- and three-body interactions which are controllable through the strength of the local confinement. This approach even permits the cancellation of two-body terms such that three-body interactions become dominant. We analyze the structure of these interactions on two-dimensional bipartite lattice geometries and explore the impact of three-body interactions on system ground state on a square lattice. Focusing specifically on a system of $ ^{87} $Rb atoms, we show that the effects of the multi-body interactions can be maximized via a tailored dressed potential within a trapping frequency range of the order of a few hundred kHz and for temperatures corresponding to a $ >90\% $ occupation of the atomic vibrational ground state. These parameters, as well as the multi-body induced time scales, are compatible with state-of-the-art arrays of optical tweezers. Our work shows a highly versatile handle for engineering multi-body interactions of quantum many-body systems in most recent manifestations on Rydberg lattice quantum simulators., Comment: Main text: 6 pages, 4 figures; Supplemental Material: 6 pages, 6 figures

Published
2019
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9. Universal scaling of quench-induced correlations in a one-dimensional channel at finite temperature

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas L., and Sassetti, Maura

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases
Abstract

It has been shown that a quantum quench of interactions in a one-dimensional fermion system at zero temperature induces a universal power law $\propto t^{-2}$ in its long-time dynamics. In this paper we demonstrate that this behaviour is robust even in the presence of thermal effects. The system is initially prepared in a thermal state, then at a given time the bath is disconnected and the interaction strength is suddenly quenched. The corresponding effects on the long times dynamics of the non-equilibrium fermionic spectral function are considered. We show that the non-universal power laws, present at zero temperature, acquire an exponential decay due to thermal effects and are washed out at long times, while the universal behaviour $\propto t^{-2}$ is always present. To verify our findings, we argue that these features are also visible in transport properties at finite temperature. The long-time dynamics of the current injected from a biased probe exhibits the same universal power law relaxation, in sharp contrast with the non-quenched case which features a fast exponential decay of the current towards its steady value, and thus represents a fingerprint of quench-induced dynamics. Finally, we show that a proper tuning of the probe temperature, compared to that of the one-dimensional channel, can enhance the visibility of the universal power-law behaviour., Comment: 22 pages, 5 figures. Submission to SciPost

Published
2017
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10. Quench-induced entanglement and relaxation dynamics in Luttinger liquids

Author

Calzona, Alessio, Gambetta, Filippo Maria, Cavaliere, Fabio, Carrega, Matteo, and Sassetti, Maura

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases
Abstract

We investigate the time evolution towards the asymptotic steady state of a one dimensional interacting system after a quantum quench. We show that at finite time the latter induces entanglement between right- and left- moving density excitations, encoded in their cross-correlators, which vanishes in the long-time limit. This behavior results in a universal time-decay in system spectral properties $ \propto t^{-2} $, in addition to non-universal power-law contributions typical of Luttinger liquids. Importantly, we argue that the presence of quench-induced entanglement clearly emerges in transport properties, such as charge and energy currents injected in the system from a biased probe, and determines their long-time dynamics. In particular, energy fractionalization phenomenon turns out to be a promising platform to observe the universal power-law decay $ \propto t^{-2} $ induced by entanglement and represents a novel way to study the corresponding relaxation mechanism., Comment: 11 pages, 3 figures

Published
2017
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12. Non-equilibrium effects on charge and energy partitioning after an interaction quench

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

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

Charge and energy fractionalization are among the most intriguing features of interacting onedimensional fermion systems. In this work we determine how these phenomena are modified in the presence of an interaction quench. Charge and energy are injected into the system suddenly after the quench, by means of tunneling processes with a non-interacting one-dimensional probe. Here, we demonstrate that the system settles to a steady state in which the charge fractionalization ratio is unaffected by the pre-quenched parameters. On the contrary, due to the post-quench nonequilibrium spectral function, the energy partitioning ratio is strongly modified, reaching values larger than one. This is a peculiar feature of the non-equilibrium dynamics of the quench process and it is in sharp contrast with the non-quenched case, where the ratio is bounded by one., Comment: 12 pages, 4 figures

Published
2016
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14. Universal scaling of quench-induced correlations in a one-dimensional channel at finite temperature

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas, and Sassetti, Maura

Abstract

It has been shown that a quantum quench of interactions in a one-dimensional fermion system at zero temperature induces a universal power law ∝t−2 in its long-time dynamics. In this paper we demonstrate that this behaviour is robust even in the presence of thermal effects. The system is initially prepared in a thermal state, then at a given time the bath is disconnected and the interaction strength is suddenly quenched. The corresponding effects on the long times dynamics of the non-equilibrium fermionic spectral function are considered. We show that the non-universal power laws, present at zero temperature, acquire an exponential decay due to thermal effects and are washed out at long times, while the universal behaviour ∝t−2 is always present. To verify our findings, we argue that these features are also visible in transport properties at finite temperature. The long-time dynamics of the current injected from a biased probe exhibits the same universal power law relaxation, in sharp contrast with the non-quenched case which features a fast exponential decay of the current towards its steady value, and thus represents a fingerprint of quench-induced dynamics. Finally, we show that a proper tuning of the probe temperature, compared to that of the one-dimensional channel, can enhance the visibility of the universal power-law behaviour.

Published
2018
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15. Asymmetries in the spectral density of an interaction-quenched Luttinger liquid

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

The spectral density of an interaction-quenched one-dimensional system is investigated. Both direct and inverse quench protocols are considered and it is found that the former leads to stronger effects on the spectral density with respect to the latter. Such asymmetry is directly reflected on transport properties of the system, namely the charge and energy current flowing to the system from a tunnel coupled biased probe. In particular, the injection of particles from the probe to the right-moving channel of the system is considered. The resulting fractionalization phenomena are strongly affected by the quench protocol and display asymmetries in the case of direct and inverse quench. Transport properties therefore emerge as natural probes for the observation of this quench-induced behavior.

Published
2018
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17. Nonequilibrium effects on charge and energy partitioning after an interaction quench

Author

MIUR-FIRB2013 – Project Coca (Grant No. RBFR1379UX) [sponsor], COST Action MP1209 [sponsor], Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Sassetti, Maura, MIUR-FIRB2013 – Project Coca (Grant No. RBFR1379UX) [sponsor], COST Action MP1209 [sponsor], Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, and Sassetti, Maura

Abstract

Charge and energy fractionalization are among the most intriguing features of interacting one-dimensional fermion systems. In this work we determine how these phenomena are modified in the presence of an interaction quench. Charge and energy are injected into the system suddenly after the quench, by means of tunneling processes with a noninteracting one-dimensional probe. Here, we demonstrate that the system settles to a steady state in which the charge fractionalization ratio is unaffected by the prequenched parameters. On the contrary, due to the postquench nonequilibrium spectral function, the energy partitioning ratio is strongly modified, reaching values larger than 1. This is a peculiar feature of the nonequilibrium dynamics of the quench process and it is in sharp contrast with the nonquenched case, where the ratio is bounded by 1.

Published
2017

19. Transport Properties as a Tool to Study Universal Quench-induced Dynamics in 1D Systems

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Sassetti, Maura, Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, and Sassetti, Maura

Abstract

The study of the relaxation process that follows a quantum quench in 1D systems still represents an open research field. Here we consider a sudden change of the interparticle interaction and we identify a peculiar correlator of the system whose behavior is directly and deeply affected by the quench-induced dynamics. Interestingly, it features a universal power-law decay in time. Unfortunately, such a universal decay, although present, turns out to be subleading in intrinsic properties of the system such as the non- equilibrium spectral function. We thus consider a tunnel coupling of the system with a biased tip in order to be able to study also transport properties, namely the charge and energy current flowing from the tip to the system after the quench. In these quantities the universal power-law emerges clearly, especially if one focuses on energy current and its fractionalization into a right- and left- moving components. In particular, we show that the presence of a transient in the energy fractionalization ratio is a direct hallmark of the quench-induced relaxation. Within the setup we have considered, time-dependent transport properties are thus promoted to useful and promising tools to access the mechanisms at the base of the out-of- equilibrium dynamics following quantum quench.

Published
2017

20. Quench-induced entanglement and relaxation dynamics in Luttinger liquids

Author

Calzona, Alessio(*), Gambetta, Filippo Maria(*), Cavaliere, Fabio, Carrega, Matteo, Sassetti, Maura, Calzona, Alessio(*), Gambetta, Filippo Maria(*), Cavaliere, Fabio, Carrega, Matteo, and Sassetti, Maura

Abstract

We investigate the time evolution towards the asymptotic steady state of a one-dimensional interacting system after a quantum quench. We show that at finite times the latter induces entanglement between right- and left-moving density excitations, encoded in their cross-correlators, which vanishes in the long-time limit. This behavior results in a universal time decay ∝t−2 of the system spectral properties, in addition to nonuniversal power-law contributions typical of Luttinger liquids. Importantly, we argue that the presence of quench-induced entanglement clearly emerges in transport properties, such as charge and energy currents injected in the system from a biased probe and determines their long-time dynamics. In particular, the energy fractionalization phenomenon turns out to be a promising platform to observe the universal power-law decay ∝t−2 induced by entanglement and represents a novel way to study the corresponding relaxation mechanism.

Published
2017

23. Anomalous Friedel oscillations in a quasihelical quantum dot

Author

Gambetta, FILIPPO MARIA, Ziani, N. Traverso, Barbarino, S., Cavaliere, Fabio, Sassetti, Maura, and TRAVERSO ZIANI, Niccolo'

Subjects
Physics, Friedel oscillations, Zeeman effect, Condensed matter physics, Quantum wire, Fermi surface, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Magnetic field, DIMENSIONAL ELECTRON-GAS, SPIN-ORBIT INTERACTION, LUTTINGER LIQUID, WIGNER MOLECULES, CARBON NANOTUBE, CONDUCTANCE, WELLS, symbols.namesake, Luttinger liquid, Electronic, Quasiparticle, symbols, Condensed Matter::Strongly Correlated Electrons, Optical and Magnetic Materials, Spin-½
Abstract

The charge and spin patterns of a quantum dot embedded into a spin-orbit coupled quantum wire subject to a magnetic field are investigated. A Luttinger liquid theory is developed, taking into account open boundaries and finite magnetic field. In the quasi-helical regime, when spin-orbit effects dominate over the Zeeman interaction, peculiar states develop at the Fermi surface of the dot. Anomalous Friedel oscillations with twice the expected wavelength develop in the wavefunction of collective excitations of such states, accompanied by peculiar spin patterns in their magnetization. Both effects are analyzed in detail and shown possible to be probed in transport experiments. The stability against electron interactions and magnetic field is investigated. We also discuss how signatures of such states survive in the total charge and spin densities.

Published
2015
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