Measuring out-of-time-order correlations and multiple quantum spectra in a trapped ion quantum magnet (1608.08938v4)

Abstract: Controllable arrays of ions and ultra-cold atoms can simulate complex many-body phenomena and may provide insights into unsolved problems in modern science. To this end, experimentally feasible protocols for quantifying the buildup of quantum correlations and coherence are needed, as performing full state tomography does not scale favorably with the number of particles. Here we develop and experimentally demonstrate such a protocol, which uses time reversal of the many-body dynamics to measure out-of-time-order correlation functions (OTOCs) in a long-range Ising spin quantum simulator with more than 100 ions in a Penning trap. By measuring a family of OTOCs as a function of a tunable parameter we obtain fine-grained information about the state of the system encoded in the multiple quantum coherence spectrum, extract the quantum state purity, and demonstrate the buildup of up to 8-body correlations. Future applications of this protocol could enable studies of many-body localization, quantum phase transitions, and tests of the holographic duality between quantum and gravitational systems.

Measuring Out-of-Time-Order Correlations and Multiple Quantum Spectra in a Trapped Ion Quantum Magnet

The paper "Measuring out-of-time-order correlations and multiple quantum spectra in a trapped ion quantum magnet" offers substantial insights into the exploration of quantum information dynamics using a trapped-ion quantum simulator. The authors present an experimental protocol that operationalizes the measurement of out-of-time-order correlation functions (OTOCs) in a long-range Ising spin quantum simulator with over 100 ions. Such protocols are pivotal as they provide fine-grained information about the quantum state, encode multiple quantum coherence spectra, and demonstrate the growth of multi-body correlations.

Protocol and Experimental Design

The authors have effectively designed a protocol that employs many-body time-reversal dynamics to probe the scrambling of quantum information. The protocol's cornerstone is the Ising model facilitated by a Penning trap containing over 100 trapped ions, which interact through all-to-all Ising couplings. This interaction model allows for a tangible simulation of quantum dynamics, capturing the coherence and correlation attributes at various levels, ranging from single-particle operators to multi-particle OTOCs.

A notable aspect of the methodology is the use of a time-reversal scheme combined with spin rotations, which provides a direct route to measure OTOCs. The configuration enables an explicit assessment of the system's fidelity, essential for benchmarking the quantum simulator, and allows for a detailed examination of the multi-body correlations up to an 8-body interaction level. Additionally, the work demonstrates the protocol's application’s potential to explore quantum phase transitions, many-body localization, and test holographic dualities.

Numerical Results and Observations

Key numerical insights are provided quantifying the scrambling of quantum information, with the buildup of higher-order correlations validated through the measurement of multiple quantum intensities—indicative of the system's coherence. The results reveal a progressive buildup of even-numbered Fourier components in the fidelity's Fourier transform as interaction time increases, indicating growing many-body correlations.

The experiments measured fidelity as a function of a rotation angle after a sequence of evolution under the Ising Hamiltonian, preceded and followed by a time reversal step. The decay of fidelity due to decoherence effects was analyzed, with off-resonant light scattering identified as a primary source. The impact of these decoherence processes on the observed fidelity and magnetization signals were thoroughly characterized, offering a calibrated understanding of the imperfections in the system, including slow magnetic field drifts and COM frequency fluctuations.

Practical and Theoretical Implications

Practically, this work demonstrates a robust platform for simulating quantum many-body dynamics, providing a significant contribution to the understanding of quantum information flow and scrambling in complex systems. The theoretical implications intersect with fundamental questions in quantum mechanics regarding entropy, unitary evolution, and the information-theoretic interpretation of physical laws. These protocols are not only applicable to trapped-ion setups but also extendable to other platforms with reversible dynamics, such as ultracold atomic gases and superconducting qubits.

Future Directions

The findings open pathways for future research in the domain of quantum simulations, with potential extensions encompassing more complex systems beyond classical simulation limits. By incorporating spatially inhomogeneous magnetic fields or preparing the quantum system in non-symmetric initial states, further studies can explore uncharted regimes of fast scrambling. The continued development of such experimental techniques promises deeper insights into the quantum-classical boundary and potentially life the veil on the implications of quantum mechanics on statistical mechanics and thermodynamics.

In summary, this paper underscores critical progress in the experimental application of quantum information theory, significantly enhancing our toolkit for probing the fundamental behaviors of quantum many-body systems. Future investigations, leveraging these methodologies, are likely to unlock further complexities of quantum phenomena, driving forward our comprehensive understanding of quantum mechanics.