Your search keyword '"Bengs, Christian"' showing total 8 results

1. Anomalously extended Floquet prethermal lifetimes and applications to long-time quantum sensing

Author

Harkins, Kieren A., Selco, Cooper, Bengs, Christian, Marchiori, David, Moon, Leo Joon Il, Zhang, Zhuo-Rui, Yang, Aristotle, Singh, Angad, Druga, Emanuel, Song, Yi-Qiao, and Ajoy, Ashok

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Floquet prethermalization is observed in periodically driven quantum many-body systems where the system avoids heating and maintains a stable, non-equilibrium state, for extended periods. Here we introduce a novel quantum control method using off-resonance and short-angle excitation to significantly extend Floquet prethermal lifetimes. This is demonstrated on randomly positioned, dipolar-coupled, 13C nuclear spins in diamond, but the methodology is broadly applicable. We achieve a lifetime $T_2'~800 s at 100 K while tracking the transition to the prethermal state quasi-continuously. This corresponds to a >533,000-fold extension over the bare spin lifetime without prethermalization, and constitutes a new record both in terms of absolute lifetime as well as the total number of Floquet pulses applied (here exceeding 7 million). Using Laplace inversion, we develop a new form of noise spectroscopy that provides insights into the origin of the lifetime extension. Finally, we demonstrate applications of these extended lifetimes in long-time, reinitialization-free quantum sensing of time-varying magnetic fields continuously for ~10 minutes at room temperature. Our work facilitates new opportunities for stabilizing driven quantum systems through Floquet control, and opens novel applications for continuously interrogated, long-time responsive quantum sensors., Comment: 6 pages, 4 figures

Published

2024

2. Robust Parahydrogen-Induced Polarization at High Concentrations

Author

Dagys, Laurynas, Korzeczek, Martin C., Parker, Anna J., Eills, James, Blanchard, John W., Bengs, Christian, Levitt, Malcolm H., Knecht, Stephan, Schwartz, Ilai, and Plenio, M. B.

Subjects

Physics - Chemical Physics, Quantum Physics

Abstract

Parahydrogen-Induced Polarization (PHIP) is a potent technique for generating target molecules with high nuclear spin polarization. The PHIP process involves a chemical reaction between parahydrogen and a target molecule, followed by the transformation of nuclear singlet spin order into magnetization of a designated nucleus through magnetic field manipulations. Although the singlet-to-magnetization polarization transfer process works effectively at moderate concentrations, it is observed to become much less efficient at high molar polarization, defined as the product of polarization and concentration. This strong dependence on the molar polarization is attributed to interference from the field produced by the sample's magnetization during polarization transfer, which leads to complex dynamics and can severely impact the scalability of the technique. We address this challenge with a pulse sequence that negates the influence of the distant dipolar field, while simultaneously achieving singlet-to-magnetization polarization transfer to the desired target spins, free from restrictions on the molar polarization.

Published

2024

3. Cross-correlation effects in the solution NMR spectra of near-equivalent spin-1/2 pairs

Author

Whipham, James W., Moustafa, Gamal A. I., Sabba, Mohamed, Gong, Weidong, Bengs, Christian, and Levitt, Malcolm H.

Subjects

Physics - Chemical Physics

Abstract

The NMR spectra of spin-1/2 pairs contains four peaks, with two inner peaks much stronger than the outer peaks in the near-equivalence regime. We have observed that the strong inner peaks have significantly different linewidths, when measurements were performed on a 13C2-labelled triyne derivative. This linewidth difference may be attributed to strong cross-correlation effects. We develop the theory of cross-correlated relaxation in the case of near-equivalent homonuclear spin-1/2 pairs, in the case of a molecule exhibiting strongly anisotropic rotational diffusion. Good agreement is found with the experimental NMR lineshapes., Comment: Main text 11 pages, supplementary material 8 pages. Main text 5 figures, supplementary material 6 figures. To be published in the Journal of Chemical Physics

Published

2022

4. Symmetry-Based Singlet-Triplet Excitation in Solution Nuclear Magnetic Resonance

Author

Sabba, Mohamed, Wili, Nino, Bengs, Christian, Brown, Lynda J., and Levitt, Malcolm H.

Subjects

Quantum Physics

Abstract

Coupled pairs of spin-1/2 nuclei support one singlet state and three triplet states. In many circumstances the nuclear singlet order, defined as the difference between the singlet population and the mean of the triplet populations, is a long-lived state which persists for a relatively long time in solution. Various methods have been proposed for generating singlet order, starting from nuclear magnetization. This requires the stimulation of singlet-to-triplet transitions by modulated radiofrequency fields. We show that a recently described pulse sequence, known as PulsePol (Schwartz $\textit{et al.}$, Science Advances, $\textbf{4}$, eaat8978 (2018) and arXiv:1710.01508), is an efficient technique for converting magnetization into long-lived singlet order. We show that the operation of this pulse sequence may be understood by adapting the theory of symmetry-based recoupling sequences in magic-angle-spinning solid-state NMR. The concept of riffling allows PulsePol to be interpreted using the theory of symmetry-based pulse sequences, and explains its robustness. This theory is used to derive a range of new pulse sequences for performing singlet-triplet excitation and conversion in solution NMR. Schemes for further enhancing the robustness of the transformations are demonstrated., Comment: 30 pages, 17 figures (9 in main text; 8 in SI). Submitted to JCP on 14/06/22

Published

2022

5. Hyperpolarization read-out through rapidly rotating fields in the zero- and low-field regime

Author

Dagys, Laurynas and Bengs, Christian

Subjects

Quantum Physics, Physics - Chemical Physics

Abstract

An integral part of para-hydrogen induced polarization (PHIP) methods is the conversion of nuclear singlet order into observable magnetization. In this study polarisation transfer to a heteronucleus is achieved through a selective rotation of the proton singlet-triplet states driven by a combination of a rotating magnetic field and a weak bias field. Surprisingly we find that efficient polarisation transfer driven by a STORM (Singlet-Triplet Oscillations through Rotating Magnetic fields) pulse in the presence of $\mu$T bias fields requires rotation frequencies on the order of several kHz. The rotation frequencies therefore greatly exceed any of the internal frequencies of typical zero- to ultralow field experiments. We further show that the rotational direction of the rotating field is not arbitrary and greatly influences the final transfer efficiency. Some of these aspects are demonstrated experimentally by considering hyperpolarised (1-$^{13}$C)fumarate. In addition, we provide numerical simulations highlighting the resilience of the STORM pulse against disruptive quadrupolar coupling partners. In contrast to most of the existing methods, the STORM procedure therefore represents a promising candidate for quadrupolar decoupled polarisation transfer in PHIP experiments.

Published

2022

6. Low-Frequency Excitation of Singlet-Triplet Transitions. Application to Nuclear Hyperpolarization

Author

Dagys, Laurynas, Bengs, Christian, and Levitt, Malcolm H.

Subjects

Quantum Physics

Abstract

Coupled pairs of nuclear spins-1/2 support one singlet state and three triplet states. Transitions between the singlet state and one of the triplet states may be driven by an oscillating low-frequency magnetic field, in the presence of couplings to a third nuclear spin, and a weak bias magnetic field.This phenomenon allows the generation of strong nuclear hyperpolarization of ${}^{13}\mathrm{C}$ nuclei, starting from the nuclear singlet polarization of a ${}^{1}\mathrm{H}$ spin pair, associated with the enriched para spin isomer of hydrogen gas. Hyperpolarization is demonstrated for two molecular system.

Published

2021

7. Algorithmic Cooling of Nuclear Spin Pairs using a Long-Lived Singlet State

Author

Rodin, Bogdan A., Bengs, Christian, Brown, Lynda J., Sheberstov, Kirill F., Kiryutin, Alexey S., Brown, Richard C. D., Yurkovskaya, Alexandra V., Ivanov, Konstantin L., and Levitt, Malcolm H.

Subjects

Quantum Physics, Physics - Applied Physics, Physics - Chemical Physics

Abstract

Algorithmic cooling methods manipulate an open quantum system in order to lower its temperature below that of the environment. We show that significant cooling is achieved on an ensemble of spin-pair systems by exploiting the long-lived nuclear singlet state, which is an antisymmetric quantum superposition of the "up" and "down" qubit states. The effect is demonstrated by nuclear magnetic resonance (NMR) experiments on a molecular system containing a coupled pair of near-equivalent 13C nuclei. The populations of the system are subjected to a repeating sequence of cyclic permutations separated by relaxation intervals. The long-lived nuclear singlet order is pumped well beyond the unitary limit, and the nuclear magnetization is enhanced by 21% relative to its thermal equilibrium value. To our knowledge this is the first demonstration of algorithmic cooling using a quantum superposition state and without making a distinction between rapidly and slowly relaxing qubits., Comment: 22 pages, 6 figures

Published

2019

8. Spin-isomer conversion of water at room temperature, and quantum-rotor-induced nuclear polarization, in the water-endofullerene H$_2$O@C$_{60}$

Author

Meier, Benno, Kouřil, Karel, Bengs, Christian, Kouřilová, Hana, Barker, Timothy J., Elliott, Stuart J., Alom, Shamim, Whitby, Richard J., and Levitt, Malcolm H.

Subjects

Physics - Chemical Physics

Abstract

Water exists in two forms, para and ortho, that have nuclear spin states with different symmetries. Here we report the conversion of fullerene-encapsulated para-water to ortho-water. The enrichment of para-water at low temperatures is monitored via changes in the electrical polarizability of the material. Upon rapid dissolution of the material in toluene the excess para-water converts to ortho- water. In H$_2{}^{16}$O@C$_{60}$ the conversion leads to a slow increase in the NMR signal. In H$_2{}^{16}$O@C$_{60}$ the conversion gives rise to weak signal enhancements attributed to quantum-rotor-induced nuclear spin polarization. The time constants for the spin-isomer conversion of fullerene-encapsulated water in ambient temperature solution are estimated as 30$\pm$4 s for the $^{16}$O-isotopologue of water, and 16$\pm$3 s for the $^{17}$O isotopologue., Comment: 6 pages, 5 figures

Published

2018