Your search keyword '"Katherine C. McCormick"' showing total 6 results

1. Feshbach Resonances in p-Wave Three-Body Recombination within Fermi-Fermi Mixtures of Open-Shell ^{6}Li and Closed-Shell ^{173}Yb Atoms

Author

Alaina Green, Hui Li, Jun Hui See Toh, Xinxin Tang, Katherine C. McCormick, Ming Li, Eite Tiesinga, Svetlana Kotochigova, and Subhadeep Gupta

Subjects

Physics, QC1-999

Abstract

We report on the observation of magnetic Feshbach resonances in a Fermi-Fermi mixture of ultracold atoms with extreme mass imbalance and on their unique p-wave dominated three-body recombination processes. Our system consists of open-shell alkali-metal ^{6}Li and closed-shell ^{173}Yb atoms, both spin polarized and held at various temperatures between 1 and 20 μK. We confirm that Feshbach resonances in this system are solely the result of a weak separation-dependent hyperfine coupling between the electronic spin of ^{6}Li and the nuclear spin of ^{173}Yb. Our analysis also shows that three-body recombination rates are controlled by the identical fermion nature of the mixture, even in the presence of s-wave collisions between the two species and with recombination rate coefficients outside the Wigner threshold regime at our lowest temperature. Specifically, a comparison of experimental and theoretical line shapes of the recombination process indicates that the characteristic asymmetric line shape as a function of applied magnetic field and a maximum recombination rate coefficient that is independent of temperature can only be explained by triatomic collisions with nonzero, p-wave total orbital angular momentum. The resonances can be used to form ultracold doublet ground-state molecules and to simulate quantum superfluidity in mass-imbalanced mixtures.

Published

2020

2. Quantum-enhanced sensing of a single-ion mechanical oscillator

Author

David J. Wineland, Jonas Keller, Katherine C. McCormick, S. C. Burd, Andrew C. Wilson, and Dietrich Leibfried

Subjects

Physics, Multidisciplinary, Quantum decoherence, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Article, Fock state, Quantum state, Quantum mechanics, 0103 physical sciences, Coherent states, Heisenberg limit, Sensitivity (control systems), Atomic physics, 010306 general physics, 0210 nano-technology, Ground state, Harmonic oscillator

Abstract

The use of special quantum states to achieve sensitivities below the limits established by classically behaving states has enjoyed immense success since its inception. In bosonic interferometers, squeezed states, number states and cat states have been implemented on various platforms and have demonstrated improved measurement precision over interferometers based on coherent states. Another metrologically useful state is an equal superposition of two eigenstates with maximally different energies; this state ideally reaches the full interferometric sensitivity allowed by quantum mechanics. By leveraging improvements to our apparatus made primarily to reach higher operation fidelities in quantum information processing, we extend a technique to create number states up to $n=100$ and to generate superpositions of a harmonic oscillator ground state and a number state of the form $\textstyle{\frac{1}{\sqrt{2}}}(\lvert 0\rangle+\lvert n\rangle)$ with $n$ up to 18 in the motion of a single trapped ion. While experimental imperfections prevent us from reaching the ideal Heisenberg limit, we observe enhanced sensitivity to changes in the oscillator frequency that initially increases linearly with $n$, with maximal value at $n=12$ where we observe 3.2(2) dB higher sensitivity compared to an ideal measurement on a coherent state with the same average occupation number. The quantum advantage from using number-state superpositions can be leveraged towards precision measurements on any harmonic oscillator system; here it enables us to track the average fractional frequency of oscillation of a single trapped ion to approximately 2.6 $\times$ 10$^{-6}$ in 5 s. Such measurements should provide improved characterization of imperfections and noise on trapping potentials, which can lead to motional decoherence, a leading source of error in quantum information processing with trapped ions.

Published

2019

3. Quantum harmonic oscillator spectrum analyzers

Author

Katherine C. McCormick, Daniel C. Cole, P.-Y. Hou, Jonas Keller, Stephen Erickson, Dietrich Leibfried, Jenny J. Wu, and Andrew C. Wilson

Subjects

Physics, Spectrum analyzer, Quantum Physics, Measure (physics), General Physics and Astronomy, Resonance, FOS: Physical sciences, 01 natural sciences, Noise (electronics), Amplitude, Quantum harmonic oscillator, Qubit, Quantum electrodynamics, 0103 physical sciences, 010306 general physics, Quantum Physics (quant-ph), Harmonic oscillator

Abstract

Characterization and suppression of noise are essential for the control of harmonic oscillators in the quantum regime. We measure the noise spectrum of a quantum harmonic oscillator from low frequency to near the oscillator resonance by sensing its response to amplitude modulated periodic drives with a qubit. Using the motion of a trapped ion, we experimentally demonstrate two different implementations with combined sensitivity to noise from 500 Hz to 600 kHz. We apply our method to measure the intrinsic noise spectrum of an ion trap potential in a previously unaccessed frequency range., 6 + 10 pages, 4 + 7 figures

Published

2020

4. Feshbach Resonances in p -Wave Three-Body Recombination within Fermi-Fermi Mixtures of Open-Shell Li6 and Closed-Shell Yb173 Atoms

Author

Ming Li, Xinxin Tang, Hui Li, Alaina Green, Jun Hui See Toh, Eite Tiesinga, Subhadeep Gupta, Katherine C. McCormick, and Svetlana Kotochigova

Subjects

Condensed Matter::Quantum Gases, Physics, Angular momentum, Triatomic molecule, General Physics and Astronomy, Fermion, 01 natural sciences, 010305 fluids & plasmas, Magnetic field, Superfluidity, Ultracold atom, 0103 physical sciences, Atomic physics, 010306 general physics, Spin (physics), Open shell

Abstract

We report on the observation of magnetic Feshbach resonances in a Fermi-Fermi mixture of ultracold atoms with extreme mass imbalance and on their unique p-wave dominated three-body recombination processes. Our system consists of open-shell alkali-metal 6Li and closed-shell 173Yb atoms, both spin polarized and held at various temperatures between 1 and 20 μK. We confirm that Feshbach resonances in this system are solely the result of a weak separation-dependent hyperfine coupling between the electronic spin of 6Li and the nuclear spin of 173Yb. Our analysis also shows that three-body recombination rates are controlled by the identical fermion nature of the mixture, even in the presence of s-wave collisions between the two species and with recombination rate coefficients outside the Wigner threshold regime at our lowest temperature. Specifically, a comparison of experimental and theoretical line shapes of the recombination process indicates that the characteristic asymmetric line shape as a function of applied magnetic field and a maximum recombination rate coefficient that is independent of temperature can only be explained by triatomic collisions with nonzero, p-wave total orbital angular momentum. The resonances can be used to form ultracold doublet ground-state molecules and to simulate quantum superfluidity in mass-imbalanced mixtures.

Published

2020

5. State Readout of a Trapped Ion Qubit Using a Trap-Integrated Superconducting Photon Detector

Author

Susanna Todaro, Andrew C. Wilson, R. P. Mirin, Varun B. Verma, David J. Wineland, Daniel H. Slichter, Dietrich Leibfried, Sae Woo Nam, Katherine C. McCormick, and David Allcock

Subjects

Physics, Quantum Physics, Photon, Physics::Instrumentation and Detectors, Atomic Physics (physics.atom-ph), Condensed Matter - Superconductivity, Detector, General Physics and Astronomy, Physics::Optics, FOS: Physical sciences, 01 natural sciences, Ion, Physics - Atomic Physics, Optical pumping, Superconductivity (cond-mat.supr-con), Qubit, 0103 physical sciences, Quantum efficiency, Ion trap, Atomic physics, 010306 general physics, Quantum Physics (quant-ph), Hyperfine structure

Abstract

We report high-fidelity state readout of a trapped ion qubit using a trap-integrated photon detector. We determine the hyperfine qubit state of a single $^9$Be$^+$ ion held in a surface-electrode rf ion trap by counting state-dependent ion fluorescence photons with a superconducting nanowire single-photon detector (SNSPD) fabricated into the trap structure. The average readout fidelity is 0.9991(1), with a mean readout duration of 46 $\mu$s, and is limited by the polarization impurity of the readout laser beam and by off-resonant optical pumping. Because there are no intervening optical elements between the ion and the detector, we can use the ion fluorescence as a self-calibrated photon source to determine the detector quantum efficiency and its dependence on photon incidence angle and polarization., Comment: 15 pages, 11 figures, including supplemental material

Published

2020

6. Coherently displaced oscillator quantum states of a single trapped atom

Author

Jonas Keller, Dietrich Leibfried, Andrew C. Wilson, Katherine C. McCormick, and David J. Wineland

Subjects

Physics, Quantum Physics, Physics and Astronomy (miscellaneous), Sideband, Atomic Physics (physics.atom-ph), Materials Science (miscellaneous), FOS: Physical sciences, Atomic and Molecular Physics, and Optics, Physics - Atomic Physics, Quantum state, Atom, Coherent states, Electrical and Electronic Engineering, Atomic physics, Quantum Physics (quant-ph), Quantum, Excitation, Noise (radio), Harmonic oscillator

Abstract

Coherently displaced harmonic oscillator number states of a harmonically bound ion can be coupled to two internal states of the ion by a laser-induced motional sideband interaction. The internal states can subsequently be read out in a projective measurement via state-dependent fluorescence, with near-unit fidelity. This leads to a rich set of line shapes when recording the internal-state excitation probability after a sideband excitation, as a function of the frequency detuning of the displacement drive with respect to the ion's motional frequency. We precisely characterize the coherent displacement based on the resulting line shapes, which exhibit sharp features that are useful for oscillator frequency determination from the single quantum regime up to very large coherent states with average occupation numbers of several hundred. We also introduce a technique based on multiple coherent displacements and free precession for characterizing noise on the trapping potential in the frequency range of 500 Hz to 400 kHz. Signals from the ion are directly used to find and eliminate sources of technical noise in this typically unaccessed part of the spectrum.

Published

2018