Your search keyword '"Ransford, Anthony"' showing total 25 results

1. Measuring the Loschmidt amplitude for finite-energy properties of the Fermi-Hubbard model on an ion-trap quantum computer

Author

Hémery, Kévin, Ghanem, Khaldoon, Crane, Eleanor, Campbell, Sara L., Dreiling, Joan M., Figgatt, Caroline, Foltz, Cameron, Gaebler, John P., Johansen, Jacob, Mills, Michael, Moses, Steven A., Pino, Juan M., Ransford, Anthony, Rowe, Mary, Siegfried, Peter, Stutz, Russell P., Dreyer, Henrik, Schuckert, Alexander, and Nigmatullin, Ramil

Subjects

Quantum Physics

Abstract

Calculating the equilibrium properties of condensed matter systems is one of the promising applications of near-term quantum computing. Recently, hybrid quantum-classical time-series algorithms have been proposed to efficiently extract these properties from a measurement of the Loschmidt amplitude $\langle \psi| e^{-i \hat H t}|\psi \rangle$ from initial states $|\psi\rangle$ and a time evolution under the Hamiltonian $\hat H$ up to short times $t$. In this work, we study the operation of this algorithm on a present-day quantum computer. Specifically, we measure the Loschmidt amplitude for the Fermi-Hubbard model on a $16$-site ladder geometry (32 orbitals) on the Quantinuum H2-1 trapped-ion device. We assess the effect of noise on the Loschmidt amplitude and implement algorithm-specific error mitigation techniques. By using a thus-motivated error model, we numerically analyze the influence of noise on the full operation of the quantum-classical algorithm by measuring expectation values of local observables at finite energies. Finally, we estimate the resources needed for scaling up the algorithm., Comment: 18 pages, 12 figures

Published

2023

2. Non-Abelian Topological Order and Anyons on a Trapped-Ion Processor

Author

Iqbal, Mohsin, Tantivasadakarn, Nathanan, Verresen, Ruben, Campbell, Sara L., Dreiling, Joan M., Figgatt, Caroline, Gaebler, John P., Johansen, Jacob, Mills, Michael, Moses, Steven A., Pino, Juan M., Ransford, Anthony, Rowe, Mary, Siegfried, Peter, Stutz, Russell P., Foss-Feig, Michael, Vishwanath, Ashvin, and Dreyer, Henrik

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

Non-Abelian topological order (TO) is a coveted state of matter with remarkable properties, including quasiparticles that can remember the sequence in which they are exchanged. These anyonic excitations are promising building blocks of fault-tolerant quantum computers. However, despite extensive efforts, non-Abelian TO and its excitations have remained elusive, unlike the simpler quasiparticles or defects in Abelian TO. In this work, we present the first unambiguous realization of non-Abelian TO and demonstrate control of its anyons. Using an adaptive circuit on Quantinuum's H2 trapped-ion quantum processor, we create the ground state wavefunction of $D_4$ TO on a kagome lattice of 27 qubits, with fidelity per site exceeding $98.4\%$. By creating and moving anyons along Borromean rings in spacetime, anyon interferometry detects an intrinsically non-Abelian braiding process. Furthermore, tunneling non-Abelions around a torus creates all 22 ground states, as well as an excited state with a single anyon -- a peculiar feature of non-Abelian TO. This work illustrates the counterintuitive nature of non-Abelions and enables their study in quantum devices., Comment: 6 + 20 pages, 6 + 5 figures, 3 tables v2: Changed title, added a reference

Published

2023

3. Non-Abelian topological order and anyons on a trapped-ion processor

Author

Iqbal, Mohsin, Tantivasadakarn, Nathanan, Verresen, Ruben, Campbell, Sara L., Dreiling, Joan M., Figgatt, Caroline, Gaebler, John P., Johansen, Jacob, Mills, Michael, Moses, Steven A., Pino, Juan M., Ransford, Anthony, Rowe, Mary, Siegfried, Peter, Stutz, Russell P., Foss-Feig, Michael, Vishwanath, Ashvin, and Dreyer, Henrik

Published

2024

4. High fidelity state preparation and measurement of ion hyperfine qubits with I > 1/2

Author

An, Fangzhao Alex, Ransford, Anthony, Schaffer, Andrew, Sletten, Lucas R., Gaebler, John, Hostetter, James, and Vittorini, Grahame

Subjects

Quantum Physics

Abstract

We present a method for achieving high fidelity state preparation and measurement (SPAM) using trapped ion hyperfine qubits with nuclear spins higher than $I = 1/2$. The ground states of these higher nuclear spin isotopes do not afford a simple frequency-selective state preparation scheme. We circumvent this limitation by stroboscopically driving strong and weak transitions, blending fast optical pumping using dipole transitions and narrow microwave or optical quadrupole transitions. We demonstrate this method with the $I=3/2$ isotope $^{137}\mbox{Ba}^+$ to achieve a SPAM infidelity of $\left(9.0 \pm 1.3\right) \times 10^{-5}$ ($-40.5 \pm 0.6$ dB), facilitating the use of a wider range of ion isotopes with favorable wavelengths and masses for quantum computation., Comment: 5 pages, 4 figures

Published

2022

5. Weak dissipation for high fidelity qubit state preparation and measurement

Author

Ransford, Anthony, Roman, Conrad, Dellaert, Thomas, McMillin, Patrick, and Campbell, Wesley C.

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Highly state-selective, weakly dissipative population transfer is used to irreversibly move the population of one ground state qubit level of an atomic ion to an effectively stable excited manifold with high fidelity. Subsequent laser interrogation accurately distinguishes these electronic manifolds, and we demonstrate a total qubit state preparation and measurement (SPAM) inaccuracy $\epsilon_\mathrm{SPAM} < 1.7 \times 10^{-4}$ ($-38 \mbox{ dB}$), limited by imperfect population transfer between qubit eigenstates. We show experimentally that full transfer would yield an inaccuracy less than $8.0 \times 10^{-5}$ ($-41 \mbox{ dB}$). The high precision of this method revealed a rare ($\approx 10^{-4}$) magnetic dipole decay induced error that we demonstrate can be corrected by driving an additional transition. Since this technique allows fluorescence collection for effectively unlimited periods, high fidelity qubit SPAM is achievable even with limited optical access and low quantum efficiency., Comment: 5 pages, 4 figures

Published

2021

6. Hyperfine structure of $^{173}\mathrm{Yb}^+$: toward resolving the $^{173}\mathrm{Yb}$ nuclear octupole moment puzzle

Author

Xiao, Di, Li, Jiguang, Campbell, Wesley C., Dellaert, Thomas, McMillin, Patrick, Ransford, Anthony, Roman, Conrad, and Derevianko, Andrei

Subjects

Physics - Atomic Physics, Nuclear Theory

Abstract

Hyperfine structure (HFS) of atomic energy levels arises due to interactions of atomic electrons with a hierarchy of nuclear multipole moments, including magnetic dipole, electric quadrupole and higher rank moments. Recently, a determination of the magnetic octupole moment of the $^{173}\mathrm{Yb}$ nucleus was reported from HFS measurements in neutral ${}^{173}\mathrm{Yb}$ [PRA 87, 012512 (2013)], and is four orders of magnitude larger than the nuclear theory prediction. Considering this substantial discrepancy between the spectroscopically extracted value and nuclear theory, here we propose to use an alternative system to resolve this tension, a singly charged ion of the same $^{173}\mathrm{Yb}$ isotope. Utilizing the substantial suite of tools developed around $\mathrm{Yb}^+$ for quantum information applications, we propose to extract nuclear octupole and hexadecapole moments from measuring hyperfine splittings in the extremely long lived first excited state ($4f^{13}(^2\!F^{o})6s^2$, $J=7/2$) of $^{173}\mathrm{Yb}^+$. We present results of atomic structure calculations in support of the proposed measurements.

Published

2020

7. Coherent control for qubit state readout

Author

Roman, Conrad, Ransford, Anthony, Ip, Michael, and Campbell, Wesley C.

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

Short pulses from mode-locked lasers can produce background-free atomic fluorescence by allowing temporal separation of the prompt incidental scatter from the subsequent atomic emission. We use this to improve quantum state detection of optical-frequency and electron-shelved trapped ion qubits by more than 2 orders of magnitude. For direct detection of qubits defined on atomic hyperfine structure, however, the large bandwidth of short pulses is greater than the hyperfine splitting, and repeated excitation is not qubit state selective. Here, we show that the state resolution needed for projective quantum measurement of hyperfine qubits can be recovered by applying techniques from coherent control to the orbiting valence electron of the queried ion. We demonstrate electron wavepacket interference to allow readout of the original qubit state using broadband pulses, even in the presence of large amounts of background laser scatter., Comment: 7 pages, 3 figures

Published

2019

8. Hyperfine structure of Yb-173(+): Toward resolving the Yb-173 nuclear-octupole-moment puzzle

Author

Xiao, Di, Li, Jiguang, Campbell, Wesley C, Dellaert, Thomas, McMillin, Patrick, Ransford, Anthony, Roman, Conrad, and Derevianko, Andrei

Subjects

physics.atom-ph, nucl-th

Abstract

Hyperfine structure (HFS) of atomic energy levels arises due to interactionsof atomic electrons with a hierarchy of nuclear multipole moments, includingmagnetic dipole, electric quadrupole and higher rank moments. Recently, adetermination of the magnetic octupole moment of the $^{173}\mathrm{Yb}$nucleus was reported from HFS measurements in neutral ${}^{173}\mathrm{Yb}$[PRA 87, 012512 (2013)], and is four orders of magnitude larger than thenuclear theory prediction. Considering this substantial discrepancy between thespectroscopically extracted value and nuclear theory, here we propose to use analternative system to resolve this tension, a singly charged ion of the same$^{173}\mathrm{Yb}$ isotope. Utilizing the substantial suite of tools developedaround $\mathrm{Yb}^+$ for quantum information applications, we propose toextract nuclear octupole and hexadecapole moments from measuring hyperfinesplittings in the extremely long lived first excited state($4f^{13}(^2\!F^{o})6s^2$, $J=7/2$) of $^{173}\mathrm{Yb}^+$. We presentresults of atomic structure calculations in support of the proposedmeasurements.

Published

2020

9. Hyperfine structure of Yb+173: Toward resolving the Yb173 nuclear-octupole-moment puzzle

Author

Xiao, Di, Li, Jiguang, 李冀光, Campbell, Wesley C, Dellaert, Thomas, McMillin, Patrick, Ransford, Anthony, Roman, Conrad, and Derevianko, Andrei

Subjects

Affordable and Clean Energy, physics.atom-ph, nucl-th, Mathematical Sciences, Physical Sciences, Chemical Sciences, General Physics

Abstract

Hyperfine structure (HFS) of atomic energy levels arises due to interactionsof atomic electrons with a hierarchy of nuclear multipole moments, includingmagnetic dipole, electric quadrupole and higher rank moments. Recently, adetermination of the magnetic octupole moment of the $^{173}\mathrm{Yb}$nucleus was reported from HFS measurements in neutral ${}^{173}\mathrm{Yb}$[PRA 87, 012512 (2013)], and is four orders of magnitude larger than thenuclear theory prediction. Considering this substantial discrepancy between thespectroscopically extracted value and nuclear theory, here we propose to use analternative system to resolve this tension, a singly charged ion of the same$^{173}\mathrm{Yb}$ isotope. Utilizing the substantial suite of tools developedaround $\mathrm{Yb}^+$ for quantum information applications, we propose toextract nuclear octupole and hexadecapole moments from measuring hyperfinesplittings in the extremely long lived first excited state($4f^{13}(^2\!F^{o})6s^2$, $J=7/2$) of $^{173}\mathrm{Yb}^+$. We presentresults of atomic structure calculations in support of the proposedmeasurements.

Published

2020

10. Coherent control for qubit state readout

Author

Roman, Conrad, Ransford, Anthony, Ip, Michael, and Campbell, Wesley C

Subjects

coherent control, quantum information, trapped ions, Fluids & Plasmas, Physical Sciences

Published

2020

11. Phonon lasing from optical frequency comb illumination of a trapped ion

Author

Ip, Michael, Ransford, Anthony, Jayich, Andrew M., Long, Xueping, Roman, Conrad, and Campbell, Wesley C.

Subjects

Physics - Atomic Physics

Abstract

An atomic transition can be addressed by a single tooth of an optical frequency comb if the excited state lifetime ($\tau$) is significantly longer than the pulse repetition period ($T_\mathrm{r}$). In the crossover regime between fully-resolved and unresolved comb teeth ($\tau \lessapprox T_\mathrm{r}$), we observe Doppler cooling of a pre-cooled trapped atomic ion by a single tooth of a frequency-doubled optical frequency comb. We find that for initially hot ions, a multi-tooth effect gives rise to lasing of the ion's harmonic motion in the trap, verified by acoustic injection locking. The gain saturation of this phonon laser action leads to a comb of steady-state oscillation amplitudes, allowing hot ions to be loaded directly into the trap and laser cooled to crystallization despite the presence of hundreds of blue-detuned teeth., Comment: 5 pages, 4 figures

Published

2017

12. Displacement operators: the classical face of their quantum phase

Author

Vutha, Amar C., Bohr, Eliot A., Ransford, Anthony, Campbell, Wesley C., and Hamilton, Paul

Subjects

Quantum Physics, Physics - Atomic Physics, Physics - Physics Education

Abstract

In quantum mechanics, the operator representing the displacement of a system in position or momentum is always accompanied by a path-dependent phase factor. In particular, two non-parallel displacements in phase space do not compose together in a simple way, and the order of these displacements leads to different displacement composition phase factors. These phase factors are often attributed to the nonzero commutator between quantum position and momentum operators, but such a mathematical explanation might be unsatisfactory to students who are after more physical insight. We present a couple of simple demonstrations, using classical wave mechanics and classical particle mechanics, that provide some physical intuition for the phase associated with displacement operators., Comment: 14 pages, 4 figures, reorganized and reformatted

Published

2017

13. Phonon Lasing from Optical Frequency Comb Illumination of Trapped Ions

Author

Ip, Michael, Ransford, Anthony, Jayich, Andrew M, Long, Xueping, Roman, Conrad, and Campbell, Wesley C

Subjects

physics.atom-ph, Mathematical Sciences, Physical Sciences, Engineering, General Physics

Abstract

We demonstrate the use of a frequency-doubled optical frequency comb to load, cool, and crystallize trapped atomic ions as an alternative to ultraviolet (UV) or even deep UV continuous-wave lasers. We find that the Doppler shift from the atom's oscillation in the trap, driven by the blue-detuned comb teeth, introduces additional cooling and amplification which gives rise to steady-state phonon lasing of the ion's harmonic motion in the trap. The phonon laser's gain saturation keeps the optical frequency comb from continually adding energy without bound. This protection allows us to demonstrate loading and crystallization of hot ions directly with the comb, eliminating the need for a continuous-wave cooling laser, a technique that is extendable to the deep UV.

Published

2018

14. Achieving translational symmetry in trapped cold ion rings

Author

Li, Hao-Kun, Urban, Erik, Noel, Crystal, Chuang, Alexander, Xia, Yang, Ransford, Anthony, Hemmerling, Boerge, Wang, Yuan, Li, Tongcang, Haeffner, Hartmut, and Zhang, Xiang

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics

Abstract

Spontaneous symmetry breaking is a universal concept throughout science. For instance, the Landau-Ginzburg paradigm of translational symmetry breaking underlies the classification of nearly all quantum phases of matter and explains the emergence of crystals, insulators, and superconductors. Usually, the consequences of translational invariance are studied in large systems to suppress edge effects which cause undesired symmetry breaking. While this approach works for investigating global properties, studies of local observables and their correlations require access and control of the individual constituents. Periodic boundary conditions, on the other hand, could allow for translational symmetry in small systems where single particle control is achievable. Here, we crystallize up to fifteen 40Ca+ ions in a microscopic ring with inherent periodic boundary conditions. We show the ring's translational symmetry is preserved at millikelvin temperatures by delocalizing the Doppler laser cooled ions. This establishes an upper bound for undesired symmetry breaking at a level where quantum control becomes feasible. These findings pave the way towards studying quantum many-body physics with translational symmetry at the single particle level in a variety of disciplines from simulation of Hawking radiation to exploration of quantum phase transitions., Comment: 15 pages, 4 figures

Published

2016

15. Realization of Translational Symmetry in Trapped Cold Ion Rings.

Author

Li, Hao-Kun, Urban, Erik, Noel, Crystal, Chuang, Alexander, Xia, Yang, Ransford, Anthony, Hemmerling, Boerge, Wang, Yuan, Li, Tongcang, Häffner, Hartmut, and Zhang, Xiang

Subjects

quant-ph, cond-mat.mes-hall, physics.atom-ph, Mathematical Sciences, Physical Sciences, Engineering, General Physics

Abstract

We crystallize up to 15 ^{40}Ca^{+} ions in a ring with a microfabricated silicon surface Paul trap. Delocalization of the Doppler laser-cooled ions shows that the translational symmetry of the ion ring is preserved at millikelvin temperatures. By characterizing the collective motion of the ion crystals, we identify homogeneous electric fields as the dominant symmetry-breaking mechanism at this energy scale. With increasing ion numbers, such detrimental effects are reduced. We predict that, with only a ten-ion ring, uncompensated homogeneous fields will not break the translational symmetry of the rotational ground state. This experiment opens a door towards studying quantum many-body physics with translational symmetry at the single-particle level.

Published

2017

16. Old Dog, New Trick: High Fidelity, Background-free State Detection of an Ytterbium Ion Qubit

Author

Ransford, Anthony M

Subjects

Atomic physics, F state, fidelity, metastable, shelving, ultrafast, ytterbium

Abstract

The highly popular ytterbium-171 ($^{171} \mathrm{Yb}^+$) ion is commonly employed in quantum information research as a qubit whose excellent coherence time and fast, simple state preparation has allowed cutting edge work in quantum computation and simulation. Despite these large benefits, the demonstrated measurement fidelity of this ion has lagged the state preparation and gate fidelity achieved to date.In this thesis we investigate and realize methods of increasing the measurement fidelity of $^{171} \mathrm{Yb}^+$ in a scaleable way for large quantum systems. Using methods of coherent control, we implement a pulsed state detection scheme using a mode-locked laser to perform background-free spectroscopy of the ``bright'' state of the qubit. The small hyperfine splitting of the ion necessitates the use of multiple (two) pulses to manipulate time dynamics of the ion to excite a single transition. A Mach-Zehnder interferometer is constructed to control these pulse separations both coarsely ($\sim$ 237 ps) and on a fine sub-femtosecond scale. These pulses cause destructive/constructive interference of the electron wave packet of a single ion levitated in vacuum and are engineered to state-selectively excite the qubit. This allows measurement of the qubit whose transition frequency is much smaller than the bandwidth of the interrogation laser.During this spectroscopy, mechanical forces from the mode-locked laser frequency comb can drive the ion into large coherent states of motion. This motion has been dubbed ``phonon lasing''. We investigate the phonon lasing affect and how the ion interacts with multiple comb teeth. The large number of teeth leads to a protection mechanism from runaway energy gain by near-by blue detuned teeth, allowing ions to be trapped and cooled by the mode-locked laser, regardless of its detuning. We further explore these discrete amplitude coherent states by injecting energy into the ion's motion and exciting higher-order oscillations.We, for the first time, implement an ``electron shelving'' of the hyperfine qubit, and incoherently transfer the bright state population in the extremely long-lived ($\approx$5 yr) $^2$F$_{7/2}$ state of $^{171}$Yb$^+$, functionally disconnected state. This is accomplished via narrow-band optical pumping on the $^2$S$_{1/2}$ to the $^2$D$_{5/2}$ quadrupole which has a leaky dipole channel into the $^2$F$_{7/2}$. Narrow-band optical pumping is again used to rescue the ion at the end of the experiment with the aid of a 760 nm E2 transition back into the cooling cycle. Measurement with this scheme is no longer limited by off-resonant effects from the main cycling transition. Limits of this novel technique, as well as further directions using the F state as a utility for quantum information are explored. Finally, we combine the pulsed background-free spectroscopy with shelving and demonstrate high-fidelity, background free detection of a single trapped $^{171}\mathrm{Yb}^+$ qubit.

Published

2020

17. Supporting Data for 'Creation of Non-Abelian Topological Order and Anyons on a Trapped-Ion Processor'

Author

Iqbal, Mohsin, Tantivasadakarn, Nathanan, Verresen, Ruben, Campbell, Sara, Dreiling, Joan, Figgatt, Caroline, Gaebler, John, Johansen, Jacob, Mills, Michael, Pino, Juan, Ransford, Anthony, Rowe, Mary, Siegfried, Peter, Stutz, Russell, Foss-Feig, Michael, Vishwanath, Ashvin, and Dreyer, Henrik

Abstract

Supporting data for experiment codenamedD4H2. Will be made available on May 9th 2023.

Published

2023

18. Creation of Non-Abelian Topological Order and Anyons on a Trapped-Ion Processor

Author

Iqbal, Mohsin, Tantivasadakarn, Nathanan, Verresen, Ruben, Campbell, Sara L., Dreiling, Joan M., Figgatt, Caroline, Gaebler, John P., Johansen, Jacob, Mills, Michael, Moses, Steven A., Pino, Juan M., Ransford, Anthony, Rowe, Mary, Siegfried, Peter, Stutz, Russell P., Foss-Feig, Michael, Vishwanath, Ashvin, and Dreyer, Henrik

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Strongly Correlated Electrons (cond-mat.str-el), FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

Non-Abelian topological order (TO) is a coveted state of matter with remarkable properties, including quasiparticles that can remember the sequence in which they are exchanged. These anyonic excitations are promising building blocks of fault-tolerant quantum computers. However, despite extensive efforts, non-Abelian TO and its excitations have remained elusive, unlike the simpler quasiparticles or defects in Abelian TO. In this work, we present the first unambiguous realization of non-Abelian TO and demonstrate control of its anyons. Using an adaptive circuit on Quantinuum's H2 trapped-ion quantum processor, we create the ground state wavefunction of $D_4$ TO on a kagome lattice of 27 qubits, with fidelity per site exceeding $98.4\%$. By creating and moving anyons along Borromean rings in spacetime, anyon interferometry detects an intrinsically non-Abelian braiding process. Furthermore, tunneling non-Abelions around a torus creates all 22 ground states, as well as an excited state with a single anyon -- a peculiar feature of non-Abelian TO. This work illustrates the counterintuitive nature of non-Abelions and enables their study in quantum devices., 6 + 20 pages, 6 + 5 figures, 3 tables

Published

2023

19. High Fidelity State Preparation and Measurement of Ion Hyperfine Qubits with I>12

Author

An, Fangzhao Alex, primary, Ransford, Anthony, additional, Schaffer, Andrew, additional, Sletten, Lucas R., additional, Gaebler, John, additional, Hostetter, James, additional, and Vittorini, Grahame, additional

Published

2022

20. Fast Loading of a Trapped Ion Quantum Computer Using a 2D Magneto-Optical Trap

Author

Johansen, Jacob, primary, Estey, Brian, additional, Rowe, Mary, additional, and Ransford, Anthony, additional

Published

2022

21. High fidelity state preparation and measurement of ion qubits with spin I > ½

Author

Schaffer, Andrew, primary, An, Fangzhao Alex, additional, Ransford, Anthony, additional, Sletten, Lucas R., additional, Gaebler, John, additional, Hostetter, James, additional, and Vittorini, Grahame, additional

Published

2022

22. Weak dissipation for high-fidelity qubit-state preparation and measurement

Author

Ransford, Anthony, primary, Roman, Conrad, additional, Dellaert, Thomas, additional, McMillin, Patrick, additional, and Campbell, Wesley C., additional

Published

2021

23. Background free high fidelity state preparation and measurement (SPAM) in a 171Yb+ qubit (Conference Presentation)

Author

Roman, Conrad, primary, Ransford, Anthony, additional, Ip, Michael, additional, and Campbell, Wesley C., additional

Published

2020

24. Displacement operators: the classical face of their quantum phase

Author

Vutha, Amar C, primary, Bohr, Eliot A, additional, Ransford, Anthony, additional, Campbell, Wesley C, additional, and Hamilton, Paul, additional

Published

2018

25. Realization of Translational Symmetry in Trapped Cold Ion Rings.

Author

Hao-Kun Li, Erik Urban, Noel, Crystal, Chuang, Alexander, Yang Xia, Ransford, Anthony, Hemmerling, Boerge, Yuan Wang, Tongcang Li, Häffner, Hartmut, and Xiang Zhang

Subjects

*ION traps, *MICROFABRICATION, *TRANSLATIONAL symmetry

Abstract

We crystallize up to 15 40Ca+ ions in a ring with a microfabricated silicon surface Paul trap. Delocalization of the Doppler laser-cooled ions shows that the translational symmetry of the ion ring is preserved at millikelvin temperatures. By characterizing the collective motion of the ion crystals, we identify homogeneous electric fields as the dominant symmetry-breaking mechanism at this energy scale. With increasing ion numbers, such detrimental effects are reduced. We predict that, with only a ten-ion ring, uncompensated homogeneous fields will not break the translational symmetry of the rotational ground state. This experiment opens a door towards studying quantum many-body physics with translational symmetry at the single-particle level. [ABSTRACT FROM AUTHOR]

Published

2017