Your search keyword '"Haeffner, Hartmut"' showing total 92 results

1. Temporally multiplexed ion-photon quantum interface via fast ion-chain transport

Author

You, Bingran, Wu, Qiming, Miron, David, Ke, Wenjun, Monga, Inder, Saglamyurek, Erhan, and Haeffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

High-rate remote entanglement between photon and matter-based qubits is essential for distributed quantum information processing. A key technique to increase the modest entangling rates of existing long-distance quantum networking approaches is multiplexing. Here, we demonstrate a temporally multiplexed ion-photon interface via rapid transport of a chain of nine calcium ions across 74 $\mathrm{\mu m}$ within 86 $\mathrm{\mu s}$. The non-classical nature of the multiplexed photons is verified by measuring the second-order correlation function with an average value of $g^{(2)}(0)$ = 0.060(13), indicating negligible crosstalk between the multiplexed modes. In addition, we characterize the motional degree-of-freedom of the ion crystal after transport and find that it is coherently excited to as much as $\bar{n}_\alpha\approx 110$ for the center-of-mass mode. Our proof-of-principle implementation paves the way for large-scale quantum networking with trapped ions, but highlights some challenges that must be overcome., Comment: 6 pages, 4 figures

Published

2024

2. Systematic study of rotational decoherence with a trapped-ion planar rotor

Author

Glikin, Neil, Stickler, Benjamin A., Tollefsen, Ryan, Mouradian, Sara, Yadav, Neha, Urban, Erik, Hornberger, Klaus, and Haeffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Quantum rotors promise unique advantages for quantum sensing, quantum simulation, and quantum information processing. At present, a variety of systems ranging from nanoparticles to single molecules and trapped ions have demonstrated detection and control of rotational motion in and near the quantum regime. For future applications of quantum rotors, understanding their dynamics in the presence of ambient environments and decoherence will be critical. While other model quantum systems such as the harmonic oscillator have seen extensive experimental study of their decoherence dynamics, such experiments remain an open task for the rigid rotor. We present measurements of fundamental scaling relationships for decoherence of a quantum planar rotor realized with two trapped ions, and find excellent agreement with recent theoretical work., Comment: 9 pages + supplementary information, 3 + 4 figures

Published

2023

3. 3D-Printed Micro Ion Trap Technology for Scalable Quantum Information Processing

Author

Xu, Shuqi, Xia, Xiaoxing, Yu, Qian, Khan, Sumanta, Megidish, Eli, You, Bingran, Hemmerling, Boerge, Jayich, Andrew, Biener, Juergen, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Trapped-ion applications, such as in quantum information, precision measurements, optical clocks, and mass spectrometry, rely on specialized high-performance ion traps. The latter applications typically employ traditional machining to customize macroscopic 3D Paul traps, while quantum information processing experiments usually rely on photo-lithographic techniques to miniaturize the traps and meet scalability requirements. Using photolithography, however, it is challenging to fabricate the complex three-dimensional electrode structures required for optimal confinement. Here we address these limitations by adopting a high-resolution 3D printing technology based on two-photon polymerization supporting fabrication of large arrays of high-performance miniaturized 3D traps. We show that 3D-printed ion traps combine the advantages of traditionally machined 3D traps with the miniaturization provided by photolithography by confining single calcium ions in a small 3D-printed ion trap with radial trap frequencies ranging from 2 MHz to 24 MHz. The tight confinement eases ion cooling requirements and allows us to demonstrate high-fidelity coherent operations on an optical qubit after only Doppler cooling. With 3D printing technology, the design freedom is drastically expanded without sacrificing scalability and precision so that ion trap geometries can be optimized for higher performance and better functionality.

Published

2023

4. Test of Causal Non-Linear Quantum Mechanics by Ramsey Interferometry on the Vibrational Mode of a Trapped Ion

Author

Broz, Joseph, You, Bingran, Khan, Sumanta, Haeffner, Hartmut, Kaplan, David E., and Rajendran, Surjeet

Subjects

Quantum Physics

Abstract

Kaplan and Rajendran have recently demonstrated that non-linear and state-dependent terms can be consistently added to quantum field theory to yield causal non-linear time evolution in quantum mechanics. Causal non-linear theories have the unavoidable feature that their quantum effects are dramatically sensitive to the full physical spread of the quantum state of the system. As a result, such theories are not well tested by conventional atomic and nuclear spectroscopy. By using a well-controlled superposition of vibrational modes of a $^{40}$Ca$^+$ ion trapped in a harmonic potential, we set a stringent limit of $5.4\times 10^{-12}$ on the magnitude of the unitless scaling factor $\tilde{\epsilon}_{\gamma}$ for the predicted causal, non-linear perturbation.

Published

2022

5. Sample-efficient verification of continuously-parameterized quantum gates for small quantum processors

Author

Shaffer, Ryan, Ren, Hang, Dyrenkova, Emiliia, Yale, Christopher G, Lobser, Daniel S, Burch, Ashlyn D, Chow, Matthew NH, Revelle, Melissa C, Clark, Susan M, and Haeffner, Hartmut

Subjects

Mathematical sciences, Physical sciences

Published

2023

6. Sample-efficient verification of continuously-parameterized quantum gates for small quantum processors

Author

Shaffer, Ryan, Ren, Hang, Dyrenkova, Emiliia, Yale, Christopher G., Lobser, Daniel S., Burch, Ashlyn D., Chow, Matthew N. H., Revelle, Melissa C., Clark, Susan M., and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

Most near-term quantum information processing devices will not be capable of implementing quantum error correction and the associated logical quantum gate set. Instead, quantum circuits will be implemented directly using the physical native gate set of the device. These native gates often have a parameterization (e.g., rotation angles) which provide the ability to perform a continuous range of operations. Verification of the correct operation of these gates across the allowable range of parameters is important for gaining confidence in the reliability of these devices. In this work, we demonstrate a procedure for sample-efficient verification of continuously-parameterized quantum gates for small quantum processors of up to approximately 10 qubits. This procedure involves generating random sequences of randomly-parameterized layers of gates chosen from the native gate set of the device, and then stochastically compiling an approximate inverse to this sequence such that executing the full sequence on the device should leave the system near its initial state. We show that fidelity estimates made via this technique have a lower variance than fidelity estimates made via cross-entropy benchmarking. This provides an experimentally-relevant advantage in sample efficiency when estimating the fidelity loss to some desired precision. We describe the experimental realization of this technique using continuously-parameterized quantum gate sets on a trapped-ion quantum processor from Sandia QSCOUT and a superconducting quantum processor from IBM Q, and we demonstrate the sample efficiency advantage of this technique both numerically and experimentally., Comment: 29 pages, 12 figures. This manuscript supersedes arXiv:2101.04474

Published

2022

7. Quantum simulation of weak-field light-matter interactions

Author

Young, Steve M., Häffner, Hartmut, and Sarovar, Mohan

Subjects

Quantum Physics, Physics - Optics

Abstract

Simulation of the interaction of light with matter, including at the few-photon level, is important for understanding the optical and optoelectronic properties of materials, and for modeling next-generation non-linear spectroscopies that use entangled light. At the few-photon level the quantum properties of the electromagnetic field must be accounted for with a quantized treatment of the field, and then such simulations quickly become intractable, especially if the matter subsystem must be modeled with a large number of degrees of freedom, as can be required to accurately capture many-body effects and quantum noise sources. Motivated by this we develop a quantum simulation framework for simulating such light-matter interactions on platforms with controllable bosonic degrees of freedom, such as vibrational modes in the trapped ion platform. The key innovation in our work is a scheme for simulating interactions with a continuum field using only a few discrete bosonic modes, which is enabled by a Green's function (response function) formalism. We develop the simulation approach, sketch how the simulation can be performed using trapped ions, and then illustrate the method with numerical examples. Our work expands the reach of quantum simulation to important light-matter interaction models and illustrates the advantages of extracting dynamical quantities such as response functions from quantum simulations.

Published

2021

8. Feasibility study of quantum computing using trapped electrons

Author

Yu, Qian, Alonso, Alberto M., Caminiti, Jackie, Beck, Kristin M., Sutherland, R. Tyler, Leibfried, Dietrich, Rodriguez, Kayla J., Dhital, Madhav, Hemmerling, Boerge, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We investigate the feasibility of using electrons in a linear Paul trap as qubits in a future quantum computer. We discuss the necessary experimental steps to realize such a device through a concrete design proposal, including trapping, cooling, electronic detection, spin readout and single and multi-qubit gate operations. Numeric simulations indicate that two-qubit Bell-state fidelities of order 99.99% can be achieved assuming reasonable experimental parameters.

Published

2021

9. One- and two-qubit gate infidelities due to motional errors in trapped ions and electrons

Author

Sutherland, R. Tyler, Yu, Qian, Beck, Kristin M., and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

In this work, we derive analytic formulae that determine the effect of error mechanisms on one- and two-qubit gates in trapped ions and electrons. First, we analyze, and derive expressions for, the effect of driving field inhomogeneities on one-qubit gate fidelities. Second, we derive expressions for two-qubit gate errors, including static motional frequency shifts, trap anharmonicities, field inhomogeneities, heating, and motional dephasing. We show that, for small errors, each of our expressions for infidelity converges to its respective numerical simulation; this shows our formulae are sufficient for determining error budgets for high-fidelity gates, obviating numerical simulations in future projects. All of the derivations are general to any internal qubit state, and any mixed state of the ion crystal's motion that is diagonal in the Fock state basis. Our treatment of static motional frequency shifts, trap anharmonicities, heating, and motional dephasing apply to both laser-based and laser-free gates, while our treatment of field imhomogenieties applies to laser-free systems.

Published

2021

10. Coupling two laser-cooled ions via a room-temperature conductor

Author

An, Da, Alonso, Alberto M., Matthiesen, Clemens, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We demonstrate coupling between the motions of two independently trapped ions with a separation distance of 620 $\mu$m. The ion-ion interaction is enhanced via a room-temperature electrically floating metallic wire which connects two surface traps. Tuning the motion of both ions into resonance, we show flow of energy with a coupling rate of 11 Hz. Quantum-coherent coupling is hindered by strong surface electric-field noise in our device. Our ion wire-ion system demonstrates that room-temperature conductors can be used to mediate and tune interactions between independently trapped charges over distances beyond those achievable with free-space dipole-dipole coupling. This technology may be used to sympathetically cool or entangle remotely trapped charges and enable coupling between disparate physical systems.

Published

2021

11. Trapped electrons and ions as particle detectors

Author

Carney, Daniel, Häffner, Hartmut, Moore, David C., and Taylor, Jacob M.

Subjects

Quantum Physics, High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

Electrons and ions trapped with electromagnetic fields have long served as important high-precision metrological instruments, and more recently have also been proposed as a platform for quantum information processing. Here we point out that these systems can also be used as highly sensitive detectors of passing charged particles, due to the combination of their extreme charge-to-mass ratio and low-noise quantum readout and control. In particular, these systems can be used to detect energy depositions many orders of magnitude below typical ionization scales. As illustrations, we suggest some applications in particle physics. We outline a non-destructive time-of-flight measurement capable of sub-eV energy resolution for slowly moving, collimated particles. We also show that current devices can be used to provide competitive sensitivity to models where ambient dark matter particles carry small electric millicharges $\ll e$. Our calculations may also be useful in the characterization of noise in quantum computers coming from backgrounds of charged particles., Comment: 4 pages, 3 figures. v2: published version, now includes time-of-flight measurement application and more detailed comments on millicharged DM at q > 10^-5

Published

2021

12. Changes in electric-field noise due to thermal transformation of a surface ion trap

Author

Berlin-Udi, Maya, Matthiesen, Clemens, Lloyd, P. N. Thomas, Alonso, Alberto M., Noel, Crystal, Saarel, Benjamin, Orme, Christine A., Kim, Chang-Eun, Nelson, Art J., Ray, Keith G., Lordi, Vincenzo, and Häffner, Hartmut

Subjects

Condensed Matter - Materials Science, Physics - Atomic Physics, Quantum Physics

Abstract

We aim to illuminate how the microscopic properties of a metal surface map to its electric-field noise characteristics. In our system, prolonged heat treatments of a metal film can induce a rise in the magnitude of the electric-field noise generated by the surface of that film. We refer to this heat-induced rise in noise magnitude as a thermal transformation. The underlying physics of this thermal transformation process is explored through a series of heating, milling, and electron treatments performed on a single surface ion trap. Between these treatments, $^{40}$Ca$^+$ ions trapped 70~$\mu$m above the surface of the metal are used as detectors to monitor the electric-field noise at frequencies close to 1~MHz. An Auger spectrometer is used to track changes in the composition of the contaminated metal surface. With these tools we investigate contaminant deposition, chemical reactions, and atomic restructuring as possible drivers of thermal transformations.

Published

2021

13. Quantum Sensing of Intermittent Stochastic Signals

Author

Mouradian, Sara, Glikin, Neil, Megidish, Eli, Ellers, Kai-Isaak, and Haeffner, Hartmut

Subjects

Quantum Physics, Physics - Applied Physics, Physics - Atomic Physics

Abstract

Realistic quantum sensors face a trade-off between the number of sensors measured in parallel and the control and readout fidelity ($F$) across the ensemble. We investigate how the number of sensors and fidelity affect sensitivity to continuous and intermittent signals. For continuous signals, we find that increasing the number of sensors by $1/F^2$ for $F<1$ always recovers the sensitivity achieved when $F=1$. However, when the signal is intermittent, more sensors are needed to recover the sensitivity achievable with one perfect quantum sensor. We also demonstrate the importance of near-unity control fidelity and readout at the quantum projection noise limit by estimating the frequency components of a stochastic, intermittent signal with a single trapped ion sensor. Quantum sensing has historically focused on large ensembles of sensors operated far from the standard quantum limit. The results presented in this manuscript show that this is insufficient for quantum sensing of intermittent signals and re-emphasizes the importance of the unique scaling of quantum projection noise near an eigenstate., Comment: 5 pages, 4 figures

Published

2020

14. Materials Challenges for Trapped-Ion Quantum Computers

Author

Brown, Kenneth R., Chiaverini, John, Sage, Jeremy, and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

Trapped-ion quantum information processors store information in atomic ions maintained in position in free space via electric fields. Quantum logic is enacted via manipulation of the ions' internal and shared motional quantum states using optical and microwave signals. While trapped ions show great promise for quantum-enhanced computation, sensing, and communication, materials research is needed to design traps that allow for improved performance by means of integration of system components, including optics and electronics for ion-qubit control, while minimizing the near-ubiquitous electric-field noise produced by trap-electrode surfaces. In this review, we consider the materials requirements for such integrated systems, with a focus on problems that hinder current progress toward practical quantum computation. We give suggestions for how materials scientists and trapped-ion technologists can work together to develop materials-based integration and noise-mitigation strategies to enable the next generation of trapped-ion quantum computers., Comment: 19 pages, 7 figures, commments welcome, now with all the figures

Published

2020

15. Trapping electrons in a room-temperature microwave Paul trap

Author

Matthiesen, Clemens, Yu, Qian, Guo, Jinen, Alonso, Alberto M., and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We demonstrate trapping of electrons in a millimeter-sized quadrupole Paul trap driven at 1.6~GHz in a room-temperature ultra-high vacuum setup. Cold electrons are introduced into the trap by ionization of atomic calcium via Rydberg states and stay confined by microwave and static electric fields for several tens of milliseconds. A fraction of these electrons remain trapped longer and show no measurable loss for measurement times up to a second. Electronic excitation of the motion reveals secular frequencies which can be tuned over a range of several tens to hundreds of MHz. Operating a similar electron Paul trap in a cryogenic environment may provide a platform for all-electric quantum computing with trapped electron spin qubits., Comment: Version accepted by PRX

Published

2020

16. Practical verification protocols for analog quantum simulators

Author

Shaffer, Ryan, Megidish, Eli, Broz, Joseph, Chen, Wei-Ting, and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

Analog quantum simulation is expected to be a significant application of near-term quantum devices. Verification of these devices without comparison to known simulation results will be an important task as the system size grows beyond the regime that can be simulated classically. We introduce a set of experimentally-motivated verification protocols for analog quantum simulators, discussing their sensitivity to a variety of error sources and their scalability to larger system sizes. We demonstrate these protocols experimentally using a two-qubit trapped-ion analog quantum simulator and numerically using models of up to five qubits.

Published

2020

17. Quantum sensing of intermittent stochastic signals

Author

Mouradian, Sara L, Glikin, Neil, Megidish, Eli, Ellers, Kai-Isaak, and Haeffner, Hartmut

Subjects

Quantum Physics, Physical Sciences, Chemical sciences, Mathematical sciences, Physical sciences

Abstract

Realistic quantum sensors face a trade-off between the number of sensors measured in parallel and the control and readout fidelity (F) across the ensemble. We investigate how the number of sensors and fidelity affect sensitivity to continuous and intermittent signals. For continuous signals, we find that increasing the number of sensors by 1/F2 for F

Published

2021

18. Distance scaling and polarization of electric-field noise in a surface ion trap

Author

An, Da, Matthiesen, Clemens, Urban, Erik, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We probe electric-field noise in a surface ion trap for ion-surface distances $d$ between 50 and 300 $\mu\mathrm{m}$ in the normal and planar directions. We find the noise distance dependence to scale as $d^{-2.6}$ in our trap and a frequency dependence which is consistent with $1/f$ noise. Simulations of the electric-field noise specific to our trap geometry provide evidence that we are not limited by technical noise sources. Our distance scaling data is consistent with a noise correlation length of about 100 $\mu\mathrm{m}$ at the trap surface, and we discuss how patch potentials of this size would be modified by the electrode geometry.

Published

2019

19. Coherent Control of the Rotational Degree of Freedom of a Two-Ion Coulomb Crystal

Author

Urban, Erik, Glikin, Neil, Mouradian, Sara, Krimmel, Kai, Hemmerling, Boerge, and Haeffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We demonstrate the preparation and coherent control of the angular momentum state of a two-ion crystal. The ions are prepared with an average angular momentum of $7780\hbar$ freely rotating at 100~kHz in a circularly symmetric potential, allowing us to address rotational sidebands. By coherently exciting these motional sidebands, we create superpositions of states separated by up to four angular momentum quanta. Ramsey experiments show the expected dephasing of the superposition which is dependent on the number of quanta separating the states. These results demonstrate coherent control of a collective motional state described as a quantum rotor in trapped ions. Moreover, our work offers an expansion of the utility of trapped ions for quantum simulation, interferometry, and sensing.

Published

2019

20. Studying light–matter interactions and energy transfer at the nanoscale with a trapped–ion quantum computer

Author

Haeffner, Hartmut, primary

Published

2023

21. Improved Test of Local Lorentz Invariance from a Deterministic Preparation of Entangled States

Author

Megidish, Eli, Broz, Joseph, Greene, Nicole, and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

The high degree of control available over individual atoms enables precision tests of fundamental physical concepts. In this Letter, we experimentally study how precision measurements can be improved by preparing entangled states immune to the dominant source of decoherence. Using \Ca ions, we explicitly demonstrate the advantage from entanglement on a precision test of local Lorentz invariance for the electron. Reaching the quantum projection noise limit set by quantum mechanics, we observe for bipartite entangled states the expected gain of a factor of two in the precision. Under specific conditions, multipartite entangled states may yield substantial further improvements. Our measurements improve the previous best limit for local Lorentz invariance of the electron using \Ca ions by factor of two to four to about $5\times10^{-19}$.

Published

2018

22. Electric-field noise from thermally-activated fluctuators in a surface ion trap

Author

Noel, Crystal, Berlin-Udi, Maya, Matthiesen, Clemens, Yu, Jessica, Zhou, Yi, Lordi, Vincenzo, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We probe electric-field noise near the metal surface of an ion trap chip in a previously unexplored high-temperature regime. We observe a non-trivial temperature dependence with the noise amplitude at 1-MHz frequency saturating around 500~K. Measurements of the noise spectrum reveal a $1/f^{\alpha\approx1}$-dependence and a small decrease in $\alpha$ between low and high temperatures. This behavior can be explained by considering noise from a distribution of thermally-activated two-level fluctuators with activation energies between 0.35~eV and 0.65~eV. Processes in this energy range may be relevant to understanding electric-field noise in ion traps; for example defect motion in the solid state and surface adsorbate binding energies. Studying these processes may aid in identifying the origin of excess electric-field noise in ion traps -- a major source of ion motional decoherence limiting the performance of surface traps as quantum devices., Comment: Version accepted by PRA, significantly expanded compared to v1

Published

2018

23. Surface trap with dc-tunable ion-electrode distance

Author

An, Da, Matthiesen, Clemens, Abdelrahman, Ahmed, Berlin-Udi, Maya, Gorman, Dylan, Möller, Sönke, Urban, Erik, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We describe the design, fabrication, and operation of a novel surface-electrode Paul trap that produces a radio-frequency-null along the axis perpendicular to the trap surface. This arrangement enables control of the vertical trapping potential and consequentially the ion-electrode distance via dc-electrodes only. We demonstrate confinement of single $^{40}$Ca$^+$ ions at heights between $50~\mu$m and $300~\mu$m above planar copper-coated aluminium electrodes. We investigate micromotion in the vertical direction and show cooling of both the planar and vertical motional modes into the ground state. This trap architecture provides a platform for precision electric-field noise detection, trapping of vertical ion strings without excess micromotion, and may have applications for scalable quantum computers with surface ion traps.

Published

2018

24. New ideas for tests of Lorentz invariance with atomic systems

Author

Shaniv, Ravid, Ozeri, Roee, Safronova, Marianna S., Porsev, Sergey G., Dzuba, Vladimir A., Flambaum, Victor V., and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We describe a broadly applicable experimental proposal to search for the violation of local Lorentz invariance (LLI) with atomic systems. The new scheme uses dynamic decoupling and can be implemented in current atomic clocks experiments, both with single ions and arrays of neutral atoms. Moreover, the scheme can be performed on systems with no optical transitions, and therefore it is also applicable to highly charged ions which exhibit particularly high sensitivity to Lorentz invariance violation. We show the results of an experiment measuring the expected signal of this proposal using a two-ion crystal of $^{88}$Sr$^+$ ions. We also carry out a systematic study of the sensitivity of highly charged ions to LLI to identify the best candidates for the LLI tests., Comment: 8 pages, two figures in main text, one figure in the supplementary material

Published

2017

25. Engineering vibrationally-assisted energy transfer in a trapped-ion quantum simulator

Author

Gorman, Dylan J, Hemmerling, Boerge, Megidish, Eli, Moeller, Soenke A., Schindler, Philipp, Sarovar, Mohan, and Haeffner, Hartmut

Subjects

Quantum Physics

Abstract

Many important chemical and biochemical processes in the condensed phase are notoriously difficult to simulate numerically. Often this difficulty arises from the complexity of simulating dynamics resulting from coupling to structured, mesoscopic baths, for which no separation of time scales exists and statistical treatments fail. A prime example of such a process is vibrationally assisted charge or energy transfer. A quantum simulator, capable of implementing a realistic model of the system of interest, could provide insight into these processes in regimes where numerical treatments fail. We take a first step towards modeling such transfer processes using an ion trap quantum simulator. By implementing a minimal model, we observe vibrationally assisted energy transport between the electronic states of a donor and an acceptor ion augmented by coupling the donor ion to its vibration. We tune our simulator into several parameter regimes and, in particular, investigate the transfer dynamics in the nonperturbative regime often found in biochemical situations.

Published

2017

26. Engineering Vibrationally Assisted Energy Transfer in a Trapped-Ion Quantum Simulator

Author

Gorman, Dylan J, Hemmerling, Boerge, Megidish, Eli, Moeller, Soenke A, Schindler, Philipp, Sarovar, Mohan, and Haeffner, Hartmut

Subjects

Quantum Physics, Physical Sciences, Affordable and Clean Energy, quant-ph, Astronomical and Space Sciences, Condensed Matter Physics, Physical sciences

Abstract

Many important chemical and biochemical processes in the condensed phase are notoriously difficult to simulate numerically. Often, this difficulty arises from the complexity of simulating dynamics resulting from coupling to structured, mesoscopic baths, for which no separation of time scales exists and statistical treatments fail. A prime example of such a process is vibrationally assisted charge or energy transfer. A quantum simulator, capable of implementing a realistic model of the system of interest, could provide insight into these processes in regimes where numerical treatments fail. We take a first step towards modeling such transfer processes using an ion-trap quantum simulator. By implementing a minimal model, we observe vibrationally assisted energy transport between the electronic states of a donor and an acceptor ion augmented by coupling the donor ion to its vibration. We tune our simulator into several parameter regimes and, in particular, investigate the transfer dynamics in the nonperturbative regime often found in biochemical situations.

Published

2018

27. Spin readout of trapped electron qubits

Author

Peng, Pai, Matthiesen, Clemens, and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

We propose a scheme to read out the spin of a single electron quantum bit in a surface Paul trap using oscillating magnetic field gradients. The readout sequence is composed of cooling, driving, amplification and detection of the electron's motion. We study the scheme in the presence of noise and trap anharmonicities at liquid helium temperatures. An analysis of the the four procedures shows short measurement times ($25~\mu$s) and high fidelities ($99.7\%$) are achievable with realistic experimental parameters. Our scheme performs the function of fluorescence detection in ion trapping schemes, highlighting the potential to built all-electric quantum computers based on trapped electron spin qubits.

Published

2016

28. Local probe of single phonon dynamics in warm ion crystals

Author

Abdelrahman, Ahmed, Khosravani, Omid, Gessner, Manuel, Breuer, Heinz-Peter, Buchleitner, Andreas, Gorman, Dylan J., Masuda, Ryo, Pruttivarasin, Thaned, Ramm, Michael, Schindler, Philipp, and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

The detailed characterization of non-trivial coherence properties of composite quantum systems of increasing size is an indispensable prerequisite for scalable quantum computation, as well as for understanding of nonequilibrium many-body physics. Here we show how autocorrelation functions in an interacting system of phonons as well as the quantum discord between distinct degrees of freedoms can be extracted from a small controllable part of the system. As a benchmark, we show this in chains of up to 42 trapped ions, by tracing a single phonon excitation through interferometric measurements of only a single ion in the chain. We observe the spreading and partial refocusing of the excitation in the chain, even on a background of thermal excitations. We further show how this local observable reflects the dynamical evolution of quantum discord between the electronic state and the vibrational degrees of freedom of the probe ion., Comment: 22 pages, 4 figures

Published

2016

29. 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

30. Investigation of two-frequency Paul traps for antihydrogen production

Author

Leefer, Nathan, Krimmel, Kai, Bertsche, William, Budker, Dmitry, Fajans, Joel, Folman, Ron, Haeffner, Hartmut, and Schmidt-Kaler, Ferdinand

Subjects

Physics - Atomic Physics, High Energy Physics - Experiment, Physics - Plasma Physics

Abstract

Radio-frequency (rf) Paul traps operated with multifrequency rf trapping potentials provide the ability to independently confine charged particle species with widely different charge-to-mass ratios. In particular, these traps may find use in the field of antihydrogen recombination, allowing antiproton and positron clouds to be trapped and confined in the same volume without the use of large superconducting magnets. We explore the stability regions of two-frequency Paul traps and perform numerical simulations of small, multispecies charged-particle mixtures that indicate the promise of these traps for antihydrogen recombination., Comment: 11 pages, 10 figures

Published

2016

31. Polarization of electric field noise near metallic surfaces

Author

Schindler, Philipp, Gorman, Dylan J, Daniilidis, Nikos, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Electric field noise in proximity to metallic surfaces is a poorly understood phenomenon that appears in different areas of physics. Trapped ion quantum information processors are particular susceptible to this noise, leading to motional decoherence which ultimately limits the fidelity of quantum operations. On the other hand they present an ideal tool to study this effect, opening new possibilities in surface science. In this work we analyze and measure the polarization of the noise field in a micro-fabricated ion trap for various noise sources. We find that technical noise sources and noise emanating directly from the surface give rise to different degrees of polarization which allows us to differentiate between the two noise sources. Based on this, we demonstrate a method to infer the magnitude of surface noise in the presence of technical noise.

Published

2015

32. Design of a Surface Trap for Freely Rotating Ion Ring Crystals

Author

Wang, Po-Jen, Li, Tongcang, Noel, Crystal, Zhang, Xiang, and Haeffner, Hartmut

Subjects

Physics - Atomic Physics

Abstract

We present a design of an r.f. trap using planar electrodes with the goal to trap on the order of 100 ions in a small ring structure of diameters ranging between 100 $\mu$m and 200 $\mu$m. In order to minimize the influence of trap electrode imperfections due to the fabrication, we aim at trapping the ions around 400 $\mu$m above the trap electrodes. In view of experiments to create freely rotating crystals near the ground state, we numerically study factors breaking the rotational symmetry such as external stray electric fields, local charging of the trap electrodes, and fabrication imperfections. We conclude that these imperfections can be controlled sufficiently well under state-of-the-art experimental conditions to allow for freely rotating ion rings even at energies comparable to the ground state energy of the rotational degree-of-freedom., Comment: 8 pages, 11 figures; submitted to Physical Review A

Published

2014

33. Two mode coupling in a single ion oscillator via parametric resonance

Author

Gorman, Dylan J, Schindler, Philipp, Selvarajan, Sankaranarayanan, Daniilidis, Nikos, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Atomic ions, confined in radio-frequency Paul ion traps, are a promising candidate to host a future quantum information processor. In this letter, we demonstrate a method to couple two motional modes of a single trapped ion, where the coupling mechanism is based on applying electric fields rather than coupling the ion's motion to a light field. This reduces the design constraints on the experimental apparatus considerably. As an application of this mechanism, we cool a motional mode close to its ground state without accessing it optically. As a next step, we apply this technique to measure the mode's heating rate, a crucial parameter determining the trap quality. In principle, this method can be used to realize a two-mode quantum parametric amplifier., Comment: 8 pages, 5 figures

Published

2014

34. Observing a Quantum Phase Transition by Measuring a Single Spin

Author

Gessner, Manuel, Ramm, Michael, Haeffner, Hartmut, Buchleitner, Andreas, and Breuer, Heinz-Peter

Subjects

Quantum Physics

Abstract

We show that the ground-state quantum correlations of an Ising model can be detected by monitoring the time evolution of a single spin alone, and that the critical point of a quantum phase transition is detected through a maximum of a suitably defined observable. A proposed implementation with trapped ions realizes an experimental probe of quantum phase transitions which is based on quantum correlations and scalable for large system sizes., Comment: 5 pages, 2 figures

Published

2014

35. Direct spectroscopy of the $^2$S$_{1/2}-^2$P$_{1/2}$ and $^2$D$_{3/2}-^2$P$_{1/2}$ transitions and observation of micromotion modulated spectra in trapped \Ca

Author

Pruttivarasin, Thaned, Ramm, Michael, and Haeffner, Hartmut

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

We present an experimental scheme to perform spectroscopy of the $^2$S$_{1/2}-^2$P$_{1/2}$ and $^2$D$_{3/2}-^2$P$_{1/2}$ transitions in \Ca. By rapidly switching lasers between both transitions, we circumvent the complications of both dark resonances and Doppler heating. We apply this method to directly observe the micromotion modulated fluorescence spectra of both transitions and measure the dependence of the micromotion modulation index on the trap frequency. With a measurement time of 10 minutes, we can detect the center frequencies of both dipole transitions with a precision on the order of 200 kHz even in the presence of strong micromotion.

Published

2013

36. Energy Transport in Trapped Ion Chains

Author

Ramm, Michael, Pruttivarasin, Thaned, and Häffner, Hartmut

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We experimentally study energy transport in chains of trapped ions. We use a pulsed excitation scheme to rapidly add energy to the local motional mode of one of the ions in the chain. Subsequent energy readout allows us to determine how the excitation has propagated throughout the chain. We observe energy revivals that persist for many cycles. We study the behavior with an increasing number of ions of up to 37 in the chain, including a zig-zag configuration. The experimental results agree well with the theory of normal mode evolution. The described system provides an experimental toolbox for the study of thermodynamics of closed systems and energy transport in both classical and quantum regimes.

Published

2013

37. Precision Measurement Method for Branching Fractions of Excited P1/2 States Applied to 40Ca+

Author

Ramm, Michael, Pruttivarasin, Thaned, Kokish, Mark, Talukdar, Ishan, and Häffner, Hartmut

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

We present a method for measuring branching fractions for the decay of $J = 1/2$ atomic energy levels to lower-lying states based on time-resolved recording of the atom's fluorescence during a series of population transfers. We apply this method to measure the branching fractions for the decay of the 4$^{2}$P$_{1/2}$ state of $^{40}$\Ca to the 4$^{2}$S$_{1/2}$ and 3$^{2}$D$_{3/2}$ states to be \branching\ and \branchingsm, respectively. The measurement scheme requires that at least one of the lower-lying states be long-lived. The method is insensitive to fluctuations in laser light intensity and magnetic field and is readily applicable to various atomic species due to its simplicity. Our result distinguishes well among existing state-of-the-art theoretical models of \Ca.

Published

2013

38. Quantum information processing with trapped electrons and superconducting electronics

Author

Daniilidis, Nikos, Gorman, Dylan J, Tian, Lin, and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

We describe a parametric frequency conversion scheme for trapped charged particles which enables a coherent interface between atomic and solid-state quantum systems. The scheme uses geometric non-linearities of the potential of a coupling electrode near a trapped particle. Our scheme does not rely on actively driven solid-state devices, and is hence largely immune to noise in such devices. We present a toolbox which can be used to build electron-based quantum information processing platforms, as well as quantum interfaces between trapped electrons and superconducting electronics., Comment: 23 pages, 5 figures

Published

2013

39. Electric field compensation and sensing with a single ion in a planar trap

Author

Selvarajan, Sankaranarayanan, Daniilidis, Nikos, Möller, Sönke, Clark, Rob, Ziesel, Frank, Singer, Kilian, Schmidt-Kaler, Ferdinand, and Häffner, Hartmut

Subjects

Physics - Atomic Physics, Physics - Instrumentation and Detectors, Quantum Physics

Abstract

We use a single ion as an movable electric field sensor with accuracies on the order of a few V/m. For this, we compensate undesired static electric fields in a planar RF trap and characterize the static fields over an extended region along the trap axis. We observe a strong buildup of stray charges around the loading region on the trap resulting in an electric field of up to 1.3 kV/m at the ion position. We also find that the profile of the stray field remains constant over a time span of a few months.

Published

2011

40. Trapped ions in optical lattices for probing oscillator chain models

Author

Pruttivarasin, Thaned, Ramm, Michael, Talukdar, Ishan, Kreuter, Axel, and Haeffner, Hartmut

Subjects

Quantum Physics

Abstract

We show that a chain of trapped ions embedded in microtraps generated by an optical lattice can be used to study oscillator models related to dry friction and energy transport. Numerical calculations with realistic experimental parameters demonstrate that both static and dynamic properties of the ion chain change significantly as the optical lattice power is varied. Finally, we lay out an experimental scheme to use the spin degree of freedom to probe the phase space structure and quantum critical behavior of the ion chain.

Published

2011

41. Transport of charged particles by adjusting rf voltage amplitudes

Author

Karin, Todd, Bras, Isabela Le, Kehlberger, Andreas, Singer, Kilian, Daniilidis, Nikos, and Häffner, Hartmut

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

We propose a planar architecture for scalable quantum information processing (QIP) that includes X-junctions through which particles can move without micromotion. This is achieved by adjusting radio frequency (rf) amplitudes to move an rf null along the legs of the junction. We provide a proof-of-principle by transporting dust particles in three dimensions via adjustable rf potentials in a 3D trap. For the proposed planar architecture, we use regularization techniques to obtain amplitude settings that guarantee smooth transport through the X-junction., Comment: 16 pages, 10 figures

Published

2010

42. Direct spectroscopy of the S-2(1/2)-P-2(1/2) and D-2(3/2)-P-2(1/2) transitions and observation of micromotion modulated spectra in trapped Ca-40(+)

Author

Pruttivarasin, Thaned, Ramm, Michael, and Haeffner, Hartmut

Subjects

spectroscopy, trapped ions and atoms, micromotion, General Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Optical Physics, Theoretical and Computational Chemistry

Published

2014

43. Energy transport in trapped ion chains

Author

Ramm, Michael, Pruttivarasin, Thaned, and Haeffner, Hartmut

Subjects

energy transport, trapped ions, pulsed excitation, Physical Sciences, Fluids & Plasmas

Published

2014

44. Universal quantum computation in decoherence-free subspaces with hot trapped-ions

Author

Aolita, Leandro, Davidovich, Luiz, Kim, Kihwan, and Häffner, Hartmut

Subjects

Quantum Physics

Abstract

We consider interactions that generate a universal set of quantum gates on logical qubits encoded in a collective-dephasing-free subspace, and discuss their implementations with trapped ions. This allows for the removal of the by-far largest source of decoherence in current trapped-ion experiments, collective dephasing. In addition, an explicit parametrization of all two-body Hamiltonians able to generate such gates without the system's state ever exiting the protected subspace is provided., Comment: 8 pages, 1 figure

Published

2007

45. Single photons on demand from 3D photonic band-gap structures

Author

Florescu, Marian, Scheel, Stefan, Haeffner, Hartmut, Lee, Hwang, Strekalov, Dmitry V., Knight, Peter L., and Dowling, Jonathan P.

Subjects

Quantum Physics

Abstract

We describe a practical implementation of a (semi-deterministic) photon gun based on stimulated Raman adiabatic passage pumping and the strong enhancement of the photonic density of states in a photonic band-gap material. We show that this device allows {\em deterministic} and {\em unidirectional} production of single photons with a high repetition rate of the order of 100kHz. We also discuss specific 3D photonic microstructure architectures in which our model can be realized and the feasibility of implementing such a device using ${Er}^{3+}$ ions that produce single photons at the telecommunication wavelength of $1.55 \mu$m., Comment: 4 pages, 4 EPS figures

Published

2002

46. Control and Measurement of Three-Qubit Entangled States

Author

Roos, Christian F., Riebe, Mark, Häffner, Hartmut, Hänsel, Wolfgang, Benhelm, Jan, Becher, Christoph, Schmidt-Kaler, Ferdinand, and Blatt, Rainer

Published

2004

47. Efficient experimental verification of continuously-parameterized gate sets and analog quantum simulators.

Author

Shaffer, Ryan, primary, Ren, Hang, additional, Dyrenkova, Emiliia, additional, Megidish, Eli, additional, Broz, Joseph, additional, Chen, Wei-Ting, additional, Yale, Christopher, additional, Lobser, Daniel, additional, Grinevich, Ashlyn, additional, Chow, Matthew, additional, Revelle, Melissa, additional, Clark, Susan, additional, and Haeffner, Hartmut, additional

Published

2022

48. Mass of the Electron from the Electronic g Factor in Hydrogenlike Carbon — the Influence of other Fundamental Parameters

Author

Beier, Thomas, Kluge, H.-Jürgen, Quint, Wolfgang, Häffner, Hartmut, Werth, Günther, Knudsen, Helge, editor, Andersen, Jens Ulrik, editor, and Kluge, Heinz-Jürgen, editor

Published

2003

49. Prototype quantum simulator of structured environment-assisted energy transfer

Author

Barajas, Kristian, primary, Broz, Joseph, primary, Haeffner, Hartmut, primary, and Campbell, Wesley, primary

Published

2022

50. Towards a trapped electron quantum computing platform

Author

Dhital, Madhav, primary, Yu, Qian, primary, Alonso, Alberto, primary, Caminiti, Jackie, primary, Beck, Kristin, primary, Sutherland, Robert, primary, Leibfried, Dietrich, primary, Rodriguez, Kayla, primary, Haeffner, Hartmut, primary, and Hemmerling, Boerge, primary

Published

2022