Your search keyword '"Hennrich, Markus"' showing total 14 results

1. Time-resolved and state-selective detection of single freely falling atoms

Author

Bondo, Torsten, Hennrich, Markus, Legero, Thomas, Rempe, Gerhard, and Kuhn, Axel

Subjects

*RUBIDIUM, *ATOMS, *LASER beams, *DEMODULATION

Abstract

Abstract: We report on the detection of single, slowly moving Rubidium atoms using laser-induced fluorescence. The atoms move at 3m/s while they are detected with a time resolution of 60μs. The detection scheme employs a near-resonant laser beam that drives a cycling atomic transition, and a highly efficient mirror setup to focus a large fraction of the fluorescence photons to a photomultiplier tube. It counts on average 20 photons per atom. [Copyright &y& Elsevier]

Published

2006

2. Counter-intuitive vacuum-stimulated Raman scattering.

Author

Hennrich, Markus, Legero, Thomas, Kuhn, Axel, and Rempe, Gerhard

Subjects

*RAMAN effect, *PHOTONS

Abstract

Vacuum-stimulated Raman scattering in strongly coupled atom--cavity systems allows one to generate free-running single photon pulses on demand. Most properties of the emitted photons are well defined, provided spontaneous emission processes do not contribute. Therefore, electronic excitation of the atom must not occur, which is assured for a system adiabatically following a dark state during the photon-generation process. We experimentally investigate the conditions that must be met for adiabatic following in a time-of-flight driven system, with atoms passing through a cavity and a pump beam oriented transverse to the cavity axis. From our results, we infer the optimal intensity and relative pump-beam position with respect to the cavity axis. [ABSTRACT FROM AUTHOR]

Published

2003

3. Exploring the Many-Body Dynamics Near a Conical Intersection with Trapped Rydberg Ions.

Author

Gambetta, Filippo M., Chi Zhang, Hennrich, Markus, Lesanovsky, Igor, and Weibin Li

Subjects

*RYDBERG states, *POTENTIAL energy surfaces, *ION traps, *ELECTRONIC measurements, *EXCITED states

Abstract

Conical intersections between electronic potential energy surfaces are paradigmatic for the study of nonadiabatic processes in the excited states of large molecules. However, since the corresponding dynamics occurs on a femtosecond timescale, their investigation remains challenging and requires ultrafast spectroscopy techniques. We demonstrate that trapped Rydberg ions are a platform to engineer conical intersections and to simulate their ensuing dynamics on larger length scales and timescales of the order of nanometers and microseconds, respectively; all this in a highly controllable system. Here, the shape of the potential energy surfaces and the position of the conical intersection can be tuned thanks to the interplay between the high polarizability and the strong dipolar exchange interactions of Rydberg ions. We study how the presence of a conical intersection affects both the nuclear and electronic dynamics demonstrating, in particular, how it results in the inhibition of the nuclear motion. These effects can be monitored in real time via a direct spectroscopic measurement of the electronic populations in a state-of-the-art experimental setup. [ABSTRACT FROM AUTHOR]

Published

2021

4. Long-Range Multibody Interactions and Three-Body Antiblockade in a Trapped Rydberg Ion Chain.

Author

Gambetta, Filippo M., Chi Zhang, Hennrich, Markus, Lesanovsky, Igor, and Weibin Li

Subjects

*ION traps, *RYDBERG states, *PHASES of matter, *QUANTUM theory, *QUANTUM information science, *DEGREES of freedom

Abstract

Trapped Rydberg ions represent a flexible platform for quantum simulation and information processing that combines a high degree of control over electronic and vibrational degrees of freedom. The possibility to individually excite ions to high-lying Rydberg levels provides a system where strong interactions between pairs of excited ions can be engineered and tuned via external laser fields. We show that the coupling between Rydberg pair interactions and collective motional modes gives rise to effective long-range and multibody interactions consisting of two, three, and four-body terms. Their shape, strength, and range can be controlled via the ion trap parameters and strongly depends on both the equilibrium configuration and vibrational modes of the ion crystal. By focusing on an experimentally feasible quasi one-dimensional setup of 88Sr+ Rydberg ions, we demonstrate that multibody interactions are enhanced by the emergence of soft modes associated with, e.g., a structural phase transition. This has a striking impact on many-body electronic states and results--for example--in a three-body antiblockade effect that can be employed as a sensitive probe to detect structural phase transitions in Rydberg ion chains. Our study unveils the possibilities offered by trapped Rydberg ions for studying exotic phases of matter and quantum dynamics driven by enhanced multibody interactions. [ABSTRACT FROM AUTHOR]

Published

2020

5. A quantum information processor with trapped ions.

Author

Schindler, Philipp, Nigg, Daniel, Monz, Thomas, Barreiro, Julio T, Martinez, Esteban, Wang, Shannon X, Quint, Stephan, Brandl, Matthias F, Nebendahl, Volckmar, Roos, Christian F, Chwalla, Michael, Hennrich, Markus, and Blatt, Rainer

Subjects

*ION traps, *QUANTUM information science, *FOURIER transforms, *QUANTUM computers, *ALGORITHMS

Abstract

Quantum computers hold the promise to solve certain problems exponentially faster than their classical counterparts. Trapped atomic ions are among the physical systems in which building such a computing device seems viable. In this work we present a small-scale quantum information processor based on a string of 40Ca+ ions confined in a macroscopic linear Paul trap. We review our set of operations which includes non-coherent operations allowing us to realize arbitrary Markovian processes. In order to build a larger quantum information processor it is mandatory to reduce the error rate of the available operations which is only possible if the physics of the noise processes is well understood. We identify the dominant noise sources in our system and discuss their effects on different algorithms. Finally we demonstrate how our entire set of operations can be used to facilitate the implementation of algorithms by examples of the quantum Fourier transform and the quantum order finding algorithm. [ABSTRACT FROM AUTHOR]

Published

2013

6. Demonstration of genuine multipartite entanglement with device-independent witnesses.

Author

Barreiro, Julio T., Bancal, Jean-Daniel, Schindler, Philipp, Nigg, Daniel, Hennrich, Markus, Monz, Thomas, Gisin, Nicolas, and Blatt, Rainer

Subjects

*QUANTUM entanglement, *CALCIUM ions, *CALCIUM isotopes, *BELL'S theorem, *PHYSICS experiments, *QUANTUM theory

Abstract

Entanglement in a quantum system can be demonstrated experimentally by performing the measurements prescribed by an appropriate entanglement witness. However, the unavoidable mismatch between the implementation of measurements in practical devices and their precise theoretical modelling generally results in the undesired possibility of false-positive entanglement detection. Such scenarios can be avoided by using the recently developed device-independent entanglement witnesses (DIEWs) for genuine multipartite entanglement. Similarly to Bell inequalities, the only assumption of DIEWs is that consistent measurements are performed locally on each subsystem. No precise description of the measurement devices is required. Here we report an experimental test of DIEWs on up to six entangled 40Ca+ ions. We also demonstrate genuine multipartite quantum nonlocality between up to six parties with the detection loophole closed. [ABSTRACT FROM AUTHOR]

Published

2013

7. Undoing a Quantum Measurement.

Author

Schindler, Philipp, Monz, Thomas, Nigg, Daniel, Barreiro, Julio T., Martinez, Esteban A., Brandl, Matthias F., Chwalla, Michael, Hennrich, Markus, and Blatt, Rainer

Subjects

*QUANTUM measurement, *QUANTUM measure theory, *QUANTUM information theory, *DETERMINISTIC processes, *ION traps

Abstract

In general, a quantum measurement yields an undetermined answer and alters the system to be consistent with the measurement result. This process maps multiple initial states into a single state and thus cannot be reversed. This has important implications in quantum information processing, where errors can be interpreted as measurements. Therefore, it seems that it is impossible to correct errors in a quantum information processor, but protocols exist that are capable of eliminating them if they affect only part of the system. In this work we present the deterministic reversal of a fully projective measurement on a single particle, enabled by a quantum error-correction protocol in a trapped ion quantum information processor. We further introduce an in-sequence, single-species recooling procedure to counteract the motional heating of the ion string due to the measurement. [ABSTRACT FROM AUTHOR]

Published

2013

8. Experimental Characterization of Quantum Dynamics Through Many-Body Interactions.

Author

Nigg, Daniel, Barreiro, Julio T., Schindler, Philipp, Mohseni, Masoud, Monz, Thomas, Chwalla, Michael, Hennrich, Markus, and Blatt, Rainer

Subjects

*QUANTUM theory, *TOMOGRAPHY, *QUBITS, *MULTIBODY systems, *MEASUREMENT

Abstract

We report on the implementation of a quantum process tomography technique known as direct characterization of quantum dynamics applied on coherent and incoherent single-qubit processes in a system of trapped 40Ca+ ions. Using quantum correlations with an ancilla qubit, direct characterization of quantum dynamics reduces substantially the number of experimental configurations required for a full quantum process tomography and all diagonal elements of the process matrix can be estimated with a single setting. With this technique, the system's relaxation times T1 and T2 were measured with a single experimental configuration. We further show the first, complete characterization of single-qubit processes using a single generalized measurement realized through multibody correlations with three ancilla qubits. [ABSTRACT FROM AUTHOR]

Published

2013

9. An open-system quantum simulator with trapped ions.

Author

Barreiro, Julio T., Müller, Markus, Schindler, Philipp, Nigg, Daniel, Monz, Thomas, Chwalla, Michael, Hennrich, Markus, Roos, Christian F., Zoller, Peter, and Blatt, Rainer

Subjects

*ION traps, *IONIC mobility, *PROPERTIES of matter, *SIMULATION methods & models, *OPERATIONS research

Abstract

The control of quantum systems is of fundamental scientific interest and promises powerful applications and technologies. Impressive progress has been achieved in isolating quantum systems from the environment and coherently controlling their dynamics, as demonstrated by the creation and manipulation of entanglement in various physical systems. However, for open quantum systems, engineering the dynamics of many particles by a controlled coupling to an environment remains largely unexplored. Here we realize an experimental toolbox for simulating an open quantum system with up to five quantum bits (qubits). Using a quantum computing architecture with trapped ions, we combine multi-qubit gates with optical pumping to implement coherent operations and dissipative processes. We illustrate our ability to engineer the open-system dynamics through the dissipative preparation of entangled states, the simulation of coherent many-body spin interactions, and the quantum non-demolition measurement of multi-qubit observables. By adding controlled dissipation to coherent operations, this work offers novel prospects for open-system quantum simulation and computation. [ABSTRACT FROM AUTHOR]

Published

2011

10. Experimental multiparticle entanglement dynamics induced by decoherence.

Author

Barreiro, Julio T., Schindler, Philipp, Gühne, Otfried, Monz, Thomas, Chwalla, Michael, Roos, Christian F., Hennrich, Markus, and Blatt, Rainer

Subjects

*MULTIPLICITY of hadrons, *COHERENCE (Physics), *BELL'S theorem, *QUANTUM theory, *ENVIRONMENTAL engineering, *PHYSICS

Abstract

Multiparticle entanglement leads to richer correlations than two-particle entanglement and gives rise to striking contradictions with local realism, inequivalent classes of entanglement and applications such as one-way or topological quantum computing. When exposed to decohering or dissipative environments, multiparticle entanglement yields subtle dynamical features and access to new classes of states and applications. Here, using a string of trapped ions, we experimentally characterize the dynamics of entanglement of a multiparticle state under the influence of decoherence. By embedding an entangled state of four qubits in a decohering environment (through spontaneous decay), we observe a rich dynamics crossing distinctive domains: Bell-inequality violation, entanglement superactivation, bound entanglement and full separability. We also develop new theoretical tools for characterizing entanglement in quantum states. Recent quantum-computing, state-engineering and simulation paradigms driven by dissipative or decohering environments can benefit from the environment engineering techniques demonstrated here. [ABSTRACT FROM AUTHOR]

Published

2010

11. Experimental Repetitive Quantum Error Correction.

Author

Schindler, Philipp, Barreiro, Julio T., Monz, Thomas, Nebendahl, Volckmar, Nigg, Daniel, Chwalla, Michael, Hennrich, Markus, and Blatt, Rainer

Subjects

*PHYSICS research, *PHYSICS experiments, *QUANTUM computers, *ELECTROMAGNETIC noise, *MATHEMATICAL physics, *ERROR functions

Abstract

The computational potential of a quantum processor can only be unleashed if errors during a quantum computation can be controlled and corrected for. Quantum error correction works if imperfections of quantum gate operations and measurements are below a certain threshold and corrections can be applied repeatedly. We implement multiple quantum error correction cycles for phase-flip errors on qubits encoded with trapped ions. Errors are corrected by a quantum-feedback algorithm using high-fidelity gate operations and a reset technique for the auxiliary qubits. Up to three consecutive correction cycles are realized, and the behavior of the algorithm for different noise environments is analyzed. [ABSTRACT FROM AUTHOR]

Published

2011

12. Tracking the Dynamics of an Ideal Quantum Measurement.

Author

Pokorny, Fabian, Chi Zhang, Higgins, Gerard, Cabello, Adán, Kleinmann, Matthias, and Hennrich, Markus

Subjects

*QUANTUM theory, *QUANTUM measurement, *QUANTUM mechanics, *ION traps, *QUANTUM states

Abstract

The existence of ideal quantum measurements is one of the fundamental predictions of quantum mechanics. In theory, an ideal measurement projects a quantum state onto the eigenbasis of the measurement observable, while preserving coherences between eigenstates that have the same eigenvalue. The question arises whether there are processes in nature that correspond to such ideal quantum measurements and how such processes are dynamically implemented in nature. Here we address this question and present experimental results monitoring the dynamics of a naturally occurring measurement process: the coupling of a trapped ion qutrit to the photon environment. By taking tomographic snapshots during the detection process, we show that the process develops in agreement with the model of an ideal quantum measurement with an average fidelity of 94%. [ABSTRACT FROM AUTHOR]

Published

2020

13. Highly Polarizable Rydberg Ion in a Paul Trap.

Author

Higgins, Gerard, Pokorny, Fabian, Chi Zhang, and Hennrich, Markus

Subjects

*RYDBERG states, *STARK effect, *RABI oscillations, *ATOMIC clocks, *ION traps, *ELECTRIC fields

Abstract

Usually the influence of the quadratic Stark effect on an ion's trapping potential is minuscule and only needs to be considered in atomic clock experiments. In this work we excite a trapped ion to a Rydberg state with polarizability ∼ 8 orders of magnitude higher than a low-lying electronic state; we find that the highly polarizable ion experiences a vastly different trapping potential owing to the Stark effect. We observe changes in trap stiffness, equilibrium position, and minimum potential, which can be tuned using the trapping electric fields. These effects lie at the heart of several proposed studies, including a high-fidelity submicrosecond entangling operation; in addition we demonstrate these effects may be used to minimize ion micromotion. Mitigation of Stark effects is important for coherent control of Rydberg ions; we illustrate this by carrying out the first Rabi oscillations between a low-lying electronic state and a Rydberg state of an ion. [ABSTRACT FROM AUTHOR]

Published

2019

14. Coherent Control of a Single Trapped Rydberg Ion.

Author

Higgins, Gerard, Pokorny, Fabian, Chi Zhang, Bodart, Quentin, and Hennrich, Markus

Subjects

*RYDBERG states, *ION traps, *QUANTUM computing

Abstract

Trapped Rydberg ions are a promising novel approach to quantum computing and simulations. They are envisaged to combine the exquisite control of trapped ion qubits with the fast two-qubit Rydberg gates already demonstrated in neutral atom experiments. Coherent Rydberg excitation is a key requirement for these gates. Here, we carry out the first coherent Rydberg excitation of an ion and perform a single-qubit Rydberg gate, thus demonstrating basic elements of a trapped Rydberg ion quantum computer. [ABSTRACT FROM AUTHOR]

Published

2017