Your search keyword '"Wang, Shannon X."' showing total 6 results

1. Laser-induced charging of microfabricated ion traps.

Author

Wang, Shannon X., Hao Low, Guang, Lachenmyer, Nathan S., Ge, Yufei, Herskind, Peter F., and Chuang, Isaac L.

Subjects

ION traps, LASERS, ALUMINUM, COPPER, GOLD, SOLUTION (Chemistry), IONS

Abstract

Electrical charging of metal surfaces due to photoelectric generation of carriers is of concern in trapped ion quantum computation systems, due to the high sensitivity of the ions' motional quantum states to deformation of the trapping potential. The charging induced by typical laser frequencies involved in Doppler cooling and quantum control is studied here, with microfabricated surface-electrode traps made of aluminum, copper, and gold, operated at 6 K with a single Sr+ ion trapped 100 μm above the trap surface. The lasers used are at 370, 405, 460, and 674 nm, and the typical photon flux at the trap is 1014 photons/cm2/sec. Charging is detected by monitoring the ion's micromotion signal, which is related to the number of charges created on the trap. A wavelength and material dependence of the charging behavior is observed: Lasers at lower wavelengths cause more charging, and aluminum exhibits more charging than copper or gold. We describe the charging dynamic based on a rate-equation approach. [ABSTRACT FROM AUTHOR]

Published

2011

2. 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

3. LANDAU-ZENER TRANSITIONS IN THE PRESENCE OF SPIN ENVIRONMENT.

Author

WAN, ANDY T. S., AMIN, M. H. S., and WANG, SHANNON X.

Subjects

QUANTUM computers, PROBABILITY theory, QUANTUM theory, FERMIONS, HAMILTONIAN systems

Abstract

We study the effect of an environment consisting of noninteracting two level systems on Landau-Zener transitions with an interest on the performance of an adiabatic quantum computer. We show that if the environment is initially at zero temperature, it does not affect the transition probability. An excited environment, however, will always increase the probability of making a transition out of the ground state. For the case of equal intermediate gaps, we find an analytical upper bound for the transition probability in the limit of large number of environmental spins. We show that such an environment will only suppress the probability of success for adiabatic quantum computation by at most a factor close to 1/2. [ABSTRACT FROM AUTHOR]

Published

2009

4. Transparent ion trap with integrated photodetector.

Author

Eltony, Amira M., Wang, Shannon X., Akselrod, Gleb M., Herskind, Peter F., and Chuang, Isaac L.

Subjects

ION traps, OPTOELECTRONIC devices, FLUORESCENCE, QUBITS, PROPERTIES of matter, LUMINESCENCE

Abstract

Fluorescence collection sets the efficiency of state detection and the rate of entanglement generation between remote trapped ion qubits. Despite efforts to improve light collection using various optical elements, solid angle capture is limited to ≈10% for implementations that are scalable to many ions. We present an approach based on fluorescence detection through a transparent trap using an integrated photodetector, combining collection efficiency approaching 50% with scalability. We microfabricate transparent surface traps with indium tin oxide and verify stable trapping of single ions. The fluorescence from a cloud of ions is detected using a photodiode sandwiched with a transparent trap. [ABSTRACT FROM AUTHOR]

Published

2013

5. Superconducting microfabricated ion traps.

Author

Wang, Shannon X., Ge, Yufei, Labaziewicz, Jaroslaw, Dauler, Eric, Berggren, Karl, and Chuang, Isaac L.

Subjects

SUPERCONDUCTIVITY, MICROFABRICATION, ION traps, NITRIDES, ELECTRIC resistance, CRITICAL currents, ELECTRIC heating, SURFACES (Technology)

Abstract

We fabricate superconducting ion traps with niobium and niobium nitride and trap single 88Sr ions at cryogenic temperatures. The superconducting transition is verified and characterized by measuring the resistance and critical current using a four-wire measurement on the trap structure, and observing change in the rf reflection. The lowest observed heating rate is 2.1(3) quanta/s at 800 kHz at 6 K and shows no significant change across the superconducting transition, suggesting that anomalous heating is primarily caused by noise sources on the surface. This demonstration of superconducting ion traps opens up possibilities for integrating trapped ions and molecular ions with superconducting devices. [ABSTRACT FROM AUTHOR]

Published

2010

6. Individual addressing of ions using magnetic field gradients in a surface-electrode ion trap.

Author

Wang, Shannon X., Labaziewicz, Jaroslaw, Yufei Ge, Shewmon, Ruth, and Chuang, Isaac L.

Subjects

IONS, MAGNETIC fields, ION traps, FIELD theory (Physics), ELECTRON spin echoes, QUANTUM theory, PHYSICS

Abstract

A dense array of ions in microfabricated traps represents one possible way to scale up ion trap quantum computing. The ability to address individual ions is an important component of such a scheme. We demonstrate individual addressing of trapped ions in a microfabricated surface-electrode trap using a magnetic field gradient generated on-chip. A frequency splitting of 310(2) kHz for two ions separated by 5 μm is achieved. Selective single qubit operations are performed on one of two trapped ions with an average of 2.2(±1.0%) crosstalk. Coherence time is reduced by the magnetic field gradient, but the spin-echo technique effectively restores the coherence time. [ABSTRACT FROM AUTHOR]

Published

2009