News & Events

  • Generation of Quantum States of Light with a Josephson Laser

    April 1, 2014

    Quantum states of light are a topic of considerable current interest, and may lead to use of continuous variables for quantum information processing, as well as to quantum-enhanced measurements. Ideally, one would like to be able to generate such states simply, and to have the states contain large numbers of photons. We have recently developed a device, the cavity-embedded Cooper pair transistor, that uses the ac Josephson effect to inject large numbers of microwave photons into a cavity.

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  • Quantum-Classical Correspondence for Strongly Nonlinear, Circuit QED Based Systems

    April 1, 2014

    We are investigating the quantum versus classical dynamics involving tunneling Cooper-pairs in self-oscillating superconducting Josephson devices that are strongly interacting with microwave cavity photons. Manifest quantum states comprising large numbers of microwave photons result for such devices. This project provides theoretical support for experiments being carried out by Alex Rimberg's group. FACULTY CONTACT: Miles Blencowe

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  • Gravitationally Induced Decoherence

    April 1, 2014

    We are investigating the role that gravity plays as an environment in causing the rapid decoherence of matter superposition states. Our approach is based on the viewpoint that the standard perturbative quantization of general relativity provides an effective description of quantum gravity that is valid at ordinary energies. FACULTY CONTACT: Miles Blencowe

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  • Optimizing Dynamic Nuclear Polarization

    April 1, 2014

    Dynamic nuclear polarization (DNP) is a technique used to transfer spin polarization from electron to nuclear spins. Since the magnetic moment of the electron is over three orders of magnitude larger than that of most nuclear spins, this results in a dramatic increase in the magnitude of nuclear magnetic resonance signals. DNP is increasingly being used across a wide range of applications to improve the sensitivity of NMR measurements.

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  • High-Fidelity Control and Readout of Spins in Semiconductors

    April 1, 2014

    Our improving ability to control quantum mechanical systems is heralding a new generation of quantum devices whose performance is ultimately only limited by the laws of physics. Spins in semiconductors are a promising platform for such devices as they can have long coherence times, and could leverage the existing capabilities of the semiconductor industry. Our goal is to demonstrate high fidelity control and readout schemes for electron and nuclear spins in semiconductors such as silicon and silicon carbide.

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