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Nagoya University Photo-Science Nanofactory ProjectTakashima, Yoshifumi, Yamane, Takashi, Takeda, Yoshikazu, Soda, Kazuo, Yagi, Shinya, Takeuchi, Tsunehiro, Akimoto, Koichi, Sakata, Makoto, Suzuki, Atsuo, Tanaka, Keisuke, Nakamura, Arao, Hori, Masaru, Morita, Shinzo, Seki, Kazuhiko, Mizutani, Uichiro, Kobayakawa, Hisashi, Yamashita, Koujun, Katoh, Masahiro January 2007 (has links)
No description available.
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Design guideline of flux-lock type HTS fault current limiter for power system applicationMatsumura, T., Shimizu, H., Yokomizu, Y. 03 1900 (has links)
No description available.
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Development of a 6600 V/210 V kVA hybrid-type superconducting transformerKito, Y., Okubo, H., Hayakawa, N., Mita, Y., Yamamoto, M. 04 1900 (has links)
No description available.
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Aluminium-Palladium Transition Edge SensorsPersaud, Lauren Margaret January 2008 (has links)
A superconducting Transition Edge Sensor (TES) can be used to make the most sensitive thermometer which operates in a very narrow
temperature range. The thin film bi-layer fabrication details are discussed as well as application in condensed matter physics. These include: measurement of quasi-adiabatic latent heat of superconducting transition, cobalt thermometry and photon detection.
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Quantum Microwave Photodetection Using Superconducting Josephson Circuits.Osberg, Brendan 24 August 2009 (has links)
Superconducting circuits have recently become a major contender for the implementation of quantum computers owing to their compatibility with existing microchip fabrication technologies. Their utility stems largely from their ability to be coupled with resonant cavities for the purposes of trapping and relaying microwave radiation. Because of this feature, scientists are able to transmit quantum information from a variety of qubits. Though quantum-limited amplifiers exist, unfortunately there currently exists no microwave photon counter capable of single shot quantum detection. Hence, we use superconducting circuits with Josephson junctions to design a microwave photon detector based on a modified phase qubit that exhibits a bandwidth of 4GHz, and a detection fidelity of 98%. We use metastable barrier transition (driven by incident photons) to create an avalanche effect analogous to current photo-diodes. Linear coupling of the junction flux with the radiation permits photodetection from an arbitrary quantum source in the GHz range. We show the device to be robust to changes in drive frequency, temporal photon width, and resonator quality factor, and we optimize our device with respect to these parameters. We show the device to be stable over the necessary time scales, and yet sensitive enough to accurately measure photons on demand.
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Aluminium-Palladium Transition Edge SensorsPersaud, Lauren Margaret January 2008 (has links)
A superconducting Transition Edge Sensor (TES) can be used to make the most sensitive thermometer which operates in a very narrow
temperature range. The thin film bi-layer fabrication details are discussed as well as application in condensed matter physics. These include: measurement of quasi-adiabatic latent heat of superconducting transition, cobalt thermometry and photon detection.
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Quantum Microwave Photodetection Using Superconducting Josephson Circuits.Osberg, Brendan 24 August 2009 (has links)
Superconducting circuits have recently become a major contender for the implementation of quantum computers owing to their compatibility with existing microchip fabrication technologies. Their utility stems largely from their ability to be coupled with resonant cavities for the purposes of trapping and relaying microwave radiation. Because of this feature, scientists are able to transmit quantum information from a variety of qubits. Though quantum-limited amplifiers exist, unfortunately there currently exists no microwave photon counter capable of single shot quantum detection. Hence, we use superconducting circuits with Josephson junctions to design a microwave photon detector based on a modified phase qubit that exhibits a bandwidth of 4GHz, and a detection fidelity of 98%. We use metastable barrier transition (driven by incident photons) to create an avalanche effect analogous to current photo-diodes. Linear coupling of the junction flux with the radiation permits photodetection from an arbitrary quantum source in the GHz range. We show the device to be robust to changes in drive frequency, temporal photon width, and resonator quality factor, and we optimize our device with respect to these parameters. We show the device to be stable over the necessary time scales, and yet sensitive enough to accurately measure photons on demand.
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Guided-Wave Superconducting Quantum Optoelectronic DevicesGhohroodi Ghamsari, Behnood 25 May 2010 (has links)
This thesis investigates a novel optoelectronic platform based on
the integration of superconductive structures, such as thin films
and micro-constrictions, with optical waveguides for ultra-fast and
ultra-sensitive devices with applications including high-speed
optical communications, quantum optical information processing, and
terahertz (THz) devices and systems.
The kinetic-inductive photoresponse of superconducting thin films
will be studied as the basic optoelectronic process underlying the
operation of these novel devices. Analytical formulation for the
non-bolometric response is presented, and experimental
photodetection in YBCO meander-line structures will be demonstrated.
A set of superconducting coplanar waveguides (CPW) are designed and
characterized, which support the operation of the devices at
microwave frequencies. Microwave-photonic devices comprising a
microwave transmission line and a light-sensitive element, such as a
meander-line structure, are designed and measured for implementation
of optically tunable microwave components.
In order to support low-loss and low-dispersion propagation of
millimeter-wave and THz signals in ultra-fast and wideband
kinetic-inductive devices, surface-wave transmission lines are
proposed, incorporating long-wavelength Surface Plasmon Polariton
(SPP) modes in planar metal-dielectric waveguides.
The theory of superconducting optical waveguides, including
analytical formulation and numerical methods, is developed in
detail. The implementation of superconducting optical waveguides is
discussed thoroughly, employing conventional dielectric-waveguide
techniques as well as optical SPP modes.
Superconductive traveling-wave photodetectors (STWPDs) are
introduced as a viable means for ultra-fast and ultra-sensitive
photodetection and photomixing. A modified transmission line
formalism is developed to model STWPDs, where light is guided
through an optical waveguide and photodetection is distributed along
a transmission line.
As an appendix, a systematic approach is developed for the analysis
of carrier transport through superconducting heterostructures and
micro-constrictions within the Bogoliubov-de Gennes (BdG) framework.
The method is applied to study the role of Andreev reflection and
Josephson-like phenomena in the current-voltage characteristics of
inhomogeneous superconducting structures. I-V characteristics are
experimentally demonstrated in YBCO micro-constrictions with
potential applications in millimeter-wave and THz devices.
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Active and reactive power control model of superconducting magnetic energy storage (SMES) for the improvement of power system stabilityHam, Wan Kyun, January 2003 (has links) (PDF)
Thesis (Ph. D.)--University of Texas at Austin, 2003. / Vita. Includes bibliographical references. Available also from UMI Company.
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Active and reactive power control model of superconducting magnetic energy storage (SMES) for the improvement of power system stabilityHam, Wan Kyun 28 August 2008 (has links)
Not available / text
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