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Автор: Grafiati
Опубліковано: 6 вересня 2023

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Статті в журналах з теми "Superconducting quantum devices"

1

Su, Fei-Fan, Zhao-Hua Yang, Shou-Kuan Zhao, Hai-Sheng Yan, Ye Tian, and Shi-Ping Zhao. "Fabrication of superconducting qubits and auxiliary devices with niobium base layer." Acta Physica Sinica 71, no. 5 (2022): 050303. http://dx.doi.org/10.7498/aps.71.20211865.

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Over the past two decades significant advances have been made in the research of superconducting quantum computing and quantum simulation, in particular of the device design and fabrication that leads to ever-increasing superconducting qubit coherence times and scales. With Google’s announcement of the realization of “quantum supremacy”, superconducting quantum computing has attracted even more attention. Superconducting qubits are macroscopic objects with quantum properties such as quantized energy levels and quantum-state superposition and entanglement. Their quantum states can be precisely manipulated by tuning the magnetic flux, charge, and phase difference of the Josephson junctions with nonlinear inductance through electromagnetic pulse signals, thereby implementing the quantum information processing. They have advantages in many aspects and are expected to become the central part of universal quantum computing. Superconducting qubits and auxiliary devices prepared with niobium or other hard metals like tantalum as bottom layers of large-area components have unique properties and potentials for further development. In this paper the research work in this area is briefly reviewed, starting from the design and working principle of a variety of superconducting qubits, to the detailed procedures of substrate selection and pretreatment, film growth, pattern transfer, etching, and Josephson junction fabrication, and finally the practical superconducting qubit and their auxiliary device fabrications with niobium base layers are also presented. We aim to provide a clear overview for the fabrication process of these superconducting devices as well as an outlook for further device improvement and optimization in order to help establish a perspective for future progress.
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2

Shi, Wenbo, and Robert Malaney. "Entanglement of Signal Paths via Noisy Superconducting Quantum Devices." Entropy 25, no. 1 (January 12, 2023): 153. http://dx.doi.org/10.3390/e25010153.

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Quantum routers will provide for important functionality in emerging quantum networks, and the deployment of quantum routing in real networks will initially be realized on low-complexity (few-qubit) noisy quantum devices. A true working quantum router will represent a new application for quantum entanglement—the coherent superposition of multiple communication paths traversed by the same quantum signal. Most end-user benefits of this application are yet to be discovered, but a few important use-cases are now known. In this work, we investigate the deployment of quantum routing on low-complexity superconducting quantum devices. In such devices, we verify the quantum nature of the routing process as well as the preservation of the routed quantum signal. We also implement quantum random access memory, a key application of quantum routing, on these same devices. Our experiments then embed a five-qubit quantum error-correcting code within the router, outlining the pathway for error-corrected quantum routing. We detail the importance of the qubit-coupling map for a superconducting quantum device that hopes to act as a quantum router, and experimentally verify that optimizing the number of controlled-X gates decreases hardware errors that impact routing performance. Our results indicate that near-term realization of quantum routing using noisy superconducting quantum devices within real-world quantum networks is possible.
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3

Dhakal, Pashupati. "Superconducting Radio Frequency Resonators for Quantum Computing: A Short Review." Journal of Nepal Physical Society 7, no. 3 (December 31, 2021): 1–5. http://dx.doi.org/10.3126/jnphyssoc.v7i3.42179.

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Superconducting radiofrequency (SRF) technology is being used not only in discovery science programs and basic research but also for several applications that benefit society more directly. The advantage of superconducting resonators over those made of normal-conducting metal is their ability to store electromagnetic energy with much lower dissipation. The high-quality factor and longer dissipation time provided by these superconducting resonators can deliver superior performance. Currently, the quantum processing architecture uses resonators and interconnecting circuits operating in the microwave regime with superconducting strip-line technology and low noise electronic devices for switching and communication. The performance of these devices can be enhanced by embedding them in 3D SRF cavity resonators to prolong the coherence time, which improves the utility of the device by reducing error rates and allowing more manipulations (calculations) before the quantum state decays. Here, we present a short review of current microwave technology used in quantum computers and progress towards the 3D resonators to enhance thecoherence time.
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4

Song, Chao, Jing Cui, H. Wang, J. Hao, H. Feng, and Ying Li. "Quantum computation with universal error mitigation on a superconducting quantum processor." Science Advances 5, no. 9 (September 2019): eaaw5686. http://dx.doi.org/10.1126/sciadv.aaw5686.

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Medium-scale quantum devices that integrate about hundreds of physical qubits are likely to be developed in the near future. However, these devices will lack the resources for realizing quantum fault tolerance. Therefore, the main challenge of exploring the advantage of quantum computation is to minimize the impact of device and control imperfections without complete logical encoding. Quantum error mitigation is a solution satisfying the requirement. Here, we demonstrate an error mitigation protocol based on gate set tomography and quasi-probability decomposition. One- and two-qubit circuits are tested on a superconducting device, and computation errors are successfully suppressed. Because this protocol is universal for digital quantum computers and algorithms computing expected values, our results suggest that error mitigation can be an essential component of near-future quantum computation.
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5

Castellano, M. G. "Macroscopic quantum behavior of superconducting quantum interference devices." Fortschritte der Physik 51, no. 45 (May 7, 2003): 288–94. http://dx.doi.org/10.1002/prop.200310041.

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CHIARELLO, F., M. G. CASTELLANO, R. LEONI, G. TORRIOLI, C. COSMELLI, and P. CARELLI. "JOSEPHSON DEVICES FOR QUANTUM COMPUTING." International Journal of Modern Physics B 17, no. 04n06 (March 10, 2003): 675–79. http://dx.doi.org/10.1142/s021797920301642x.

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Computing tools, all based on classical logic at the moment, present intrinsic limitations that can be overcome by using quantum logic. In this direction, superconducting Josephson devices have been proved to be very suitable candidates for the realization of quantum computing tools. We present some basic elements of quantum computing, possible strategies for the implementation of quantum gates by using Josephson devices, and recent experimental results in this field.
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7

De Luca, R. "Equivalent Single-Junction Model of Superconducting Quantum Interference Devices in the Presence of Time-Varying Fields." ISRN Condensed Matter Physics 2011 (November 30, 2011): 1–5. http://dx.doi.org/10.5402/2011/724384.

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The reduced dynamical model of a two-junction quantum interference device is generalized to the case of time-varying externally applied fluxes with a d. c. component and an oscillating addendum whose frequency is comparable with the inverse of the characteristic time for flux dynamics within the superconducting system. From the resulting effective single-junction model for null inductance of the superconducting loop, it can be seen that the critical current of the device shows a dependence on the frequency and amplitude of the oscillating part of the applied flux. It can therefore be argued that the latter quantities can be considered as control parameters in the voltage versus applied flux curves of superconducting quantum interference devices.
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8

Pegrum, Colin. "Modelling high- Tc electronics." Superconductor Science and Technology 36, no. 5 (March 9, 2023): 053001. http://dx.doi.org/10.1088/1361-6668/acbb35.

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Abstract This Review examines methods to model Josephson devices such as arrays of superconducting quantum interference devices (SQUIDs) and rows within two-dimensional superconducting quantum interference filters or SQIFs. The emphasis is on high temperature superconducting (HTS) devices, though the techniques apply for any operating temperature. The methods use freely-available and proven software to first extract all self and mutual inductances of the thin-film device, and then to incorporate these data, plus junction models and thermal noise sources into an equivalent circuit for Josephson simulation. The inductance extraction stage also estimates the effective areas of each loop in a structure and also the variation of inductance as temperature changes, due to the varying penetration depth. The final post-processing stage can yield current–voltage, voltage-field and field spectral density responses. The Review also touches briefly on the simulation of a simple model for a terahertz single-junction HTS mixer and also looks at the behaviour of typical hysteretic and non-hysteric HTS RF SQUIDs.
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9

Mutsenik, E., S. Linzen, E. Il’ichev, M. Schmelz, M. Ziegler, V. Ripka, B. Steinbach, G. Oelsner, U. Hübner, and R. Stolz. "Superconducting NbN-Al hybrid technology for quantum devices." Low Temperature Physics 49, no. 1 (January 2023): 92–95. http://dx.doi.org/10.1063/10.0016481.

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The high kinetic inductance of niobium nitride (NbN) thin films can be used for an implementation of compact on-chip inductances in cryoelectronic circuits. Here, for the first time, we demonstrate the implementation of a hybrid superconducting technology that includes the fabrication of standard aluminum submicron Josephson junctions and the NbN atomic layer deposition process. As an example, we fabricated and characterized a single and array of Al Josephson junctions together with NbN interconnections. The main Al Josephson junction parameters as well as NbN superconducting properties are in a good agreement with the values obtained by our standard fabrication process. The combination of technological processes for the NbN layers with Al Josephson junction allows implementing a new generation of innovative superconducting devices for different applications.
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Vettoliere, Antonio, and Carmine Granata. "Picoammeters Based on Gradiometric Superconducting Quantum Interference Devices." Applied Sciences 12, no. 18 (September 8, 2022): 9030. http://dx.doi.org/10.3390/app12189030.

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High-sensitivity ac current sensors based on a superconducting quantum interference device have been designed, fabricated and characterized. In particular, double-washer schemes in either parallel or series configurations have been considered. The advantages and the drawbacks of both configurations have been examined by measuring the main features and parameters, such as the flux-to-voltage characteristic, the magnetic field spectral noise and flux-to-current transfer factor. The devices are designed to have similar flux-to-current transfer factors and are fabricated on the same chip to avoid differences in parameters due to the fabrication process. Both devices exhibited a current sensitivity as low as 1–2 pA per bandwidth unit, allowing for their use in ultrahigh-sensitivity applications.
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Дисертації з теми "Superconducting quantum devices"

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Baker, Luke James. "Superconducting nanowire devices for optical quantum information processing." Thesis, University of Glasgow, 2018. http://theses.gla.ac.uk/8440/.

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Near infrared photons are a promising choice for quantum information processing; their low transmission loss is necessary for applications such as long distance Quantum Key Distribution (QKD) in optical fibre and integrated quantum optics. An ideal proof-of-concept test of such applications would be to create, manipulate and detect single photons on a monolithic chip. Superconducting nanowire single photon detectors promise high system detection efficiencies, low dark count and low jitter under near-infrared photon illumination. Superconducting nanowire devices using NbTiN films show improved coupling efficiencies with the aid of oxidized silicon cavities. NbTiN devices were characterised in a fibre-coupled package, achieving high SDE (43%) coherent key generation rates over 200km in a T12 QKD protocol simulation. Hairpin superconducting nanowires offer excellent integration with silicon waveguide optics and can achieve near unity absorption efficiencies. Hairpin devices fabricated from MoSi films were characterised using a custom pulse tube He-3 cryostat engineered for low vibration operation at 350mK and capable of near-infrared optical maps of superconducting nanowires. The devices exhibited high critical currents 40uA), low jitter (51ps) and a dark count rate <10cps. Tests of perpendicular coupling efficiencies yield low system detection efficiencies due to high coupling losses. Using an alternative coupling method via grating couplers or cleave mounting, it is expected a much higher system detection efficiency can be achieved.
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Judge, Elizabeth Eileen. "Direct measurement of dissipative forces in superconducting BSCCO." Access restricted to users with UT Austin EID Full text (PDF) from UMI/Dissertation Abstracts International, 2001. http://wwwlib.umi.com/cr/utexas/fullcit?p3035957.

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Akram, Uzma. "Quantum interference and cavity QED effects in a V-system /." [St. Lucia, Qld.], 2003. http://www.library.uq.edu.au/pdfserve.php?image=thesisabs/absthe17140.pdf.

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Kilian, Anton Theo. "3-Axis geomagnetic magnetometer system design using superconducting quantum interference devices." Thesis, Stellenbosch : Stellenbosch University, 2014. http://hdl.handle.net/10019.1/86452.

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Thesis (MScEng)--Stellenbosch University, 2014.
ENGLISH ABSTRACT: This work discusses the design of a 3-axis Geomagnetometer SQUID System (GSS), in which HTS SQUIDs are used unshielded. The initial GSS installed at SANSA was fully operable, however the LN2 evaporation rate and SQUID orientation required improving. Magnetic shields were also developed in case the SQUIDs would not operate unshielded and to test the system noise with geomagnetic variations removed. To enable removing the double layer shield from the probes while the SQUIDs remain submerged in LN2, the shield was designed to disassemble. The shields proved to be effective, however due to icing the shields could not be removed without removing the SQUIDs from the LN2.
AFRIKAANSE OPSOMMING: Hierdie werk bespreek die ontwerp van 'n 3-as Geomagnetometer SQUID Sisteem (GSS), waarin HTS SQUIDs sonder magnetiese skilde aangedryf word. Die aanvanklike GSS geïnstalleer by SANSA was ten volle binnewerking, maar die LN2 verdamping en SQUID oriëntasie benodig verbetering. Magnetiese skilde was ook ontwikkel vir die geval dat die SQUIDs nie sonder skilde wou werk nie en om die ruis te toets na geomagnetiese variasies verwyder is. Die dubbele laag skild was ontwerp om uitmekaar gehaal te word terwyl die SQUIDs binne die LN2 bly. Die skild was doeltreffend, maar ys het verhoed dat die skild verwyder kon word vanaf die LN2 sonder om die SQUIDs ook te verwyder.
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Abi-Salloum, Tony Y. Narducci L. M. "Interference between competing pathways in the interaction of three-level atoms and radiation /." Philadelphia, Pa. : Drexel University, 2006. http://dspace.library.drexel.edu/handle/1860%20/858.

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Marthaler, Michael [Verfasser], and G. [Akademischer Betreuer] Schön. "Study of Quantum Electrodynamics in Superconducting Devices / Michael Marthaler. Betreuer: G. Schön." Karlsruhe : KIT-Bibliothek, 2009. http://d-nb.info/1014099854/34.

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Graf, zu Eulenburg Alexander. "High temperature superconducting thin films and quantum interference devices (SQUIDs) for gradiometers." Thesis, University of Strathclyde, 1999. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.366689.

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Egger, Daniel J. [Verfasser], and Frank K. [Akademischer Betreuer] Wilhelm-Mauch. "Optimal control and quantum simulations in superconducting quantum devices / Daniel J. Egger. Betreuer: Frank K. Wilhelm-Mauch." Saarbrücken : Saarländische Universitäts- und Landesbibliothek, 2014. http://d-nb.info/1060715961/34.

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9

Podd, Gareth James. "MicroSQUIDs with independently controlled Josephson junctions." Thesis, University of Cambridge, 2007. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.613267.

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Ogunyanda, Kehinde. "A superconducting quantum interference device (SQUID) magnetometer for nanosatellite space weather missions." Thesis, Cape Peninsula University of Technology, 2012. http://hdl.handle.net/20.500.11838/1164.

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Thesis submitted in fulfilment of the requirements for the degree Master of Technology: Electrical Engineering in the Faculty of Engineering at the Cape Peninsula University of Technology, 2012
In order to effectively determine the occurrences of space weather anomalies in near Earth orbit, a highly sensitive space-grade magnetometer system is needed for measuring changes in the Earth’s magnetic field, which is the aftermath of space weather storms. This research is a foundational work, aimed at evaluating a commercial-off-the-shelf (COTS) high temperature DC SQUID (superconducting quantum interference device) magnetometer, and establishing the possibility of using it for space weather applications. A SQUID magnetometer is a magnetic field measuring in strument that produces an electrical signal relative to the sensed external magnetic field intensity.
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Книги з теми "Superconducting quantum devices"

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Hadfield, Robert H., and Göran Johansson, eds. Superconducting Devices in Quantum Optics. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-24091-6.

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2

1939-, Barone Antonio, ed. Principles and applications of superconducting quantum interference devices. Singapore: World Scientific, 1992.

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3

1934-, Weinstock Harold, and NATO Advanced Study Institute on SQUID Sensors: Fundamentals, Febrication, and Appliations (1995 : Acquafredda di Maratea, Italy), eds. SQUID sensors: Fundamentals, fabrication, and applications. Dordrecht: Kluwer Academic Publishers, 1996.

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1930-, Hahlbohm H. D., and Lübbig H. 1932, eds. SQUID '85, superconducting quantum interference devices and their applications: Proceedings of the Third International Conference on Superconducting Quantum Devices, Berlin (West), June 25-28, 1985. Berlin: W. de Gruyter, 1985.

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5

Keene, Mark Nicholas. The electrical and magnetic properties of superconducting quantum interference devices. Birmingham: University of Birmingham, 1988.

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6

J, Clarke, and Braginski A. I, eds. The SQUID handbook. Weinheim: Wiley-VCH, 2004.

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7

L, Kautz R., and National Institute of Standards and Technology (U.S.), eds. SQUIDs past, present, and future: A symposium in honor of James E. Zimmerman. Gaithersburg, MD: U.S. Dept. of Commerce, Technology Administration, National Institute of Standards and Technology, 2000.

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8

Harrop, Sean Patrick. Magnetic noise properties of ceramic high temperature superconducting quantum interference devices. Birmingham: University of Birmingham, 1991.

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9

Vleeming, Bertus Johan. The four-terminal SQUID. [Leiden: University of Leiden, 1998.

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Francesco, De Martini, Denardo G. 1935-, Zeilinger Anton, International Centre for Theoretical Physics., International Atomic Energy Agency, and Unesco, eds. Proceedings of the Adriatico Workshop on Quantum Interferometry: 2-5 March 1993, Trieste, Italy. Singapore: World Scientific, 1994.

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Частини книг з теми "Superconducting quantum devices"

1

Rogalla, H., and C. Heiden. "High-Tc Josephson Contacts and Devices." In Superconducting Quantum Electronics, 80–127. Berlin, Heidelberg: Springer Berlin Heidelberg, 1989. http://dx.doi.org/10.1007/978-3-642-95592-1_4.

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2

Annett, James F., Balazs L. Gyorffy, and Timothy P. Spiller. "Superconducting Devices for Quantum Computation." In Exotic States in Quantum Nanostructures, 165–212. Dordrecht: Springer Netherlands, 2002. http://dx.doi.org/10.1007/978-94-015-9974-0_5.

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Partanen, M., K. Y. Tan, S. Masuda, E. Hyyppä, M. Jenei, J. Goetz, V. Sevriuk, M. Silveri, and M. Möttönen. "Quantum-Circuit Refrigeration for Superconducting Devices." In 21st Century Nanoscience – A Handbook, 12–1. Boca Raton, Florida : CRC Press, [2020]: CRC Press, 2020. http://dx.doi.org/10.1201/9780429351594-12.

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Tinkham, M. "Superconducting Nanoparticles and Nanowires." In Quantum Mesoscopic Phenomena and Mesoscopic Devices in Microelectronics, 349–60. Dordrecht: Springer Netherlands, 2000. http://dx.doi.org/10.1007/978-94-011-4327-1_23.

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5

Averin, D. V. "Quantum Nondemolition Measurements of a Qubit." In International Workshop on Superconducting Nano-Electronics Devices, 1–10. Boston, MA: Springer US, 2002. http://dx.doi.org/10.1007/978-1-4615-0737-6_1.

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Corato, Valentina, Carmine Granata, Luigi Longobardi, Maurizio Russo, Berardo Ruggiero, and Paolo Silvestrini. "Josephson Systems for Quantum Coherence Experiments." In International Workshop on Superconducting Nano-Electronics Devices, 33–41. Boston, MA: Springer US, 2002. http://dx.doi.org/10.1007/978-1-4615-0737-6_5.

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7

Tamura, Kentaro, and Yutaka Shikano. "Quantum Random Numbers Generated by a Cloud Superconducting Quantum Computer." In International Symposium on Mathematics, Quantum Theory, and Cryptography, 17–37. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5191-8_6.

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Abstract A cloud quantum computer is similar to a random number generator in that its physical mechanism is inaccessible to its users. In this respect, a cloud quantum computer is a black box. In both devices, its users decide the device condition from the output. A framework to achieve this exists in the field of random number generation in the form of statistical tests for random number generators. In the present study, we generated random numbers on a 20-qubit cloud quantum computer and evaluated the condition and stability of its qubits using statistical tests for random number generators. As a result, we observed that some qubits were more biased than others. Statistical tests for random number generators may provide a simple indicator of qubit condition and stability, enabling users to decide for themselves which qubits inside a cloud quantum computer to use.
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8

Korotkov, Alexander. "Bayesian Quantum Measurement of a Single-Cooper-Pair Qubit." In International Workshop on Superconducting Nano-Electronics Devices, 11–13. Boston, MA: Springer US, 2002. http://dx.doi.org/10.1007/978-1-4615-0737-6_2.

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Semenov, Alexei D., Heinz-Wilhelm Hübers, Gregory N. Gol’tsman, and Konstantin Smirnov. "Superconducting Quantum Detector for Astronomy and X -Ray Spectroscopy." In International Workshop on Superconducting Nano-Electronics Devices, 201–10. Boston, MA: Springer US, 2002. http://dx.doi.org/10.1007/978-1-4615-0737-6_22.

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Campagnano, G., D. Giuliano, and A. Tagliacozzo. "Josephson Versus Kondo Coupling at A Quantum Dot With Superconducting Contacts." In International Workshop on Superconducting Nano-Electronics Devices, 227–39. Boston, MA: Springer US, 2002. http://dx.doi.org/10.1007/978-1-4615-0737-6_25.

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Тези доповідей конференцій з теми "Superconducting quantum devices"

1

Dumke, Rainer, Deshui Yu, Christoph Hufnagel, Alessandro Landra, and Lim Chin Chean. "Superconducting atom chips: towards quantum hybridization." In Quantum Photonic Devices, edited by Mario Agio, Kartik Srinivasan, and Cesare Soci. SPIE, 2017. http://dx.doi.org/10.1117/12.2275929.

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2

Höpker, Jan Philipp, Moritz Bartnick, Evan Meyer-Scott, Frederik Thiele, Torsten Meier, Tim Bartley, Stephan Krapick, et al. "Towards integrated superconducting detectors on lithium niobate waveguides." In Quantum Photonic Devices, edited by Mario Agio, Kartik Srinivasan, and Cesare Soci. SPIE, 2017. http://dx.doi.org/10.1117/12.2273388.

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Nakamura, Y. "Engineering superconducting quantum circuits." In 2019 International Conference on Solid State Devices and Materials. The Japan Society of Applied Physics, 2019. http://dx.doi.org/10.7567/ssdm.2019.e-1-01.

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4

Janicek, Frantisek, Anton Cerman, Milan Perny, Igor Brilla, Lubomir Marko, and Stefan Motycak. "Applications of superconducting quantum interference devices." In 2015 16th International Scientific Conference on Electric Power Engineering (EPE). IEEE, 2015. http://dx.doi.org/10.1109/epe.2015.7161204.

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5

Pernice, Wolfram H. P., and Wladick Hartmann. "Cavity-enhanced superconducting single photon detectors (Conference Presentation)." In Quantum Photonic Devices 2018, edited by Mario Agio, Kartik Srinivasan, and Cesare Soci. SPIE, 2018. http://dx.doi.org/10.1117/12.2323861.

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6

Kandala, Abhinav. "Quantum computation with superconducting qubits." In 2020 International Conference on Solid State Devices and Materials. The Japan Society of Applied Physics, 2020. http://dx.doi.org/10.7567/ssdm.2020.i-4-01.

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7

Tong, Yukai, Changlong Zhu, Xueqian Wang, and Jing Zhang. "Controlling chaos in superconducting quantum interference devices." In 2017 36th Chinese Control Conference (CCC). IEEE, 2017. http://dx.doi.org/10.23919/chicc.2017.8027478.

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8

Nersisyan, Ani, Eyob A. Sete, Sam Stanwyck, Andrew Bestwick, Matthew Reagor, Stefano Poletto, Nasser Alidoust, et al. "Manufacturing low dissipation superconducting quantum processors." In 2019 IEEE International Electron Devices Meeting (IEDM). IEEE, 2019. http://dx.doi.org/10.1109/iedm19573.2019.8993458.

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9

Van Duzer, T. "Single-flux-quantum logic." In Progress in High-Temperature Superconducting Transistors and Other Devices II. SPIE, 1992. http://dx.doi.org/10.1117/12.2321840.

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Morozov, Dmitry V., Gregor G. Taylor, Kleanthis Erotokritou, Shigehito Miki, Hirotaka Terai, and Robert H. Hadfield. "Mid-infrared photon counting with superconducting nanowires." In Quantum Nanophotonic Materials, Devices, and Systems 2021, edited by Mario Agio, Cesare Soci, and Matthew T. Sheldon. SPIE, 2021. http://dx.doi.org/10.1117/12.2597196.

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Звіти організацій з теми "Superconducting quantum devices"

1

Orlando, Terry P. Quantum Computation with Superconducting Quantum Devices. Fort Belvoir, VA: Defense Technical Information Center, April 2008. http://dx.doi.org/10.21236/ada480997.

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2

Orlando, T. P., J. E. Mooij, and Seth Lloyd. Quantum Computation With Mesoscopic Superconducting Devices. Fort Belvoir, VA: Defense Technical Information Center, May 2002. http://dx.doi.org/10.21236/ada414413.

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3

Orlando, Terry P. Student Support for Quantum Computation With Superconducting Quantum Devices. Fort Belvoir, VA: Defense Technical Information Center, January 2005. http://dx.doi.org/10.21236/ada430138.

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4

Han, Siyuan. (DEPSCOR 99) Experimental Investigation of Superconducting Quantum Interference Devices as Solid State Qubits for Quantum Computing. Fort Belvoir, VA: Defense Technical Information Center, October 2002. http://dx.doi.org/10.21236/ada416906.

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5

Nordman, James E. Superconductive Electronic Devices Using Flux Quanta. Fort Belvoir, VA: Defense Technical Information Center, February 1996. http://dx.doi.org/10.21236/ada310962.

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6

Drukier, A. K., N. Cao, and K. Carroll. Computer-Oriented, Multichannel, Direct-Current, Superconducting Quantum Interference Device. Fort Belvoir, VA: Defense Technical Information Center, May 1989. http://dx.doi.org/10.21236/ada222636.

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7

NEOCERA INC COLLEGE PARK MD. High Temperature Superconductor (HTS) Superconducting QUantum Interference Device (SQUID) Microscope. Fort Belvoir, VA: Defense Technical Information Center, October 1994. http://dx.doi.org/10.21236/ada285875.

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8

Kinion, D. Development of a Quantum-Limited Microwave Amplifier using a dc Superconducting Quantum Interference Device (dc-SQUID). Office of Scientific and Technical Information (OSTI), December 2006. http://dx.doi.org/10.2172/1036875.

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9

Myers, Whittier Ryan. Potential Applications of Microtesla Magnetic Resonance ImagingDetected Using a Superconducting Quantum Interference Device. Office of Scientific and Technical Information (OSTI), January 2006. http://dx.doi.org/10.2172/901227.

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10

Krauss, R. H. Jr, E. Flynn, and P. Ruminer. Experimental validation of superconducting quantum interference device sensors for electromagnetic scattering in geologic structures. Office of Scientific and Technical Information (OSTI), October 1997. http://dx.doi.org/10.2172/532685.

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