2018
DOI: 10.1007/s10948-018-4884-4
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Superconductor Electronics: Status and Outlook

Abstract: Superconductor electronics combines passive and active superconducting components and sometimes normal resistors into functional circuits and systems that also include room-temperature electronics for amplification, power sources, necessary controls, etc., usually computer operated. Furthermore, complete systems include magnetic and electromagnetic shielding, cryogenic enclosures, and increasingly a cryocooler in self-contained units. Components or devices of low or high critical temperature superconductors in… Show more

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Cited by 116 publications
(65 citation statements)
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References 124 publications
(156 reference statements)
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“…Underlying physics should allow such elements to overcome the constraints inherent to the complementary metal-oxide-semiconductor (CMOS) electronics. Superconducting logic devices are candidates for supercomputer applications due to their high operating frequency and ultralow energy consumption [ 6 , 7 , 8 , 9 , 10 ]. The conventional Josephson junction [ 11 , 12 ], in which the superconducting current flows due to the phase difference between two superconducting electrodes, is the basic element of superconducting circuits such as single-flux quantum logic (SFQ) [ 13 , 14 ], quantum flux parametron [ 15 , 16 ], reciprocal quantum logic [ 17 , 18 ], and adiabatic superconductor logic [ 19 ].…”
Section: Introductionmentioning
confidence: 99%
“…Underlying physics should allow such elements to overcome the constraints inherent to the complementary metal-oxide-semiconductor (CMOS) electronics. Superconducting logic devices are candidates for supercomputer applications due to their high operating frequency and ultralow energy consumption [ 6 , 7 , 8 , 9 , 10 ]. The conventional Josephson junction [ 11 , 12 ], in which the superconducting current flows due to the phase difference between two superconducting electrodes, is the basic element of superconducting circuits such as single-flux quantum logic (SFQ) [ 13 , 14 ], quantum flux parametron [ 15 , 16 ], reciprocal quantum logic [ 17 , 18 ], and adiabatic superconductor logic [ 19 ].…”
Section: Introductionmentioning
confidence: 99%
“…Both lowtemperature and high-temperature superconductor (LTS and HTS) technology provide a possibility to fabricate SQUID arrays with the number of Josephson junctions about a million [4,5]. This expands the area of SQUID applications to the one where SQUID-based structures should ideally act as a linear magnetic fluxto-voltage transformers [5][6][7][8][9][10][11]: from electrically small antennas to analog-to-digital convertor circuits and from susceptometers to SQUID-based multiplexers.…”
Section: Introductionmentioning
confidence: 99%
“…Finally we measure degenerate parametric conversion for a 95 GHz device with a forward efficiency up to +16 dB, paving the way for the development of nonlinear quantum devices at millimeter-wave frequencies.For superconducting quantum circuits, the millimeterwave spectrum presents a fascinating frequency regime between microwaves and optics, giving access to a wider range of energy scales, and lower sensitivity to thermal background noise due to higher photon energies. Many advances have been made refining microwave quantum devices [1,2], typically relying on ultra-low temperatures in the millikelvin range to reduce sources of noise and quantum decoherence. Using millimeter-wave photons as building blocks for superconducting quantum devices offers transformative opportunities by allowing quantum experiments to be run at liquid Helium-4 temperatures, allowing higher device power dissipation and enabling large scale direct integration with semiconductor devices [2].…”
mentioning
confidence: 99%
“…Many advances have been made refining microwave quantum devices [1,2], typically relying on ultra-low temperatures in the millikelvin range to reduce sources of noise and quantum decoherence. Using millimeter-wave photons as building blocks for superconducting quantum devices offers transformative opportunities by allowing quantum experiments to be run at liquid Helium-4 temperatures, allowing higher device power dissipation and enabling large scale direct integration with semiconductor devices [2]. Millimeter-wave quantum devices could also provide new routes for studying strong-coupling light-matter interactions in this frequency regime [3][4][5][6][7], and present new opportunities for quantum-limited frequency conversion and detection [8,9].Recent interest in next-generation communication devices [10, 11] has led to important advances in sensitive millimeter-wave measurement technology around 100 GHz.…”
mentioning
confidence: 99%