DC and RF Measurements of Serial Bi-SQUID Arrays

Prokopenko, G.I.; Mukhanov, Oleg A.; Escobar, Anna Leese de; Taylor, B. J.; Andrade, M. C. de; Berggren, Susan; Longhini, Patrick; Palacios, Antonio Lozano; Nisenoff, M.; Fagaly, R.L.

doi:10.1109/tasc.2012.2235171

Cited by 42 publications

(18 citation statements)

References 46 publications

(29 reference statements)

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“…This relation is truly valid only at l << 1 when the pulse component is negligibly small and, together with one of the "phase" equations (8) or (11), describes voltage response of either dc SQID or bi-SQUID at the limit as explicit and implicit functions, correspondingly.…”

Section: Phase-to-voltage Transformationmentioning

confidence: 99%

Signal and noise characteristics of bi-SQUID

Kornev

Sharafiev

Soloviev

et al. 2014

Supercond. Sci. Technol.

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We present an improved analytic theory, numerical simulation, and analysis of noise characteristics of a bi-SQUID in comparison with those of a dc SQUID in an open loop configuration. The analytic theory which had been developed earlier neglecting a pulse component of the difference of the phases of Josephson junctions is now completed with taking into account the pulse component. In the bi-SQUID, the additional Josephson junction introduces an additional source of fluctuations as well as changes its transfer function, nonlinear dynamics, and the noise spectrum transformation. Some increase in the reduced-to-input noise at low values of applied magnetic flux comes from the nonlinear flux to phase difference transformation introduced in bi-SQUID as a way to linearize its voltage response.

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Section: Phase-to-voltage Transformationmentioning

confidence: 99%

Signal and noise characteristics of bi-SQUID

Kornev

Sharafiev

Soloviev

et al. 2014

Supercond. Sci. Technol.

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“…One can mention broadband lownoise amplifiers (e.g., see design approaches in [4,5]) as well as broadband active electrically small antennas (ESAs) capable of providing concurrent receiving and amplification of the broadband electromagnetic signals. The SQAs are also beneficial for many applications, in which SQUIDs and SQUID arrays are being used [1,2,36].…”

Section: Resultsmentioning

confidence: 99%

“…Integrating such a SQA with a broadband input line to apply an input magnetic signal to all array cells (see, for example, the designs proposed in [4,5]), one can design a high-performance broadband amplifier. Moreover, an active electrically small antenna (ESA) can be developed on the basis of SQA to implement simultaneously broadband reception and amplification of electromagnetic signals.…”

Section: Introductionmentioning

confidence: 99%

From single SQUID to superconducting quantum arrays

Kornev

Kolotinskiy

Sharafiev

et al. 2017

Low Temperature Physics

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Superconducting quantum arrays (SQAs) capable of providing highly linear voltage response to magnetic signal and high dynamic range have been suggested and developed. Base elements of the arrays, quantum cells, were devised and studied in detail. Using niobium process, SQAs with different number of the cells and prototypes of the SQA-based broadband active electrically small antennas were fabricated and tested.

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“…Thus, the effective bandwidth of the SQUID can have significant improvement by using this bi‐SQUID architecture . Serial arrays of such bi‐SQUID structure can be designed to improve the device characteristics with emphasis on its dynamic range …”

Section: Recent Progress In Applications Of Hts and Their Integrationmentioning

confidence: 99%

Thin‐Film‐Based Integrated High‐Transition‐Temperature Superconductor Devices

Balasubramanian

Xing

Strugo

et al. 2019

Adv Funct Materials

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Since the discovery of superconductivity at temperatures above the technologically promising liquid nitrogen temperatures, applications based on superconductors have expanded and are being put to commercial use. However, superconductivity at higher temperatures typically occurs in complex materials requiring stringent material and environmental constraints. Such restraints make the realization and integration of these materials with normal materials a nontrivial aspect. In this progress report, unique features of these superconductors in terms of their synthesis, physical properties determining interface electrical transport, and their applications are discussed. A detailed progress report on these applications with remarks on efforts taken to integrate these devices with traditional platforms and semiconducting materials is provided.

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DC and RF Measurements of Serial Bi-SQUID Arrays

Cited by 42 publications

References 46 publications

Signal and noise characteristics of bi-SQUID

Signal and noise characteristics of bi-SQUID

From single SQUID to superconducting quantum arrays

Thin‐Film‐Based Integrated High‐Transition‐Temperature Superconductor Devices

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