H. Nijstad scite author profile

H. Nijstad

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University of Twente

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(Double) relaxation oscillation SQUIDs with high flux-to-voltage transfer: Simulations and experiments

Adelerhof¹,

Nijstad²,

Flokstra³

et al. 1994

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Relaxation oscillation superconducting quantum interference devices (SQUIDs) (ROSs) and double relaxation oscillation SQUIDs (DROSs) have been fabricated and characterized. The SQUIDs are based on hysteretic Nb/Al,AlOx/Al/Nb Josephson tunnel junctions. The relaxation oscillations were simulated by computer. By these simulations the minimum and maximum values of the shunt inductance at which the relaxation oscillations persist have been determined for different values of the shunt resistance and of the critical current and capacitance of the junctions. The transfer from flux to dc voltage in ROSs increases linearly with the shunt resistance. The operation range of the shunt inductance, however, becomes smaller with increasing shunt resistance. In ROSs with a SQUID inductance of 20 pH, a maximum voltage modulation width of 400 μV and a flux-to-voltage transfer δV/δφ of 4 mV/φ0 have been obtained. Two ROSs have been operated in a simple flux-locked loop with direct voltage readout. The experimental white flux noise spectral density of about 3μφ0/√Hz is in good agreement with the theoretical model. The sensitivity of these SQUIDs is limited by so-called switching noise, which is noise due to the interaction between the relaxation oscillations and the Josephson frequency. In DROSs typical flux-to-voltage transfer values of 10–30 mV/φ0 and maximum values up to 80 mV/φ0 have been obtained. This transfer is determined by thermal noise on the critical currents of the SQUIDs. The effective flux noise density of DROSs in flux-locked-loop operation with direct voltage readout is in good agreement with the theoretical noise level which is mainly determined by thermal noise on the critical currents. In one of the DROSs with a SQUID inductance of 20 pH, a white flux noise of 1μφ0/√Hz has been obtained at an estimated relaxation frequency of about 80 MHz. This corresponds to an energy sensitivity of about 160 h.

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Relaxation oscillation SQUIDs with high delta V/ delta Phi

Adelerhof

Nijstad

Flokstra

et al. 1993

IEEE Trans. Appl. Supercond.

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Relaxation Oscillation SQUIDs (ROSs) based on Nb/Al,AlO,/AVNb Josephson tunnel junctions have been designed and fabricated. The hysteretic SQUIDs have a maximum critical current of about 130 pA and an inductance of 20 pH. A voltage modulation of 400 pV and a flux to voltage transfer SV/6@ of 4 mV/@, have been measured in these SQUIDs. Double Relaxation Oscillation SQUIDs (DROSs), which are based on two hysteretic SQUIDs, showed transfer coefficients up to 77 mV/@,. The intrinsic white flux noise of the DROSs is smaller than 3-5 p@JdHz. The results are very promising for a next generation of SQUID systems with simplified read-out.

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H. Nijstad

(Double) relaxation oscillation SQUIDs with high flux-to-voltage transfer: Simulations and experiments

Relaxation oscillation SQUIDs with high delta V/ delta Phi

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