SKIFFS: Superconducting Kinetic Inductance Field-Frequency Sensors for sensitive magnetometry in moderate background magnetic fields

Asfaw, Abraham; Kleinbaum, Ethan; Hazard, Thomas; Gyenis, András; Houck, Andrew; Lyon, S. A.

doi:10.1063/1.5049615

Cited by 3 publications

(6 citation statements)

References 36 publications

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“…When the loop is incorporated into a resonator, the change in kinetic inductance can be seen as a shift in resonance, ω r = 1/ √ LC. [5] [12] [13] TL TL…”

Section: Operating Principlesmentioning

confidence: 99%

Development of an Array of Kinetic Inductance Magnetometers (KIMs)

Sypkens,

Faramarzi,

Colangelo

et al. 2021

Preprint

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We describe optimization of a cryogenic magnetometer that uses nonlinear kinetic inductance in superconducting nanowires as the sensitive element instead of a superconducting quantum interference device (SQUID). The circuit design consists of a loop geometry with two nanowires in parallel, serving as the inductive section of a lumped LC resonator similar to a kinetic inductance detector (KID). This device takes advantage of the multiplexing capability of the KID, allowing for a natural frequency multiplexed readout. The Kinetic Inductance Magnetometer (KIM) is biased with a DC magnetic flux through the inductive loop. A perturbing signal will cause a flux change through the loop, and thus a change in the induced current, which alters the kinetic inductance of the nanowires, causing the resonant frequency of the KIM to shift. This technology has applications in astrophysics, material science, and the medical field for readout of Metallic Magnetic Calorimeters (MMCs), axion detection, and magnetoencephalography (MEG).

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“…When the loop is incorporated into a resonator, the change in kinetic inductance can be seen as a shift in resonance, ω r = 1/ √ LC. [5] [12] [13] TL TL…”

Section: Operating Principlesmentioning

confidence: 99%

Development of an Array of Kinetic Inductance Magnetometers (KIMs)

Sypkens,

Faramarzi,

Colangelo

et al. 2021

Preprint

View full text Add to dashboard Cite

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“…Each device harnesses a certain type of a non-linearity of the kinetic inductance L k , such as that induced by temperature, electric current, or non-equilibrium quasiparticles. In sensor applications, radio-frequency (rf) techniques are often employed in observation of the variations of L k : a high sensitivity follows from the intrinsically low dissipation of the superconductors, manifesting itself as a high quality factor of resonator circuits, for example.The general advantages common to all L k sensors have motivated the development of kinetic inductance magnetometers (KIMs), devices that combine the L k current non-linearity with magnetic flux quantization 8,9 . In comparison to the most established category of sensitive magnetometers, i.e., superconducting quantum interference devices (SQUIDs), KIMs have certain benefits.…”

mentioning

confidence: 99%

“…The general advantages common to all L k sensors have motivated the development of kinetic inductance magnetometers (KIMs), devices that combine the L k current non-linearity with magnetic flux quantization 8,9 . In comparison to the most established category of sensitive magnetometers, i.e., superconducting quantum interference devices (SQUIDs), KIMs have certain benefits.…”

mentioning

confidence: 99%

“…Then, the inductance variation translates into a changing resonance frequency, a quantity which is probed by coupling the resonator weakly into a 50-Ω readout feedline. Two KIMs of this kind have recently been reported: the materials of choice have been NbN 8 and NbTiN 9 , both of which are low-T c superconductors whose disordered nature provides a magnetic penetration depth 15 λ exceeding several hundreds of nm.…”

mentioning

confidence: 99%

“…In conclusion, we have demonstrated high-T c kinetic inductance magnetometers with a sensitivity of 4 pT/ √ Hz at 10 kHz and T = 77 K. They tolerate background fields of 9 − 28 µT, which is close to the Earth's field. We anticipate that changing the sensor geometry by implementing narrow constrictions 9 to reduce I c should allow for periodical resets, enabling operation at even higher fields. The constrictions should also help to increase the kinetic inductance fraction, a likely route towards a higher device responsivity.…”

mentioning

confidence: 99%

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Magnetic field sensing with the kinetic inductance of a high-Tc superconductor

et al. 2019

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We carry out an experimental feasibility study of a magnetic field sensor based on the kinetic inductance of the high-T c superconductor yttrium barium copper oxide. We pattern thin superconducting films into radiofrequency resonators that feature a magnetic field pick-up loop. At 77 K and for film thicknesses down to 75 nm, we observe the persistence of screening currents that modulate the loop kinetic inductance. According to the experimental results the device concept appears attractive for sensing applications in ambient magnetic field environments. We report on a device with a magnetic field sensitivity of 4 pT/ √ Hz, an instantaneous dynamic range of 11 µT, and operability in magnetic fields up to 28 µT.The kinetic inductance of superconductors has found many applications in fields as diverse as bolometry 1,2 , parametric amplification 3,4 , current detectors 5 , and sensing of electromagnetic radiation 6,7 , to name but a few. Each device harnesses a certain type of a non-linearity of the kinetic inductance L k , such as that induced by temperature, electric current, or non-equilibrium quasiparticles. In sensor applications, radio-frequency (rf) techniques are often employed in observation of the variations of L k : a high sensitivity follows from the intrinsically low dissipation of the superconductors, manifesting itself as a high quality factor of resonator circuits, for example.The general advantages common to all L k sensors have motivated the development of kinetic inductance magnetometers (KIMs), devices that combine the L k current non-linearity with magnetic flux quantization 8,9 . In comparison to the most established category of sensitive magnetometers, i.e., superconducting quantum interference devices (SQUIDs), KIMs have certain benefits. KIM fabrication involves only a single-layer process that avoids Josephson junctions which are the central components of SQUIDs. Furthermore, KIMs typically have a higher dynamic range, and they enable operation in demanding ambient magnetic field conditions. KIMs also unlock the ability to use frequency multiplexing for the readout of large sensor arrays where each magnetometer has a dedicated eigenfrequency 6,10 .In this Letter, we demonstrate KIMs fabricated from yttrium barium copper oxide (YBCO). YBCO is a high-T c superconductor that enables KIM operability at elevated temperatures T , allowing for cooling with liquid nitrogen. Non-linear L k of YBCO has previously been evaluated for bolometric 2 (direct 7 ) detection of infrared (optical) radiation. A further benefit of the material is its a) visa.vesterinen@vtt.fi high tolerance against background magnetic fields, which has recently culminated in a YBCO rf resonator with a quality factor of about 10 4 at T < 55 K and at a magnetic flux density of 7 T applied parallel to the superconducting film 11 . From a sensitivity viewpoint, an important benchmark for our KIM are state-of-the-art YBCO SQUID magnetometers 12 that have a sensitivity better than 50 fT/ √ Hz. However, these SQUIDs suffer from a compli...

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