15 results on '"Maasilta, I. J."'
Search Results
2. Superconductor-ferromagnet hybrids for non-reciprocal electronics and detectors
- Author
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European Commission, Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Eusko Jaurlaritza, Geng, Zhuoran, Hijano, Alberto, Ilić, Stefan, Ilyn, Max, Maasilta, I. J., Monfardini, Alessandro, Spies, Maria, Strambini, Elia, Virtanen, Pauli, Calvo, Martino, González-Orellana, Carmen, Helenius, Ari P., Khorshidian, Sara, Levartoski de Araujo, Clodoaldo I., Levy-Bertrand, Florence, Rogero, Celia, Giazotto, Francesco, Bergeret, F. S., Heikkilä, T. T., European Commission, Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Eusko Jaurlaritza, Geng, Zhuoran, Hijano, Alberto, Ilić, Stefan, Ilyn, Max, Maasilta, I. J., Monfardini, Alessandro, Spies, Maria, Strambini, Elia, Virtanen, Pauli, Calvo, Martino, González-Orellana, Carmen, Helenius, Ari P., Khorshidian, Sara, Levartoski de Araujo, Clodoaldo I., Levy-Bertrand, Florence, Rogero, Celia, Giazotto, Francesco, Bergeret, F. S., and Heikkilä, T. T.
- Abstract
We review the use of hybrid thin films composed of superconductors and ferromagnets for creating non-reciprocal electronic components and self-biased detectors of electromagnetic radiation. We begin by introducing the theory behind these effects, as well as discussing various potential materials that can be used in the fabrication of these components. We then proceed with a detailed discussion on the fabrication and characterization of Al/EuS/Cu and EuS/Al/Co-based detectors, along with their noise analysis. Additionally, we suggest some approaches for multiplexing such self-biased detectors.
- Published
- 2023
3. Superconducting electromagnetic wave sensor
- Author
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Bergeret, F. S.[0000-0001-6007-4878], Giazotto, F. `0000-0002-1844-4393], Maasilta, I. J. [0000-0001-8566-1569], Bergeret, F. S., Giazotto, Francesco, Heikkilä, T. T., Maasilta, I. J., Bergeret, F. S.[0000-0001-6007-4878], Giazotto, F. `0000-0002-1844-4393], Maasilta, I. J. [0000-0001-8566-1569], Bergeret, F. S., Giazotto, Francesco, Heikkilä, T. T., and Maasilta, I. J.
- Abstract
An electromagnetic sensor for use in a variety of applications requiring extremely high sensitivity, such as measuring power and characteristics of incident electromagnetic radiation includes a superconducting layer that carries an exchange field for providing a spin splitting effect of charge carriers in the superconducting layer, a metal electrode, and an insulating layer arranged between the superconducting layer and metal electrode to form a spin filter junction therebetween. The electromagnetic sensor provides an antenna including a wave collecting element, in contact with the superconducting layer to convey thereinto external electromagnetic waves that are generated by an external source. An electric measurement device provides an output signal responsive to the amplitude and frequency of the external electromagnetic waves, and contacts the metal electrode to measure an electric current or voltage caused by the spin splitted charge carrier flow from the superconducting layer through the spin filter junction into the metal electrode
- Published
- 2021
4. Superconducting electromagnetic wave sensor
- Author
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Bergeret, F. S.[0000-0001-6007-4878], Giazotto, F. `0000-0002-1844-4393], Maasilta, I. J. [0000-0001-8566-1569], Bergeret, F. S., Giazotto, Francesco, Heikkilä, T. T., Maasilta, I. J., Bergeret, F. S.[0000-0001-6007-4878], Giazotto, F. `0000-0002-1844-4393], Maasilta, I. J. [0000-0001-8566-1569], Bergeret, F. S., Giazotto, Francesco, Heikkilä, T. T., and Maasilta, I. J.
- Abstract
[EN] An electromagnetic wave sensor (1) of extremely high sensitivity comprises a spin filter junction formed by an insulating layer (30) arranged between a metal electrode (20) and a superconducting layer (10) carrying an exchange field for providing a spin splitting effect of charge carriers (63, 64), an antenna comprising a wave collecting element (60) in contact with said superconducting layer to convey external electromagnetic waves (61) generated by an external source, and an electric measurement device (70) in contact with said metal electrode to measure an electric current or voltage caused by said spin split charge carrier flow, arranged to provide an output signal (71) responsive to the amplitude and frequency of said external electromagnetic waves, [FR] Capteur d'ondes électromagnétiques (1) de sensibilité extrêmement élevée, comprenant une jonction à filtration de spin formée par une couche isolante (30) intercalée entre une électrode métallique (20) et une couche supraconductrice (10) portant un champ d'échange permettant de fournir un effet de division de spin de porteurs de charge (63, 64), une antenne comportant un élément collecteur d'onde (60) disposé en contact avec ladite couche supraconductrice afin d'assurer le transport des ondes électromagnétiques externes (61) générées par une source externe, et un dispositif de mesure électrique (70) disposé en contact avec ladite électrode métallique afin d'assurer la mesure d'un courant ou d'une tension électrique dû-e au flux porteur de charge spin, afin de fournir un signal de sortie (71) en réaction à l'amplitude et la fréquence de ces ondes électromagnétiques externes
- Published
- 2019
5. Energy of dendritic avalanches in thin-film superconductors
- Author
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Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, Mikheenko, Pavlo, Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, and Mikheenko, Pavlo
- Abstract
A method for calculating stored magnetic energy in a thin superconducting film based on quantitative magneto-optical imaging is developed. Energy and magnetic moment are determined with these calculations for full hysteresis loops in a thin film of the superconductor NbN. Huge losses in energy are observed when dendritic avalanches occur. Magnetic energy, magnetic moment, sheet current and magnetic flux distributions, all extracted from the same calibrated magneto-optical images, are analyzed and discussed. Dissipated energy and the loss in moment when dendritic avalanches occur are related to each other. Calculating these losses for specific spatially-resolved flux avalanches is a great advantage, because of their unpredictable and non-reproducible nature. The relative losses in energy are much higher than the relative losses in moment.
- Published
- 2018
6. Energy of dendritic avalanches in thin-film superconductors
- Author
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Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, Mikheenko, Pavlo, Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, and Mikheenko, Pavlo
- Abstract
A method for calculating stored magnetic energy in a thin superconducting film based on quantitative magneto-optical imaging is developed. Energy and magnetic moment are determined with these calculations for full hysteresis loops in a thin film of the superconductor NbN. Huge losses in energy are observed when dendritic avalanches occur. Magnetic energy, magnetic moment, sheet current and magnetic flux distributions, all extracted from the same calibrated magneto-optical images, are analyzed and discussed. Dissipated energy and the loss in moment when dendritic avalanches occur are related to each other. Calculating these losses for specific spatially-resolved flux avalanches is a great advantage, because of their unpredictable and non-reproducible nature. The relative losses in energy are much higher than the relative losses in moment.
- Published
- 2018
7. Energy of dendritic avalanches in thin-film superconductors
- Author
-
Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, Mikheenko, Pavlo, Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, and Mikheenko, Pavlo
- Abstract
A method for calculating stored magnetic energy in a thin superconducting film based on quantitative magneto-optical imaging is developed. Energy and magnetic moment are determined with these calculations for full hysteresis loops in a thin film of the superconductor NbN. Huge losses in energy are observed when dendritic avalanches occur. Magnetic energy, magnetic moment, sheet current and magnetic flux distributions, all extracted from the same calibrated magneto-optical images, are analyzed and discussed. Dissipated energy and the loss in moment when dendritic avalanches occur are related to each other. Calculating these losses for specific spatially-resolved flux avalanches is a great advantage, because of their unpredictable and non-reproducible nature. The relative losses in energy are much higher than the relative losses in moment.
- Published
- 2018
8. Thermoelectric radiation detector based on superconductor-ferromagnet systems
- Author
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Academy of Finland, European Commission, Ministerio de Economía, Industria y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Heikkilä, T. T., Ojajärvi, Risto, Maasilta, I. J., Strambini, Elia, Giazotto, Francesco, Bergeret, F. S., Academy of Finland, European Commission, Ministerio de Economía, Industria y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Heikkilä, T. T., Ojajärvi, Risto, Maasilta, I. J., Strambini, Elia, Giazotto, Francesco, and Bergeret, F. S.
- Abstract
We suggest an ultrasensitive detector of electromagnetic fields exploiting the giant thermoelectric effect recently found in superconductor-ferromagnet hybrid structures. Compared with other types of superconducting detectors where the detected signal is based on variations of the detector impedance, the thermoelectric detector has the advantage of requiring no external driving fields. This is especially relevant in multipixel detectors, where the number of bias lines and the heating induced by them are an issue. We propose different material combinations to implement the detector and provide a detailed analysis of its sensitivity and speed. In particular, we perform a proper noise analysis that includes the cross correlation between heat and charge current noise and thereby describes also thermoelectric detectors with a large thermoelectric figure of merit.
- Published
- 2018
9. Energy of dendritic avalanches in thin-film superconductors
- Author
-
Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, Mikheenko, Pavlo, Qureishy, T, Vestgarden, J I, Qviller, A J, Fjellvag, A S, Meckbach, J M, Torgovkin, A, Johansen, Tom H, Ilin, K, Siegel, M, Maasilta, I J, and Mikheenko, Pavlo
- Abstract
A method for calculating stored magnetic energy in a thin superconducting film based on quantitative magneto-optical imaging is developed. Energy and magnetic moment are determined with these calculations for full hysteresis loops in a thin film of the superconductor NbN. Huge losses in energy are observed when dendritic avalanches occur. Magnetic energy, magnetic moment, sheet current and magnetic flux distributions, all extracted from the same calibrated magneto-optical images, are analyzed and discussed. Dissipated energy and the loss in moment when dendritic avalanches occur are related to each other. Calculating these losses for specific spatially-resolved flux avalanches is a great advantage, because of their unpredictable and non-reproducible nature. The relative losses in energy are much higher than the relative losses in moment.
- Published
- 2018
10. Metal frame as local protection of superconducting films from thermomagnetic avalanches
- Author
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Mikheenko, Pavlo, Vestgarden, J I, Chaudhuri, Supratim, Maasilta, I J, Galperin, Y, Johansen, Tom H, Mikheenko, Pavlo, Vestgarden, J I, Chaudhuri, Supratim, Maasilta, I J, Galperin, Y, and Johansen, Tom H
- Abstract
Thermomagnetic avalanches in superconducting films propagating extremely fast while forming unpredictable patterns, represent a serious threat for the performance of devices based on such materials. It is shown here that a normal-metal frame surrounding a selected region inside the film area can provide efficient protection from the avalanches during their propagation stage. Protective behavior is confirmed by magneto-optical imaging experiments on NbN films equipped with Cu and Al frames, and also by performing numerical simulations. Experimentally, it is found that while conventional flux creep is not affected by the frames, the dendritic avalanches are partially or fully screened by them. The level of screening depends on the ratio of the sheet conductance of the metal and the superconductor in the resistive state, and for ratios much larger than unity the screening is very efficient.
- Published
- 2016
11. Metal frame as local protection of superconducting films from thermomagnetic avalanches
- Author
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Mikheenko, Pavlo, Vestgarden, J I, Chaudhuri, Supratim, Maasilta, I J, Galperin, Y, Johansen, Tom H, Mikheenko, Pavlo, Vestgarden, J I, Chaudhuri, Supratim, Maasilta, I J, Galperin, Y, and Johansen, Tom H
- Abstract
Thermomagnetic avalanches in superconducting films propagating extremely fast while forming unpredictable patterns, represent a serious threat for the performance of devices based on such materials. It is shown here that a normal-metal frame surrounding a selected region inside the film area can provide efficient protection from the avalanches during their propagation stage. Protective behavior is confirmed by magneto-optical imaging experiments on NbN films equipped with Cu and Al frames, and also by performing numerical simulations. Experimentally, it is found that while conventional flux creep is not affected by the frames, the dendritic avalanches are partially or fully screened by them. The level of screening depends on the ratio of the sheet conductance of the metal and the superconductor in the resistive state, and for ratios much larger than unity the screening is very efficient.
- Published
- 2016
12. Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films
- Author
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Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, Johansen, Tom H, Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, and Johansen, Tom H
- Abstract
Combined voltage and magneto-optical study of magnetic flux flow in superconducting NbN films is reported. The nanosecond-scale voltage pulses appearing during thermomagnetic avalanches have been recorded in films partially coated by a metal layer. Simultaneous magneto-optical imaging and voltage measurements allowed the pulses to be associated with individual flux branches penetrating the superconductor below the metal coating. From detailed characteristics of pulse and flux branches, the electrical field in the superconductor is found to be in the range of 5-50 kV/m, while the propagation speed of the avalanche during its final stage is found to be close to 5 km/s.
- Published
- 2013
13. Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films
- Author
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Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, Johansen, Tom H, Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, and Johansen, Tom H
- Abstract
Combined voltage and magneto-optical study of magnetic flux flow in superconducting NbN films is reported. The nanosecond-scale voltage pulses appearing during thermomagnetic avalanches have been recorded in films partially coated by a metal layer. Simultaneous magneto-optical imaging and voltage measurements allowed the pulses to be associated with individual flux branches penetrating the superconductor below the metal coating. From detailed characteristics of pulse and flux branches, the electrical field in the superconductor is found to be in the range of 5-50 kV/m, while the propagation speed of the avalanche during its final stage is found to be close to 5 km/s.
- Published
- 2013
14. Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films
- Author
-
Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, Johansen, Tom H, Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, and Johansen, Tom H
- Abstract
Combined voltage and magneto-optical study of magnetic flux flow in superconducting NbN films is reported. The nanosecond-scale voltage pulses appearing during thermomagnetic avalanches have been recorded in films partially coated by a metal layer. Simultaneous magneto-optical imaging and voltage measurements allowed the pulses to be associated with individual flux branches penetrating the superconductor below the metal coating. From detailed characteristics of pulse and flux branches, the electrical field in the superconductor is found to be in the range of 5-50 kV/m, while the propagation speed of the avalanche during its final stage is found to be close to 5 km/s.
- Published
- 2013
15. Nanosecond voltage pulses from dendritic flux avalanches in superconducting NbN films
- Author
-
Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, Johansen, Tom H, Mikheenko, P, Qviller, A J, Vestgarden, J I, Chaudhuri, S, Maasilta, I J, Galperin, Y M, and Johansen, Tom H
- Abstract
Combined voltage and magneto-optical study of magnetic flux flow in superconducting NbN films is reported. The nanosecond-scale voltage pulses appearing during thermomagnetic avalanches have been recorded in films partially coated by a metal layer. Simultaneous magneto-optical imaging and voltage measurements allowed the pulses to be associated with individual flux branches penetrating the superconductor below the metal coating. From detailed characteristics of pulse and flux branches, the electrical field in the superconductor is found to be in the range of 5-50 kV/m, while the propagation speed of the avalanche during its final stage is found to be close to 5 km/s.
- Published
- 2013
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