P. W. Anderson and J. M. Rowell, Probable observation of the Josephson superconducting tunneling effect, Physical Review Letters, issue.6, p.10, 1963.

M. C. Andrade, . De, A. L. Escobar, . De, B. J. Taylor et al., Detection of Far-Field Radio-Frequency Signals by Niobium Superconducting Quantum Interference Device Arrays, vol.25, 2015.

L. G. Aslamazov, A. I. Larkin, and Y. N. Ovchinnikov, Josephson effect in superconductors separated by a normal metal, Soviet Physics JETP, issue.1, p.28, 1969.

K. Barthel, D. Koelle, B. Chesca, A. I. Braginski, A. Marx et al., Transfer function and thermal noise of YBACUO direct current superconducting quantum interference devices operated under large thermal fluctuations, Applied Physics Letters, issue.15, p.74, 1999.

X. Begaud, Technologies d ' antennes -De l ' antenne élémentaire aux grandes antennes. Techniques de l'Ingénieur, pp.3282-3284, 2018.

S. P. Benz and C. J. Burroughs, Two-dimensional arrays of Josephson junctions as voltage-tunable oscillators, Superconductor Science and Technology, vol.4, 1991.

N. Bergeal, X. Grison, J. Lesueur, G. Faini, M. Aprili et al., High-quality planar high-Tc Josephson junctions, Applied Physics Letters, vol.87, issue.10, 2005.

N. Bergeal, J. Lesueur, G. Faini, M. Aprili, and J. P. Contour, High Tc superconducting quantum interference devices made by ion irradiation, Applied Physics Letters, issue.11, p.89, 2006.

N. Bergeal, J. Lesueur, M. Sirena, G. Faini, M. Aprili et al., Using ion irradiation to make high-Tc Josephson junctions, Journal of Applied Physics, issue.8, p.102, 2007.

E. A. Berggren, Computational and mathematical modeling of coupled Superconducting Quantum Interference Devices, 2012.

E. A. Berggren, R. L. Fagaly, . Leese-de, and A. Escobar, Superconducting quantum interference devices arranged in pyramid shaped arrays, IEEE Transactions on Applied Superconductivity, issue.3, p.25, 2015.

S. Berggren, G. Prokopenko, P. Longhini, A. Palacios, O. A. Mukhanov et al., Development of 2-D Bi-SQUID arrays with high linearity, IEEE Transactions on Applied Superconductivity, issue.3, p.23, 2013.

H. Bernas, Materials Science with Ion Beams, vol.116, 2010.

M. G. Blamire, D. J. Kang, G. Burnell, N. H. Peng, R. Webb et al., Masked ion damage and implantation for device fabrication, User Modeling and User-Adapted Interaction, vol.69, pp.1-3, 2002.

W. Booij, A. Pauza, E. Tarte, D. Moore, and M. Blamire, Proximity coupling in high Josephson junctions produced by focused electron beam irradiation, Physical Review B -Condensed Matter and Materials Physics, issue.21, p.55, 1997.

K. Bouzehouane, Jonctions josephson a barriere artificielle a base d'YBACUO : technologie rampe et proprietes de transport, 1996.

A. I. Braginski, K. Barthel, B. Chesca, Y. Greenberg, R. Kleiner et al., Progress in understanding of high-transition-temperature SQUIDs. Physica C: Superconductivity and Its Applications, pp.341-348, 2000.

P. Caputo, J. Tomes, J. Oppenländer, C. Häussler, A. Friesch et al., Quadratic mixing of radio frequency signals using superconducting quantum interference filters, Applied Physics Letters, issue.6, p.89, 2006.

P. Caputo, J. Tomes, J. Oppenländer, C. Häussler, A. Friesch et al., Two-tone response in superconducting quantum interference filters, IEEE Transactions on Applied Superconductivity, issue.2, p.17, 2007.

P. Carelli, M. G. Castellano, K. Flacco, R. Leoni, and G. Torrioli, An absolute magnetometer based on dc Superconducting QUantum Interference Devices, Europhysics Letters, issue.5, p.39, 1997.

P. Carelli and V. Foglietti, Behavior of a multiloop dc superconducting quantum interference device, Journal of Applied Physics, issue.11, p.53, 1998.

K. Chen, S. A. Cybart, and R. C. Dynes, Planar thin film YBa 2Cu 3O 7-? Josephson junction pairs and arrays via nanolithography and ion damage, Applied Physics Letters, issue.14, p.85, 2004.

B. Chesca, Double rf-SQUIDs operating in a non-adiabatic regime: A dream comes true? Physics Procedia, Journal of Low Temperature Physics, vol.36, issue.1, 1998.

B. Chesca, Analytical Theory of RF SQUIDS Operating in the Presence of large Thermal Fluctuations, Journal of Low Temperature Physics, vol.110, issue.5, 1998.

B. Chesca, The effect of thermal noise on the I-V curves of high inductance DC squids in the presence of microwave radiation, Journal.of.Low.Temperature.Physics, vol.116, issue.3/4, 1999.

B. Chesca, The effect of thermal noise on the operation of dc squids at 77 k -a fundamental analytical approach, IEEE Transactions on Applied Superconductivity, vol.9, issue.2, 1999.

B. Chesca, J. , D. Mellor, and C. J. , Flux-coherent series SQUID array magnetometers operating above 77 K with superior white flux noise than single-SQUIDs at 4.2 K, Applied Physics Letters, issue.16, p.107, 2015.

E. Y. Cho, K. Kouperine, Y. Zhuo, R. C. Dynes, and S. A. Cybart, The effects of annealing a 2-dimensional array of ion-irradiated Josephson junctions, Superconductor Science and Technology, issue.9, p.29, 2016.

W. Chu, J. W. Mayer, and M. Nicolet, , 1978.

G. J. Clark, F. K. Legoues, A. D. Marwick, R. B. Laibowitz, and R. Koch, Ion beam amorphization of YBa2Cu3Ox, Applied Physics Letters, issue.18, p.51, 1987.

T. D. Clark, Experiments on coupled Josephson junctions, Physics Letters, issue.9, p.27, 1968.

J. Clarke and A. I. Braginski, The SQUID Handbook: Vol 1 Fundamentals and Technology of SQUIDs and SQUID Systems, The SQUID Handbook, vol.1, 2005.

J. Clarke and A. I. Braginski, The SQUID Handbook: Vol 1 Fundamentals and Technology of SQUIDs and SQUID Systems, The SQUID Handbook, vol.1, 2005.

J. Clarke, W. M. Goubau, and M. B. Ketchen, Tunnel junction dc SQUID: Fabrication, operation, and performance, Journal of Low Temperature Physics, pp.25-26, 1976.

J. Clarke, Y. Lee, and J. Schneiderman, Focus on SQUIDs in Biomagnetism. Superconductor Science and Technology, issue.8, p.31, 2018.

J. R. Clem, Flux-flow noise in superconductors, Physics Reports, issue.1, p.75, 1981.

F. Couëdo, E. Recoba-pawlowski, J. Kermorvant, J. Trastoy, D. Crété et al., High-Tc superconducting antenna for highly-sensitive microwave magnetometry, ArXiv, 2019.

D. Crete, A. Sene, A. Labbe, E. R. Pawlowski, J. Kermorvant et al., Evaluation of Josephson Junction Parameter Dispersion Effects in Arrays of HTS SQUIDs, IEEE Transactions on Applied Superconductivity, issue.7, p.28, 2018.

S. A. Cybart, E. Y. Cho, T. J. Wong, B. H. Wehlin, M. K. Ma et al., Nano Josephson superconducting tunnel junctions in YBa2Cu3O7-? directly patterned with a focused helium ion beam, Nature Nanotechnology, issue.7, p.10, 2015.

S. A. Cybart, T. N. Dalichaouch, S. M. Wu, S. M. Anton, J. A. Drisko et al., Comparison of measurements and simulations of series-parallel incommensurate area superconducting quantum interference device arrays fabricated from YBACUO ion damage Josephson junctions, Journal of Applied Physics, issue.6, p.112, 2012.

S. A. Cybart, P. Roediger, K. Chen, J. M. Parker, E. Y. Cho et al., Temporal stability of Y-Ba-Cu-O Nano Josephson junctions from ion irradiation, IEEE Transactions on Applied Superconductivity, issue.3, p.23, 2013.

T. N. Dalichaouch, S. A. Cybart, and R. C. Dynes, The effects of mutual inductances in two-dimensional arrays of Josephson junctions, Superconductor Science and Technology, issue.6, p.27, 2014.

E. Dantsker, S. Tanaka, P. Å. Nilsson, R. Kleiner, and J. Clarke, Reduction of 1 / f noise in high-Tc dc superconducting quantum interference devices cooled in an ambient magnetic field, Appl. Phys. Lett, issue.26, p.69, 1996.

J. Darricau, Radars -Paramètres de détection Paramètres de détection, vol.6655, 1996.

J. Darricau, Radars : principes de base -Éléments constitutifs Radars : principes de base Éléments constitutifs, 2012.

M. Darula, T. Doderer, and S. Beuven, Millimetre and sub-mm wavelength radiation sources based on discrete Josephson junction arrays, Superconductor Science and Technology, vol.12, issue.1, 1999.

A. M. De-waele, W. H. Kraan, . De-bruyn, and R. Ouboter, Experimental evidence for quantized flux in superconducting cyclinders, Physical Review Letters, vol.7, issue.2, 1961.

Y. Y. Divin, U. Poppe, C. L. Jia, P. M. Shadrin, and K. Urban, Structural and electrical properties of YBa2Cu3O7, IcRn-products on SrTiO3 bicrystals. Physica C: Superconductivity and Its Applications, pp.372-376, 2002.

R. Doll and M. Näbauer, Experimental proof of magnetic flux quantization in a superconducting ring, Physical Review Letters, vol.7, issue.2, 1961.

A. P. Drozdov, M. I. Eremets, I. A. Troyan, V. Ksenofontov, and S. I. Shylin, Conventional superconductivity at 203 kelvin at high pressures in the sulfur hydride system, Nature, issue.73, p.3, 2015.

D. Drung, C. Aßmann, J. Beyer, M. Peters, F. Ruede et al., Dc SQUID readout electronics with up to 100 MHz closed-loop bandwidth, IEEE Transactions on Applied Superconductivity, p.15, 2005.

J. Du, J. Y. Lazar, S. K. Lam, E. E. Mitchell, and C. P. Foley, Fabrication and characterisation of series YBCO step-edge Josephson junction arrays, Superconductor Science and Technology, issue.9, p.27, 2014.

G. J. Ehnholm, Theory of the Signal Transfer and Noise Properties of the rf SQUID, Journal of Low Temperature Physics, vol.29, issue.1, 1977.

K. Enpuku, H. Doi, G. Tokita, and T. Maruo, Modulation voltage of high tc DC superconducting quantum interference device with damping resistance, Japanese Journal of Applied Physics, issue.5B, p.33, 1994.

K. Enpuku, H. Doi, G. Tokita, and T. Mauro, Method for improving voltage modulation depth of hight Tc DC SQUID with large inductance, IEEE Transactions on Appiled Superconductivity, vol.5, issue.2, 1995.

K. Enpuku, K. Sueoka, K. Yoshida, and F. Irie, Effect of damping resistance on voltage versus flux relation of a dc SQUID with large inductance and critical current, Journal of Applied Physics, issue.5, p.57, 1985.

K. Enpuku, K. Yoshida, and S. Kohjiro, Noise characteristics of a dc SQUID with a resistively shunted inductance. II. Optimum damping, Journal of Applied Physics, issue.12, p.57, 1986.

K. Enpuku and H. Doi, Voltage versus flux relation of dc superconducting quantum interference device using three josephson junctions, Japanese Journal of Applied Physics, issue.4A, p.33, 1994.

K. Enpuku, S. Ohta, A. Nakahodo, and T. Minotani, Josephson junction array for the measurement of highfrequency magnetic fields, Japanese Journal of Applied Physics, 2000.

R. Feynman, Ch 21 -Schrodinger Equation In Classical Context.pdf. The Feynman Lectures on Physics, vol.3, 1963.

V. Foglietti, W. J. Gallagher, M. B. Ketchen, A. W. Kleinsasser, R. H. Koch et al., Low-frequency noise in low 1 / f noise dc SQUID ' s, Applied Physics Letters, issue.27, p.49, 1986.

V. Foglietti, K. G. Stawiasz, M. B. Ketchen, and R. H. Koch, Performance of a Flux Locked Series SQUID Array, IEEE Transactions on Applied Superconductivity, vol.3, issue.4, 1993.

J. F. Ge, Z. L. Liu, C. Liu, C. L. Gao, D. Qian et al., Superconductivity above 100 K in single-layer FeSe films on doped SrTiO3, Nature Materials, issue.3, p.14, 2015.

R. P. Giffard, R. A. Webb, and J. C. Wheatley, Principles and Methods of Low-Frequency Electric and Magnetic Measurements Using an rf-Biased Point-Contact Superconducting Device, Journal of Low Temperature Physics, vol.6, issue.5, 1972.

A. M. Goldman and P. J. Kreisman, Meissner effect and vortex penetration in Josephson junctions, Physical Review, issue.2, p.164, 1967.

Y. S. Greenberg, Theory of the voltage -current characteristic of high T c DC SQUIDs, Physica C: Superconductivity and Its Applications, p.371, 2002.

Y. S. Greenberg, Theory of the voltage-current characteristics of high TCasymmetric DC SQUIDs, Physica C: Superconductivity and Its Applications, vol.383, issue.4, 2003.

Y. S. Greenberg and I. L. Novikov, The voltage-current characteristic of high-TCDC SQUID: Theory, simulation, experiment, Physica C: Superconductivity and Its Applications, p.433, 2006.

Y. S. Greenberg, I. L. Novikov, V. Schultze, and H. G. Meyer, The influence of the second harmonic in the current-phase relation on the voltage-current characteristic of high TCDC SQUID, European Physical Journal B, vol.44, issue.1, 2005.

Y. S. Greenberg, V. Schultze, and H. Meyer, Theory of the voltage -current characteristic of high T c DC SQUIDs and its experimental verification, Physica C: Superconductivity and Its Applications, p.368, 2002.

J. Guiguet, Fréquences radioélectriques -Gestion du spectre, pp.7040-7041, 2003.

C. A. Hamilton, C. J. Burroughs, and S. P. Benz, Josephson Voltage Standard -A review, IEEE Transactions on Appiled Superconductivity, vol.7, issue.2, 1997.

C. Häussler, J. Oppenländer, and N. Schopohl, Nonperiodic flux to voltage conversion of series arrays of dc superconducting quantum interference devices, Journal of Applied Physics, issue.3, p.89, 2001.

J. Hollkott, S. Hu, C. Becker, J. Auge, B. Spangenberg et al., Josephson junctions fabricated by oxygen ion irradiation of YBCO thin films, IEEE Transac. Appl. Supercond, vol.7, issue.2, 1997.

A. Horsley and P. Treutlein, Frequency-tunable microwave field detection in an atomic vapor cell, Applied Physics Letters, issue.21, p.108, 2016.

A. K. Jain, K. K. Likharev, J. E. Lukens, and J. E. Sauvageau, Mutual phase-locking in Josephson junction arrays, Physics Reports, issue.6, p.109, 1984.

R. C. Jaklevic, J. Lambe, A. H. Silver, and J. E. Mercereau, Quantum interference effects in Josephson tunneling, Physical Review Letters, issue.7, p.12, 1964.

J. M. Jaycox and M. B. Ketchen, Planar coupling scheme for ultra low noise Dc squids, IEEE Transactions on Magnetics, vol.17, issue.1, 1981.

J. T. Jeng, K. H. Huang, C. H. Wu, K. L. Chen, J. C. Chen et al., Characteristics of the superconducting-quantum-interference-grating magnetometer consisting of grain-boundary Josephson junctions, IEEE Transactions on Applied Superconductivity, issue.2, p.17, 2007.

D. W. Jillie, J. E. Lukens, Y. H. Kao, and G. J. Dolan, Observation of voltage locking and other interactions in coupled microbridge Josephson junctions, Physics Letters, issue.6, p.55, 1976.

B. D. Josephson, Possible new effects in superconductive tunnelling, Physics Letters, issue.7, p.1, 1962.

B. D. Josephson, Supercurrents through barriers, Advances in Physics, issue.56, p.14, 1965.

F. Kahlmann, A. Engelhardt, J. Schubert, W. Zander, C. Buchal et al., Superconductor-normalsuperconductor Josephson junctions fabricated by oxygen implantation into YBa2Cu3O7-delta, Appl. Phys. Lett, issue.16, p.73, 1998.

D. J. Kang, N. H. Peng, R. Webb, C. Jeynes, G. Burnell et al., Irradiation damage technology for manufacturable Josephson junctions. Nuclear Instruments and Methods in Physics Research, Section B: Beam Interactions with Materials and Atoms, vol.188, pp.1-4, 2002.

A. S. Katz, A. G. Sun, S. I. Woods, and R. C. Dynes, Planar thin film YBa2Cu3O7-?Josephson junctions via nanolithography and ion damage, Applied Physics Letters, issue.16, p.72, 1998.

A. S. Katz, S. I. Woods, and R. C. Dynes, Transport properties of high-Tcplanar Josephson junctions fabricated by nanolithography and ion implantation, Journal of Applied Physics, issue.6, p.87, 2000.

A. S. Katz, S. I. Woods, R. C. Dynes, and A. G. Sun, Stability and uniformity of planar hight temperature Josephson junctions fabricated using nanolithography and ion damage, vol.9, 1999.

M. B. Ketchen and J. M. Jaycox, Ultra-low-noise tunnel junction dc SQUID with a tightly coupled planar input coil, Appl. Phys. Lett, issue.8, p.40, 1982.

R. Kleiner, D. Koelle, F. Ludwig, and J. Clarke, Superconducting quantum interference devices: State of the art and applications, Proceedings of the IEEE, vol.92, 2004.

R. H. Koch, C. P. Umbach, G. J. Clark, P. Chaudhari, and R. B. Laibowitz, Quantum interference devices made from superconducting oxide thin films, Applied Physics Letters, issue.3, p.51, 1987.

D. Koelle, R. Kleiner, F. Ludwig, E. Dantsker, and J. Clarke, High-transition-temperature superconducting quantum interference devices, Reviews of Modern Physics, issue.3, p.71, 1999.

V. G. Kogan and R. G. Mints, Manipulating Josephson junctions in thin-films by nearby vortices. Physica C: Superconductivity and Its Applications, p.502, 2014.

V. K. Kornev, N. V. Kolotinskiy, A. V. Sharafiev, I. I. Soloviev, and O. A. Mukhanov, Broadband active electrically small superconductor antennas, Superconductor Science and Technology, issue.10, p.30, 2017.

V. K. Kornev, A. V. Sharafiev, I. I. Soloviev, and O. A. Mukhanov, Signal and noise characteristics of bi-SQUID, Superconductor Science and Technology, issue.11, p.27, 2014.

V. K. Kornev, I. I. Soloviev, N. V. Klenov, and O. A. Mukhanov, Bi-SQUID: A novel linearization method for dc SQUID voltage response, Superconductor Science and Technology, issue.11, p.22, 2009.

V. K. Kornev, I. I. Soloviev, N. V. Klenov, and O. A. Mukhanov, Design and experimental evaluation of SQIF arrays with linear voltage response, IEEE Transactions on Applied Superconductivity, vol.21, issue.3, 2011.

V. Kornev, N. Kolotinskiy, V. Skripka, A. Sharafiev, I. Soloviev et al., High linearity voltage response parallel-array cell, Journal of Physics: Conference Series, p.507, 2014.

V. Kornev, I. Soloviev, N. Klenov, and O. Mukhanov, Differential parallel-serial SQIF structures providing high linearity response, Journal of Physics: Conference Series, issue.1, p.97, 2008.

V. K. Kornev, I. I. Soloviev, N. V. Klenov, and O. A. Mukhanov, High linearity sqif-like josephson-junction structures, IEEE Transactions on Applied Superconductivity, vol.19, issue.3, 2009.

V. K. Kornev, I. I. Soloviev, N. V. Klenov, and O. A. Mukhanov, High Linearity SQIF-Like Josephson-Junction Structures, vol.19, 2009.

M. Lalande and J. Andrieu, Radars ultra large bande -Détection électromagnétique courte portée Radars ultra large bande Détection électromagnétique courte portée, pp.6706-6707, 2013.

J. Lesueur, N. Bergeal, M. Sirena, X. Grison, G. Faini et al., High Tc Josephson nanojunctions made by ion irradiation: Characteristics and reproducibility, IEEE Transactions on Applied Superconductivity, issue.2, p.17, 2007.

K. K. Likharev and V. K. Semenov, RSFQ Logic / Memory Family : A New Josephson-Junction Technology for Digital Systems, IEEE Transactions on Applied Superconductivity, p.1, 1991.

T. Lindström, S. A. Charlebois, A. Y. Tzalenchuk, Z. Ivanov, M. H. Amin et al., Dynamical Effects of an Unconventional Current-Phase Relation in YBCO dc SQUIDs, Physical Review Letters, issue.11, p.90, 2003.

P. Longhini, S. Berggren, A. Leese-de-escobar, A. Palacios, S. Rice et al., Voltage response of non-uniform arrays of bi-superconductive quantum interference devices, Journal of Applied Physics, issue.9, p.111, 2012.

P. Longhini, S. Berggren, A. Palacios, V. In, and A. L. De-escobar, Modeling non-locally coupled DC SQUID arrays, IEEE Transactions on Applied Superconductivity, vol.21, issue.3, 2011.

P. Longhini, A. L. De-escobar, F. Escobar, V. In, and A. Bulsara, Novel coupling scheme for the dynamics of non-uniform coupled SQUID, IEEE Transactions on Applied Superconductivity, vol.19, issue.3, 2009.

F. Ludwig, E. Dantsker, D. Koelles, R. Kleiner, A. H. Miklich et al., Multilayer magnetometers based on High-Tc SQUIDs, Applied Superconductivity, issue.7, p.3, 1995.

M. Tinkham, Introduction to Superconductivity, 1996.

M. Malnou, C. Feuillet-palma, C. Ulysse, G. Faini, P. Febvre et al., High-Tc superconducting Josephson mixers for terahertz heterodyne detection, Journal of Applied Physics, issue.7, p.116, 2014.

M. Malnou, High-Tc Josephson mixers for terahertz detection, 2015.
URL : https://hal.archives-ouvertes.fr/tel-01213100

P. Mangin and R. Kahn, Supraconductivité introduction (Collection; EDP scinces, 2013.

E. Maruyama, S. Kuriki, K. Yokosawa, R. Sha-ahmad, D. Suzuki et al., Flux Coupling in the DirectCoupled High-Tc Superconducting Quantum Interference Devices, Japanese Journal of Applied Physics, issue.6B, p.37, 1998.

J. Matisoo, Critical currents and current distributions in Josephson junctions, Journal of Applied Physics, issue.4, p.40, 1968.

D. E. Mccumber, Effect of ac impedance on dc voltage-current characteristics of superconductor weak-link junctions, Journal of Applied Physics, issue.7, p.39, 1968.

M. Mihet, Jonctions josephson sur rampe a base des cuprates supraconducteurs et d'oxyde mixte de cerium et lanthane, 2000.

J. H. Miller, G. H. Gunaratne, J. Huang, and T. D. Golding, Enhanced quantum interference effects in parallel Josephson junction arrays, Applied Physics Letters, issue.25, p.59, 1991.

E. E. Mitchell, K. E. Hannam, J. Lazar, K. E. Leslie, C. J. Lewis et al., 2D SQIF arrays using 20 000 YBCO high RnJosephson junctions, Superconductor Science and Technology, issue.6, p.29, 2016.

M. Mück, C. Welzel, and J. Clarke, Superconducting quantum interference device amplifiers at gigahertz frequencies, Applied Physics Letters, p.82, 2003.

I. L. Novikov, Y. S. Greenberg, V. Schultze, R. Ijsselsteijn, and H. Meyer, Voltage -current and voltage -flux characteristics of asymmetric high Tc DC SQUIDs, Physica C: Superconductivity and Its Applications, issue.1, p.469, 2009.

J. Oppenländer, P. Caputo, C. Häussier, T. Träubie, J. Tomes et al., Effects of magnetic field on two-dimensional superconducting quantum interference filters, Applied Physics Letters, issue.5, p.83, 2003.

J. Oppenländer, C. Häussler, and N. Schopohl, Non-?0-periodic macroscopic quantum interference in onedimensional parallel Josephson junction arrays with unconventional grating structure, Physical Review BCondensed Matter and Materials Physics, issue.2, p.63, 2001.

J. Oppenländer, C. Häussler, A. Friesch, J. Tomes, P. Caputo et al., , 2005.

, Superconducting Quantum Interference Filters operated in commercial miniature cryocoolers, IEEE Transactions on Applied Superconductivity, issue.2, p.15

S. Ouanani, J. Kermorvant, D. G. Crété, Y. Lemaître, J. C. Mage et al., HTS ion damage Josephson junction technology for SQUID arrays, Journal of Physics: Conference Series, vol.507, 2014.

S. Ouanani, J. Kermorvant, C. Ulysse, M. Malnou, Y. Lemaître et al., High-Tc Superconducting Quantum Interference Filters (SQIFs) made by ion irradiation. Superconductor Science and Technology, p.29, 2016.

S. Ouanani, Etude de réseaux de jonctions Josephson a haute température critique, 2015.

C. S. Owen and D. J. Scalapino, Vortex structure and critical currents in Josephson junctions, Physical Review, issue.2, p.164, 1967.

D. W. Palmer and J. E. Mercerau, Coherent effects in series arrays of proxinity effect superconducting bridges, IEEE Transactions on Magnetics, vol.11, issue.2, 1975.

C. L. Platt, A. S. Katz, R. C. Dynes, and A. E. Berkowitz, Superconducting tunneling as a probe of sputtered oxide barriers, Applied Physics Letters, vol.75, issue.1, pp.127-129, 1999.

G. V. Prokopenko and O. A. Mukhanov, Wideband microwave low noise amplifiers based on biSQUID SQIFs, IEEE 14th InternationalSuperconductive Electronics Conference, 2013.

G. V. Prokopenko, O. A. Mukhanov, A. Leese-de-escobar, B. Taylor, M. C. De-andrade et al., DC and RF measurements of serial Bi-SQUID arrays, IEEE Transactions on Applied Superconductivity, issue.3, p.23, 2013.

G. V. Prokopenko, S. V. Shitov, I. L. Lapitskaya, V. P. Koshelets, and J. Mygind, Dynamic characteristics of S-band dc SQUID amplifier, IEEE Transactions on Applied Superconductivity, vol.13, issue.2 I, 2003.

E. Recoba-pawlowski, J. Kermorvant, D. Crété, Y. Lemaître, B. Marcilhac et al., Static and radio frequency magnetic response of high T c superconducting quantum interference filters made by ion irradiation, Superconductor Science and Technology, issue.9, p.31, 2018.

J. M. Rowell, Magnetic fiel dependence of the Josephson tunnel current, vol.11, 1963.

T. Ryhänen, H. Seppä, R. Ilmoniemi, and J. Knuutila, SQUID magnetometers for low-frequency applications, Journal of Low Temperature Physics, issue.5, p.76, 1989.

M. L. Schneider, C. A. Donnelly, and S. E. Russek, Tutorial: High-speed low-power neuromorphic systems based on magnetic Josephson junctions, Journal of Applied Physics, issue.16, p.124, 2018.

V. Schultze, R. Ijsselsteijn, R. Boucher, H. G. Meyer, J. Oppenländer et al., Improved high-Tc superconducting quantum interference filters for sensitive magnetometry, Superconductor Science and Technology, issue.12, p.16, 2003.

V. Schultze, R. Ijsselsteijn, V. Zakosarenko, F. Thrum, E. Il'ichev et al., High Tc SQUIDs with two or three junctions for application in disturbed environment, Applied Superconductivity, vol.5, pp.7-12, 1997.

. Schultze, . Volkmar, R. Ijsselsteijn, and H. G. Meyer, How to puzzle out a good high-Tc superconducting quantum interference filter, Superconductor Science and Technology, vol.19, issue.5, 2006.

A. V. Shadrin, K. Y. Constantinian, and G. A. Ovsyannikov, Quantum interference filters based on oxide superconductor junctions for microwave applications, Technical Physics Letters, issue.3, p.33, 2007.

A. V. Shadrin, K. Y. Constantinian, G. A. Ovsyannikov, S. V. Shitov, I. I. Soloviev et al., Fraunhofer regime of operation for superconducting quantum interference filters, Applied Physics Letters, issue.26, p.93, 2008.

S. Shapiro, Josephson Currents in Superconducting Tunneling: The Effect of Microwaves and Other Observations, Physical Review Letters, issue.2, p.11, 1963.

M. Sirena, N. Bergeal, J. Lesueur, G. Faini, R. Bernard et al., Study and optimization of ion-irradiated high Tc Josephson junctions by Monte Carlo simulations, Journal of Applied Physics, issue.12, p.101, 2007.

M. Sirena, X. Fabrges, N. Bergeal, J. Lesueur, G. Faini et al., Improving the Ic Rn product and the reproducibility of high Tc Josephson junctions made by ion irradiation, Applied Physics Letters, issue.26, p.91, 2007.

M. Sirena, S. Matzen, N. Bergeal, J. Lesueur, G. Faini et al., Improving ion irradiated high Tc Josephson junctions by annealing: The role of vacancy-interstitial annihilation, Applied Physics Letters, issue.14, p.91, 2007.

M. Sirena, S. Matzen, N. Bergeal, J. Lesueur, G. Faini et al., Annealing of ion irradiated high TC Josephson junctions studied by numerical simulations, Journal of Applied Physics, issue.2, p.105, 2009.

O. V. Snigirev, M. L. Chukharkin, A. S. Kalabukhov, M. A. Tarasov, A. A. Deleniv et al., Superconducting quantum interference filters as RF amplifiers, IEEE Transactions on Applied Superconductivity, issue.2, p.17, 2007.

A. Stark, N. Aharon, T. Unden, D. Louzon, A. Huck et al., Narrow-bandwidth sensing of high-frequency fields with continuous dynamical decoupling, Nature Communications, vol.8, issue.1, 2017.

W. C. Stewart, Current-voltage characteristics of Josephson junctions, Applied Physics Letters, issue.8, p.12, 1968.

B. J. Taylor, S. A. Berggren, M. C. O'brien, M. C. Deandrade, B. A. Higa et al., Characterization of large two-dimensional YBa2Cu3O7-?SQUID arrays, Superconductor Science and Technology, issue.8, p.29, 2016.

C. D. Tesche and J. Clarke, DC SQUID: Noise and optimization, Journal of Low Temperature Physics, vol.29, issue.3/4, 1977.

G. Testa, C. Granata, C. Calidonna, C. Russo, . Di et al., Performance of asymmetric superconducting quantum interference devices, vol.368, pp.232-235, 2002.

G. Testa, S. Pagano, E. Sarnelli, C. R. Calidonna, and M. M. Furnari, Improved superconducting quantum interference devices by resistance asymmetry, Applied Physics Letters, issue.18, p.79, 2001.

G. Testa, S. Pagano, E. Sarnelli, C. R. Calidonna, M. M. Furnari et al., Properties of asymmetric high critical temperature dc SQUIDs, IEEE Transactions on Applied Superconductivity, issue.1, p.11, 2001.

G. Testa, E. Sarnelli, S. Pagano, C. Calidonna, and M. Furnari, Characteristics of asymetric superconducting quantum interference devices, Journal of Applied Physics, issue.9, p.89, 2001.

S. S. Tinchev, High-T SQUIDS with Local Oxygen-Ion Irradiated Weak Links, IEEE Transac. Appl. Supercond, vol.3, issue.1, 1993.

K. Wan, B. Bi, A. K. Jain, L. A. Fetter, S. Han et al., Refractory Submillimeter Josephson Effect Sources, IEEE Transactions on Magnetics, issue.2, p.27, 1991.

Q. Y. Wang, Z. Li, W. H. Zhang, Z. C. Zhang, J. S. Zhang et al., Interface-induced hightemperature superconductivity in single unit-cell FeSe films on SrTiO3, Chinese Physics Letters, issue.3, p.29, 2012.

R. Welty and J. M. Martinis, A Series Array of Dc Squid, IEEE Transactions on Magnetics, issue.2, p.27, 1991.

A. E. White, K. T. Short, R. C. Dynes, A. F. Levi, M. Anzlowar et al., Controllable reduction of critical currents in YBa2Cu 3O7-? films, Applied Physics Letters, issue.11, p.53, 1988.

T. Wolf, , p.235, 2010.

T. Wolf, N. Bergeal, J. Lesueur, C. J. Fourie, G. Faini et al., YBCO josephson junctions and striplines for RSFQ circuits made by ion irradiation, IEEE Transactions on Applied Superconductivity, issue.2, p.23, 2013.

C. H. Wu, F. J. Jhan, J. H. Chen, and J. T. Jeng, High-TcJosephson junctions fabricated by focused ion beam direct milling, Superconductor Science and Technology, vol.26, issue.2, 2013.

S. M. Wu, S. A. Cybart, S. M. Anton, and R. C. Dynes, Simulation of series arrays of superconducting quantum interference devices, IEEE Transactions on Applied Superconductivity, vol.23, issue.3, 2013.

M. J. Zani, J. A. Luine, R. W. Simon, and R. A. Davidheiser, Focused ion beam high Tc superconductor dc SQUIDs, Applied Physics Letters, issue.2, p.59, 1991.

J. F. Ziegler and J. P. Biersack, Stopping and range of ions in matter: SRIM. Web Science Conference, 2009.

J. E. Zimmerman and A. H. Silver, Macroscopic quantum interference effects through superconducting point contacts, Physical Review, issue.1, p.141, 1966.