Dr. Audrey Cottet : publications in physics                          back to menu

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2023

 

      [62]   Chiral antiferromagnetic Josephson junctions as spin-triplet supercurrent spin valves and d.c. SQUIDs

                Kun-Rok Jeon, Binoy Krishna Hazra, Jae-Keun Kim, Jae-Chun Jeon, Hyeon Han,

                Holger L. Meyerheim, Takis Kontos, Audrey Cottet & Stuart S. P. Parkin

                Nature Nanotechnology (2023)

                https://doi.org/10.1038/s41565-023-01336-z

 

      [61]   Inhomogeneous magnetic fields interacting with spinful states in a double quantum dot:

                Evidence for a staggered spin-orbit interaction

                L. C. Contamin, T. Cubaynes, W. Legrand, M. Marganska, M. Villiers, M. M. Desjardins

                M. C. Dartiailh,, V. Vinel, Z. Leghtas, A. Thiaville, S. Rohart, A. Cottet, M. R. Delbecq, and T. Kontos

                Phys. Rev. B 107, 085152 (2023)

                https://link.aps.org/doi/10.1103/PhysRevB.107.085152

2022

 

      [60]   Zero energy states clustering in an elemental nanowire coupled to a superconductor

               Lauriane C. Contamin, Lucas Jarjat, William Legrand, Audrey Cottet, Takis Kontos & Matthieu R. Delbecq

               Nature Communications volume 13, Article number: 6188 (2022)

 

      [59]    Zero-field polarity-reversible Josephson supercurrent diodes enabled by a proximity-magnetized Pt barrier

                Kun-Rok Jeon, Jae-Keun Kim, Jiho Yoon, Jae-Chun Jeon, Hyeon Han,

                Audrey Cottet, Takis Kontos & Stuart S. P. Parkin               

                Nature Materials (2022).

2021

 

      [57]   Hybrid light-matter networks of Majorana zero modes

               Lauriane Contamin, Matthieu Delbecq, Benoit Douçot, Audrey Cottet and Takis Kontos

               to appear in npj Quantum Information

               npj Quantum Information volume 7, Article number: 171 (2021)

 

      [56] Vacuum- field-induced THz transport gap in a carbon nanotube quantum dot

               F. Valmorra, K. Yoshida, L. C. Contamin, S. Messelot, S. Massabeau, M. R. Delbecq,

               M. C. Dartiailh, M. M. Desjardins, T. Cubaynes, Z. Leghtas, K. Hirakawa, J. Tignon,

               S. Dhillon, S. Balibar, J. Mangeney, A. Cottet and T. Kontos

               Nature Communications volume 12, Article number: 5490 (2021)

2020

 

      [55] Nanoassembly technique of carbon nanotubes for hybrid circuit-QED

             T. Cubaynes, L.C. Contamin, M.C. Dartiailh, M.M. Desjardins, A. Cottet, M.R. Delbecq, and T. Kontos

             Appl. Phys. Lett. 117, 114001 (2020)

 

      [54] Theory of interactions between cavity photons induced by a mesoscopic circuit

             A. Cottet, Z. Leghtas and T. Kontos

             Phys. Rev. B 102, 155105 (2020)

2019

 

      [53] Highly coherent spin states in carbon nanotubes coupled to cavity photons

             T. Cubaynes, M. R. Delbecq, M. C. Dartiailh, R. Assouly, M. M. Desjardins, L. C. Contamin, L. E. Bruhat,

             Z. Leghtas, F. Mallet, A. Cottet, T. Kontos

             npj Quantum Information 5, Article number: 47 (2019)

 

      [52] Synthetic spin orbit interaction for Majorana devices

             M. M. Desjardins, L. C. Contamin, M. R. Delbecq, M. C Dartiailh, L. E. Bruhat, T. Cubaynes, J. J. Viennot,

             F. Mallet, S. Rohart, A. Thiaville, A. Cottet, T. Kontos

             Nature Materials volume 18, 1060 (2019)

             see also:  Supplemental Material

                             News ans views “Conjuring Majorana with synthetic magnetism” by Ali Yazdani

 

      [51] Superconducting quantum bits with artificial damping tackle the many body problem

             A. Cottet

             npj Quantum Information 5, Article number: 21 (2019), Editorial

 

2018

      [50] Circuit QED with a quantum-dot charge qubit dressed by Cooper pairs

             L. E Bruhat, T. Cubaynes, J. J. Viennot, M. C. Dartiailh, M. M. Desjardins, A. Cottet, and T. Kontos,

             Phys. Rev. B 98, 155313 (2018)

 

      [49] Scaling laws of the Kondo problem at finite frequency

             L. E. Bruhat, J. J. Viennot, M. C. Dartiailh, M. M. Desjardins, A. Cottet, and T. Kontos

             Phys. Rev. B 98, 075121 (2018), Editor’s choice

2017

      [48] Cavity QED with hybrid nanocircuits: from atomic-like physics to condensed matter phenomena

            A. Cottet, M. C. Dartiailh, M. M. Desjardins, T. Cubaynes, L. C. Contamin, M. Delbecq,

            J. J. Viennot, L. E. Bruhat, B. Douçot, T. Kontos            

            J. Phys.: Condens. Matter 29 433002 (2017)

 

      [47] Observation of the frozen charge of a Kondo resonance

             M. M. Desjardins, J. J. Viennot, M. C. Dartiailh, L. E. Bruhat, M. R. Delbecq, M. Lee, M.-S. Choi, A. Cottet and T. Kontos

             Nature 545, 71 (2017)

 

      [46] Direct cavity detection of Majorana pairs

            M. Dartiailh, T. Kontos, B. Douçot, and A. Cottet

            Phys. Rev. Lett. 118, 126803 (2017).

            see also:  Supplemental Material

2016

      [45] Towards hybrid circuit quantum electrodynamics with quantum dots

            J. J. Viennot, M. R. Delbecq, L. E. Bruhat, M. C. Dartiailh, M.M. Desjardins,

            M. Baillergeau, A. Cottet, and T. Kontos

            Comptes Rendus Physique (2016).

 

       [44] Cavity photons as a probe for charge relaxation resistance and photon emission

            in a quantum dot coupled to normal and superconducting continua

            L.E. Bruhat, J.J. Viennot, M.C. Dartiailh, M.M. Desjardins, T. Kontos and A. Cottet

            Phys. Rev. X, 6, 021014 (2016).

 

      [43]  Harnessing spin precession with dissipation,

            A.D. Crisan, S. Datta, J.J. Viennot, M.R. Delbecq,  A.Cottet & T.Kontos,

            Nature Communications 7, Article number: 10451 (2016).

 

      [42]  Sensitive radio-frequency measurements of a quantum dot by tuning to perfect impedance matching,

            N. Ares, F.J. Schupp, A. Mavalankar, G. Rogers, J. Griffiths, G.A.C. Jones,

            I. Farrer, D.A. Ritchie, C.G. Smith, A. Cottet, G.A.D. Briggs, and E.A. Laird

            Phys. Rev. Applied 5, 034011 (2016).

            see also:  Supplemental Material

2015

     [41]  General Boundary Conditions for Quasiclassical Theory of Superconductivity in the Diffusive Limit:

            Application to Strongly Spin-polarized Systems

            M. Eschrig, A. Cottet, W. Belzig, J. Linder, New J. Phys. 17 083037 (2015).

 

     [40]  Coherent coupling of a single spin to microwave cavity photons

            J. J. Viennot, M. C. Dartiailh, A. Cottet, and T. Kontos

            Science 349, 6246 (2015).

            see also:  Supplemental Material

 

     [39]  Electron-photon coupling in Mesoscopic Quantum Electrodynamics

            A. Cottet, T. Kontos and B. Douçot, Phys. Rev. B 91, 205417 (2015), Editor’s suggestion

2014

     [38]  Probing coherent Cooper pair splitting with cavity photons

            A. Cottet, Phys. Rev. B 90, 125139 (2014).

 

     [37]  Out of equilibrium charge dynamics in a hybrid cQED architecture

            J.J. Viennot, M.R. Delbecq, M.C. Dartiailh, A. Cottet, T. Kontos, Phys. Rev. B 89, 165404 (2014).

 

2013

     [36]  Squeezing light with Majorana fermions

            A. Cottet, T. Kontos and B. Douçot, Phys. Rev. B 88, 195415 (2013).

 

     [35]  Photon-mediated interaction between distant quantum dot circuits

            M.R. Delbecq, L.E. Bruhat, J.J. Viennot, S. Datta, A. Cottet and T. Kontos,   

            Nature Communications 4, Article number: 1400 (2013).

2012

     [34]  Microwave spectroscopy of a Cooper pair beam splitter

           A. Cottet, Phys. Rev. B 86, 075107 (2012).

 

     [33]  Subradiant split Cooper pairs

           A. Cottet, T. Kontos, and A. Levy Yeyati, Phys. Rev. Lett. 108, 166803 (2012).

           see also:  Supplemental Material

 

2011

     [32]  Coupling a Quantum Dot, Fermionic Leads, and a Microwave Cavity on a Chip

           M.R. Delbecq, V. Schmitt, F.D. Parmentier, N. Roch, J.J. Viennot, G. Fčve, B. Huard, C. Mora, A. Cottet, and T. Kontos,

           Phys. Rev. Lett. 107, 256804 (2011).

          see also:  Supplemental Material

   

    [31]  Inducing triplet superconducting correlations in a normal metal

           A. Cottet, Phys. Rev. Lett. 107, 177001 (2011).

 

    [30]  Gate-dependent spin-torque in a nanoconductor-based spin-valve

           A. Cottet, Phys. Rev. B 84, 054402 (2011).

 

    [29]  Mesoscopic admittance of a double quantum dot

           A. Cottet, C. Mora, and T. Kontos, Phys. Rev. B 83, 121311(R) (2011).

 

2010

 

    [28]  A spin quantum bit with ferromagnetic contacts for circuit QED

          A. Cottet and T. Kontos, Phys. Rev. Lett. 105, 160502 (2010)

          see also:  Supplemental Material

 

    [27] Conserved spin and orbital phase along carbon nanotubes connected with multiple ferromagnetic contacts

           C. Feuillet-Palma, T. Delattre, P. Morfin, J.-M. Berroir, G. Fčve, D.C. Glattli, B. Plaçais, A. Cottet and T. Kontos

           Phys. Rev. B 81, 115414 (2010).

2009

 

    [26]  Spin-dependent boundary conditions for isotropic superconducting Green's functions

           A. Cottet,  D. Huertas-Hernando,  W. Belzig,  and Y. V. Nazarov, Phys. Rev. B 80, 184511 (2009).

           see also:

           Erratum, A. Cottet,  D. Huertas-Hernando,  W. Belzig,  and Y. V. Nazarov, Phys. Rev. B 83, 139901(E) (2011).

           arXiv:0911.4784v2: full condmat version, including the corrections from the erratum

 

    [25]  Multiterminal spin-dependent transport in ballistic carbon nanotubes

           A. Cottet, C. Feuillet-Palma, and T. Kontos, Phys. Rev. B 79, 125422 (2009).

 

    [24]  Superconducting/Ferromagnetic diffusive bilayer with a spin-active interface: a numerical study

           A. Cottet and J. Linder, Phys. Rev. B 79, 054518 (2009).

2008

 

    [23]  Finite frequency noise of a superconductor/ferromagnet quantum point contact

           A. Cottet, B. Douçot and W. Belzig, Phys. Rev. Lett. 101, 257001 (2008).

 

    [22]  Conductance and current noise of a superconductor/ferromagnet quantum point contact

            A. Cottet and W. Belzig, Phys. Rev. B 77, 064517 (2008).

2007

    [21]  Spectroscopy and critical temperature of diffusive superconducting/ferromagnetic hybrid structures with spin-active interfaces

           A. Cottet, Phys. Rev. B 76, 224505 (2007).

 

    [20]  Towards Nanospintronics

           T. Kontos and A. Cottet, Europhys. News 38, 28 (2007).

2006

    [19]  Nanospintronics with carbon nanotubes

           A. Cottet, T. Kontos, S. Sahoo, H.T. Man, M.-S. Choi, W. Belzig, C. Bruder, A.F. Morpurgo and C. Schönenberger

           Semicond. Sci. Technol. 21, S78 (2006).

 

    [18]  Magnetoresistance of a quantum dot with spin-active interfaces

           A. Cottet and M.-S. Choi,

           Phys. Rev. B. 74, 235316 (2006).

 

    [17]  Controlling spin in an electronic interferometer with spin-active interfaces

           A. Cottet, T. Kontos, W. Belzig, C. Schönenberger and C. Bruder,

           Europhys. Lett. 74, 320 (2006).                                                                        

2005

    [16]  Electric field control of spin transport

           S. Sahoo, T. Kontos, J. Furer, C. Hoffmann, M. Graber, A. Cottet and C. Schönenberger

           Nature Phys. 1, 99 (2005).

           see also: Supplementary information

 

    [15]  Superconducting proximity effect in a diffusive ferromagnet with spin-active interfaces

           A.  Cottet and W. Belzig, Phys. Rev. B 72, 180503(R) (2005).

 

2004

 

    [14]  "Dynamical Spin-Blockade and positive cross-correlations in a quantum dot connected to three  ferromagnetic leads"

           A. Cottet, W. Belzig, and C. Bruder,

           in " Quantum information and decoherence in nanosystems ", Proceedings of the "Rencontres

           de Moriond" (La Thuile, 2004), Thę Giói  Publishers (2004).

 

    [13]  Positive cross-correlations due to Dynamical Channel Blockade in a three-terminal quantum dot

           A. Cottet, W. Belzig, and C. Bruder, Phys. Rev. B 70, 115315 (2004).

 

    [12]   Dynamical Spin-Blockade in a quantum dot with paramagnetic leads

           A. Cottet and W. Belzig, Europhys. Lett. 66, 405 (2004).

 

    [11]  Positive cross-correlations in a three-terminal quantum dot with ferromagnetic contacts

           A. Cottet, W. Belzig, and C. Bruder, Phys. Rev. Lett. 92, 206801 (2004)

 

2003

    [10]  Towards Quantum Electrical Circuits

           D. Vion, A. Aassime, A. Cottet, P. Joyez, H. Pothier, C. Urbina, M.H. Devoret, and D. Esteve,

           Physica E, 18,7 (2003).

 

    [9]   Rabi oscillations, Ramsey fringes and spin echoes in an electrical circuit

           D. Vion, A. Aassime, A. Cottet, P. Joyez, H. Pothier, C. Urbina, D. Esteve and M.H. Devoret,

           Fortschritte der Physik, 51, 462 (2003).

 

    [8]  "Manipulation and Readout of a Josephson Qubit"

           D. Vion, A. Aassime, A. Cottet, P. Joyez, H. Pothier, M.H. Devoret, C. Urbina, and D. Esteve,

           in " Quantum Computing and Quantum Bits in Mesoscopic Systems ", Macroscopic Quantum

           Computing Conference Proceedings, Plenum Publishers (2003).

 

 

2002

 

    [7]  "Superconducting quantum bit based on the Cooper pair box", 

           D. Vion, A. Aassime, A. Cottet, P. Joyez, H. Pothier, C. Urbina, D. Esteve, and M.H. Devoret

           pp. 475-491 in: "Experimental Quantum Computation and Information", Proceedings of the

           International School of Physics Enrico Fermi, vol 148, IOS Press (2002).

 

    [6]  "Ramsey fringe measurement of decoherence in a novel superconducting quantum bit circuit

          based  on the Cooper pair box",  D. Vion, A. Aassime, A. Cottet, P. Joyez, H. Pothier, C. Urbina,

           D. Esteve, and M.H. Devoret, Phys. Scripta T102, 162-166 (2002).

 

    [5]  Manipulating the quantum state of an electrical circuit

          D. Vion, A. Aassime, A. Cottet, P. Joyez, H. Pothier, C. Urbina, D. Esteve, and M.H. Devoret,

          Science 296, 886 (2002)

 

    [4]  Implementation of a combined charge-phase quantum bit in a superconducting circuit

          A. Cottet, D. Vion, P. Joyez, A. Aassime, D. Esteve, and M.H. Devoret, Physica C 367, 197 (2002)

 

    [3]  A hysteretic single Cooper pair transistor for single-shot reading of a charge-qubit

          A.  Cottet, D. Vion, P. Joyez, D. Esteve, and M.H. Devoret,

          p. 73 in "International Workshop on Superconducting Nano-electronics Devices ''

          J. Pekola,  B. Ruggiero, and P. Silvestrini eds., Kluwer Academic, Plenum Publishers, New York (2002).

 

 

2001

 

    [2]  Superconducting electrometer for measuring the single Cooper pair box

          A. Cottet, A. Steinbach, P. Joyez, D.Vion, H. Pothier, and D. Esteve, M.E. Huber,

          pp. 111 in: ``Macroscopic Quantum Coherence and Quantum Computing'',

          D.V. Averin, B. Ruggiero, P. Silvestrini eds., Kluwer Academic, Plenum Publishers, New York (2001).

 

    [1]  Direct measurement of the Josephson supercurrent in an ultrasmall Josephson junction

          A. Steinbach, P. Joyez, A. Cottet, D. Esteve, M.H. Devoret, M.E. Huber, J.M. Martinis,

          Phys. Rev. Lett. 87, 137003 (2001).

 

    PhD Thesis                                                                                                                                                                              

    Implementation of a quantum bit in a superconducting circuit, Université Paris VI, 2002.

 

    HDR Thesis

     Hybrid Quantum Circuits, Ecole Normale Supérieure de Paris, 2017.