Sub-gap conductance fluctuations in superconductor-graphene hybrid nanostructures

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Sub-gap conductance fluctuations in superconductor-graphene hybrid nanostructures G.Albert, B.Kaviraj, F.Gustavo, F.Lefloch, L.Jansen Laboratoire de Transport Electronique Quantique et Supraconductivité INAC, CEA Grenoble Prénom Nom - Guillaume Direction des Albert Sciences GDR de Méso la Matière 2010

Outline Superconductor-Graphene hybrid nanostructures Conductance fluctuations in the normal state Superconductivity-enhanced fluctuations Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 2

Graphene A new nanomaterial : Monolayer of carbon atoms High mobility Field-effect devices A unique band structure : Linear dispersion relation 10µm Anomalous Quantum Hall Effect T = 4 K Castro Neto et al., Rev. Mod. Phys. 81, 109 (2009) Dirac cones Novoselov et al.(2007) Nature 438, 197. Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 3

Graphene and superconductivity Specular Andreev reflection : C.W.J. Beenakker.(2007) Rev.Mod.Phys. 80, 1337 Some realizations : H.B.Heersche et al., Nature 446, 56-59 (2007). X. Du et al., Phys. Rev. B 77, 184507 (2008). B.M Kessler et al., PRL 104, 047001 (2010). Observation of tunable Josephson effect Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 4

Sample design BIAS MEASURE I DC V DC I AC 10 µm V AC 10 µm Mechanical exfoliation on SiO 2 /Si wafer Deposition of Aluminum contacts by e-beam lithography 1 Sample : 3 S-G-S junctions W = 3 µm, L = 300 nm Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 5

Outline Superconductor-Graphene hybrid nanostructures Conductance fluctuations in the normal state Superconductivity-enhanced fluctuations Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 6

Field effect in the normal state Appearance of conductance fluctuations at low temperatures σ = n e µ Evaluation of the mobility : µ = 500 1000 V.cm²/s 10 µm Mean free path l = 10 nm Diffusion constant D = 5.10-3 m²/s Thouless energy Eth = 40 µev = 0.5K The sample is small enough to see Universal Conductance Fluctuations Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 7

Specific studies : UCF in graphene N.E. Stanley et al., PRB 77, 155429 (2008) Magnetic field signatures of UCF Decrease of UCF amplitude at Dirac point C. Ojeda-Aristizabal, H. Bouchiat et al., PRL 104, 186802 (2010) Study of correlations versus gate voltage Increase of UCF amplitude at Dirac point D. W. Horsell et al., Arxiv 0902:0904 (2009) Study of UCF correlations and weak localization amplitude No change UCF amplitude at Dirac point Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 8

Around the Dirac point Two sources of fluctuations : σ = n(ef) e µ(ef) Inhomogeneous sample : e h puddles at Dirac Point Martin et al., Nature Physics 4,144-148 (2008) Interferences : Universal conductance fluctuations L φ > L sample k f l > 1 Valid at the Dirac point? Percolating effects? Situation is not clear Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 9

Outline Superconductor-Graphene hybrid nanostructures Conductance fluctuations in graphene Superconductivity-enhanced fluctuations Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 10

Field effect and superconductivity Drop in the resistance of the S-G-S junction at T = 0.52 K Reproducible fluctuations get sharper Vgate = 0 V 10 µm Resistance nearly drops to zero at high gate voltage Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 11

Josephson effect in graphene Measurements of differential resistance at high gate voltage : Versus Temperature V gate = 30 V 2 = 100 µv Multiple Andreev reflections minima at 2 /2 and 2 /3 Central dip : Josephson effect ħic E J = = 10 µv 2e ~ k B T at 100mK Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 12

Josephson effect in graphene Measurements of differential resistance at high gate voltage : Versus Magnetic field V gate = 30 V T = 50 mk Critical field of the junction : H c = 140 Gauss B Fraunhofer-like pattern : Φ 0 = B x S Sample surface : S = 1 µm² Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 13

Josephson effect in graphene Measurements of differential resistance versus gate voltage : T = 50 mk Multiple Andreev reflections are still present Suppression of Josephson effect The amplitude of the peak varies strongly with small changes of the gate voltage Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 14

Enhanced conductance fluctuations Measurements of differential resistance at low gate voltage : T = 50 mk Strong fluctuations at zero bias Small fluctuations out of the gap Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 15

Enhanced conductance fluctuations Study versus temperature : Tc = 520 mk Correlations between normal state and superconducting state Increase of fluctuations amplitude by a factor 4 below T c Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 16

Enhanced conductance fluctuations Study versus Magnetic field : T = 50 mk Hc = 140 Gauss Suppression of the fluctuations below critical magnetic field Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 17

Connection with other works Another observation of the phenomenon : J.Trbovic, N.Minder, F.Freitag, C.Schönenberger, Nanotechnology 21, 274005 (2010) dip Sub-gap enhanced Fluctuations A peak below the gap : peak C. Ojeda-Aristizabal, M.Ferrier, S. Guéron, H.Bouchiat, PRB 79, 165436 (2009). Suppression of the peak by cleaning the sample Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 9/20/2010 18

Pioneer works Theory : F. Zhou, B. Spivak, JETP 65, iss.4, 347-352. Phase-sensitive transport through SNS junctions C.W.J. Beenakker, arxiv 9406083v2 (2005). Calculations for quasi-1d wires Experiments : K. Hecker, H. Hegger, A. Atland, K. Fiegle, PRL 79, 1548-1550 (1997) Study of UCF in a N-S junction Factor 2x 2 observed in amplitude between N and S state V.T. Petrashov, V.N. Antonov, P. Delsing, R.Claeson, PRL 70, 347-350 (1993) Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 20/09/2010 19

Conclusion Suppression of Josephson effect near the Dirac point Enhancement of conductance fluctuations by superconductivity Perspectives : Quantitative study of UCF and weak localization Need for a model of transport near the Dirac point Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 9/20/2010 20

The end Thank you for attention Prénom Guillaume Nom Albert - Direction GDR des Méso Sciences 2010 de la Matière 9/20/2010 21