Publications

100. F. Ghimenti, L. Berthier, J. Kurchan, and F. van Wijland, What do clever algorithms for glasses do? Time reparametrization at work.

99. F. Ghimenti, L. Berthier, and F. van Wijland, Monte Carlo simulations of glass-forming liquids beyond Metropolis.

98. Y. Zhao, R. Zakine, A. Daerr, Y. Kafri, J. Tailleur, and F. van Wijland, soumis, Active Young-Dupré Equation: How Self-organized Currents Stabilize Partial Wetting.

97. F. Ghimenti, L. Berthier, G. Szamel, and F. van Wijland, Phys. Rev. E (2024), Irreversible Boltzmann samplers in dense liquids: weak-coupling approximation and mode-coupling theory. Editors' suggestion.

96. F. Ghimenti, L. Berthier, G. Szamel, and F. van Wijland, Phys. Rev. E 109, 064133 (2024), Transverse forces and glassy liquids in infinite dimensions. Highlighted on X.

95. D. Martin, G. Spera, H. Chaté, C. Duclut, C. Nardini, J. Tailleur, and F. van Wijland, JSTAT (2024), Fluctuation-Induced First Order Transition to Collective Motion.

94. F. Ghimenti, L. Berthier, and F. van Wijland, Phys. Rev. Lett. 133, 028202 (2024), Irreversible Monte Carlo algorithms for hard disk glasses: from event-chain to collective swaps. Editors' suggestion.

93. H. Noguchi, F. van Wijland, and J.-B. Fournier, J. Chem. Phys. 161, 025101 (2024), Cycling and spiral-wave modes in an active cyclic Potts model.

92. F. Ghimenti, L. Berthier, G. Szamel, and F. van Wijland, Phys. Rev. Lett. 131, 257101 (2023), Sampling efficiency of transverse forces. Editor's suggestion.

91. T. Arnoulx de Pirey and F. van Wijland, JSTAT 093202 (2023), A run-and-tumble particle around a spherical obstacle: steady-state distribution far-from-equilibrium.

90. T. Arnoulx de Pirey, L. Cugliandolo, V. Lecomte, and F. van Wijland, Advances in Physics (2023), Path integrals and Stochastic Calculus.

89. T. Arnoulx de Pirey and F. van Wijland, Phase separation in an effective equilibrium model of active matter: a transition driven by multibody Interactions.

88. T. Kühn and F. van Wijland, J. Phys. A 56, 115001 (2023), Diagrammatics for the Inverse Problem in Spin Systems and Simple Liquids.

87. T. Arnoulx de Pirey and F. van Wijland, J. Phys. A 56, 115003 (2023), Nonlinear analog of the complexity-stability transition in random dynamical systems: a replica calculation.

86. F. Ghimenti and F. van Wijland, Phys. Rev. E 105, 054137 (2022), Accelerating, to some extent, the p-spin dynamics.

85. T. Arnoulx de Pirey, A. Manacorda, F. van Wijland, and F. Zamponi, J. Chem. Phys. 155, 174106 (2021), Active matter in infinite dimensions: Fokker-Planck equation and dynamical mean-field theory at low density.

84. J. O'Byrne, Y. Kafri, J. Tailleur, and F. van Wijland,  Nature Reviews Physics (2022), Time-(ir)reversibility in active matter: from micro to macro.

83. Q. Goutaland, F. van Wijland, and J.-B. Fournier, Soft Matter 17, 5560 (2021), Binding of thermalized and active membrane curvature-inducing proteins.

82. Y.-E. Keta, É. Fodor, F. van Wijland, M. E. Cates, R. L. Jack, Phys. Rev. E 103, 022603 (2021), Collective motion in large deviations of active particles.

81. D. Martin, J. O'Byrne, M. E. Cates, É. Fodor, C. Nardini, J. Tailleur, F. van Wijland, Phys. Rev. E 103, 032607 (2021), Statistical Mechanics of Active Ornstein Uhlenbeck Particles.

80. D. Martin, H. Chaté, C. Nardini, A. Solon, J. Tailleur, and F. van Wijland, Phys. Rev. Lett. 126, 148001 (2021), Fluctuation-induced phase separation in metric and topological models of collective motion.

79. T. Arnoulx de Pirey, G. Lozano, and F. van Wijland, Phys. Rev. Lett. 123, 260602 (2019), Active hard spheres in infinitely many dimensions and the Supplemental Material.

78. R. Zakine, Y. Zhao, M. Knežević, A. Daerr, Y. Kafri, J. Tailleur, and F. van Wijland, Phys. Rev. Lett. 124, 248003 (2020), Surface Tensions between Active Fluids and Solid Interfaces: bare vs dressed.

77. R. Zakine, J.-B. Fournier, and F. van Wijland, Phys. Rev. E 101, 022105 (2020), Spatial Organization of Active Particles with field mediated interactions.

76. P. Bohec, J. Tailleur, F. van Wijland, A. Richert, and F. Gallet, Soft Matter 15, 6952 (2019), Distribution of active forces in the cell cortex.

75. É. Fodor, H. Hayakawa, J. Tailleur, and F. van Wijland, Phys. Rev. E 98, 062610 (2018), Non-Gaussian noise without memory in active matter.

74. L. F. Cugliandolo, V. Lecomte, and F. van Wijland, J. Phys. A 52, 50LT01 (2019), Building a path-integral calculus: a covariant discretization approach.

73.  F. Caballero, C. Nardini, F. van Wijland, and M. E. Cates, Phys. Rev. Lett. 121, 020601 (2018), Strong coupling in conserved surface roughening: A new universality class? Reviewed in the condensed-matter journal club.

72. R. Zakine, J.-B. Fournier, and F. van Wijland, Phys. Rev. Lett. 121, 028001 (2018), Field-Embedded Particles Driven by Active Flips.

71. R. Zakine, A. Solon, T. Gingrich, and F. van Wijland, Entropy 19, 193 (2017), Stochastic Stirling engine operating in contact with active baths.

70. C. Nardini, É. Fodor, E. Tjhung, F. van Wijland, J. Tailleur, M. E. Cates, Phys. Rev. X 7, 021007 (2017), Entropy production in field theories without time reversal symmetry: Quantifying the non-equilibrium character of active matter.

69. É. Fodor, C. Nardini, M. E. Cates, J. Tailleur, P. Visco, and F. van Wijland, Phys. Rev. Lett. 117, 038103 (2016), How far from equilibrium is active matter? Editor's Suggestion and Featured in Physics: In, Yet Out of Equilibrium.

68. É. Fodor, H. Hayakawa, P. Visco, and F. van Wijland, Phys. Rev. E 94, 012610 (2016), Active cage model of glassy dynamics.

67. T. Laffargue, P. Sollich, J. Tailleur, and F. van Wijland, Large deviations of the largest Lyapunov exponent in diffusive systems.

66. T. Laffargue, J. Tailleur, and F. van Wijland, J. Stat. Mech. 034001 (2016), Lyapunov exponents of stochastic systems - from micro to macro.

65. E. Ben-Isaac, É. Fodor, P. Visco, F. van Wijland, and Nir S. Gov, Phys. Rev. E 92, 012716 (2015), Modeling the dynamics of a tracer particle in an elastic active gel.

64. L. Cugliandolo, P.-M. Déjardin, G. Lozano, and F. van Wijland, Phys. Rev. E 91, 032139 (2015), Stochastic dynamics of collective modes for Brownian dipoles.

63. T. Laffargue, P. Sollich, J. Tailleur, and F. van Wijland, Europhysics Letters 110, 10006 (2015), Large-scale fluctuations of the largest Lyapunov exponent in diffusive systems.

62. É. Fodor, W. W. Ahmed, M. Almonacid, M. Bussonnier, N. S. Gov, M.-H. Verlhac, T. Betz, P. Visco, and F. van Wijland, Europhysics Letters 116, 30008 (2016), Nonequilibrium dissipation in living oocytes.

61. R. Colin, B. Abou, V. Lecomte, E. Pitard, and F. van Wijland, J. Chem. Phys. 148, 164502 (2018), Activity statistics in a colloidal glass former: experimental evidence for a dynamical transition.

60. V. Mehandia, D. Riveline, É. Fodor, N. Gov, P. Visco, and F. van Wijland, Biophysical Journal 114, 939 (2018), Spatial fluctuations at thevertices of epithelial monolayers: a quantitative study of regulation by theRho pathway. With a flyer by the Editor.

59. W. Ahmed, É. Fodor , M. Almonacid, M. Bussonnier, M.-H. Verlhac, N. Gov, P. Visco , F. van Wijland , T. Betz , Biophysical Journal 114, 1667 (2018), Active Mechanics Reveal Molecular-Scale Force

Kinetics in Living Oocytes.

58. É. Fodor, K. Kanazawa, H. Hayakawa, P. Visco, and F. van Wijland, Phys. Rev. E 90, 042724 (2014), Probing Active Fluctuations in Living Cells: Energetic Approaches.

57. É. Fodor, D. Grebenkov, P. Visco, and F. van Wijland, Physica A 422, 107 (2015), Generalized Langevin Equation with Hydrodynamic Backflow: Equilibrium Properties.

56. T. Nemoto, V. Lecomte, S.-i. Sasa, and F. van Wijland, J. Stat. Mech. P10001 (2014), Finite size effects in a mean-field kinetically constrained model: dynamical glassiness and quantum criticality.

55. É. Fodor, M. Guo, N. Gov, P. Visco, D. Weitz, and F. van Wijland, Europhysics Letters 110, 48005 (2015), Activity-driven fluctuations in living cells. Appeared as a Europhysics News Highlight.

54. B. Kim, K. Kawasaki, H. Jacquin, and F. van Wijland, Phys. Rev. E 89, 012150 (2014), Equilibrium dynamics of the Dean-Kawasaki equation: Mode-coupling theory and its extension.

53. C. Maes, S. Safaverdi, P. Visco, and F. van Wijland, Phys. Rev. E 87, 022125 (2013), Fluctuation-dissipation relations for nonequilibrium diffusions.

52. H. Jacquin, B. Kim, K. Kawasaki, and F. van Wijland, Phys. Rev. E 91, 022130 (2015), Brownian dynamics: from glassy to trivial.

51. P. Bohec, F. Gallet, C. Maes, S. Safaverdi, P. Visco and F. van Wijland, Europhys. Lett. 102, 50005 (2013), Probing active forces via a fluctuation-dissipation relation.

50. V. Lecomte, J.P. Garrahan and F. van Wijland, J. Phys. A 45, 175001 (2012), Inactive dynamical phase of a symmetric exclusion process on a ring.

49. H. Jacquin and F. van Wijland, Phys. Rev. Lett. 106, 210602 (2011), Field theoretic formulation of a mode-coupling equation for colloids.

48. K. Röller, S. Herminghaus, and F. van Wijland, soumis, Velocity distribution of a dilute wet granular gas.

47. E. Pitard, V. Lecomte, and F. van Wijland, Eur. Phys. Lett. 96, 56002 (2011), Dynamic transition in an atomic glass former: a molecular dynamics evidence.

46. D.-L. González Cabrera, Z. Rácz and F. Van Wijland, Phys. Rev. A 81, 052512 (2010), .Casimir effect in the nonequilibrium steady-state of a quantum spin chain

45. V. Lecomte, A. Imparato and F. van Wijland, Prog. Theor. Phys. Suppl. 184, 276 (2010), Current fluctuations in systems with diffusive dynamics, in and out of equilibrium.

44. K. van Duijvendijk, R.L. Jack and F. van Wijland, Phys. Rev. E 81, 011110 (2010), .Second-order dynamic transition in a p=2 spin-glass model

43. A. Imparato, V. Lecomte and F. van Wijland, Phys. Rev. E 80, 011131 (2009), Equilibirum-like fluctuations in some boundary-driven open diffusive systems.

42. J.P. Garrahan, R.L. Jack, V. Lecomte, E. Pitard, K. van Duijvendijk and F. van Wijland, J. Phys. A 42, 075007 (2009) First-order dynamical phase transition in models of glasses: an approach based on ensembles of histories.

41. T. Bodineau, B. Derrida, V. Lecomte and F. van Wijland, J. Stat. Phys 133, 1013 (2008) Long range correlations and phase transition in nonequilibrium diffusive systems.

40. K. van Duijvendijk, G. Schehr and F. van Wijland, Phys. Rev. E 78, 011120 (2008) Slow relaxation, dynamic transitions and extreme value statistics in disordered systems.

39. C. Appert-Rolland, B. Derrida, V. Lecomte and F. van Wijland, Phys. Rev. E 78, 021122 (2008) Universal cumulants of the current in diffusive systems on a ring.

38. P. Visco, F. van Wijland and E. Trizac, Phys. Rev. E 77, 041117 (2008) Collisional statistics of the hard-sphere gas.

37. P. Visco, F. van Wijland and E. Trizac, J. Phys. Chem. B 112, 5412(2008) Non Poissonian statistics in a low density fluid.

36. J.P. Garrahan, R.L. Jack,V. Lecomte, E. Pitard, K. van Duijvendijk and F. van Wijland, Phys. Rev. Lett. 98, 195702 (2007)Dynamic first-order transition in kinetically constrained models of glasses.

35. V. Lecomte, C. Appert-Rolland and F. van Wijland, Cr. Acad. Sc. Paris 8, 609 (2007), Thermodynamic formalism and large deviation functions in continuous-time Markov dynamics.

34. P. Visco, A. Puglisi, A. Barrat, E. Trizac and F. van Wijland, Cr. Acad. Sc. Paris 8, 641 (2007), Power injected in a granular gas.

33. V. Lecomte, U.C. Täuber and F. van Wijland, J. Phys. A 40, 1447 (2007), Current distribution in systems with anomalous diffusion: renormalization group approach.

32. V. Lecomte, C. Appert-Rolland and F. van Wijland, J. Stat. Phys. 127, 51 (2007), Thermodynamic formalism for systems with Markov dynamics.

31. F. van Wijland, Phys. Rev. E 74, 063101 (2006), Comment on: “Heat fluctuations in Brownian transducers”.

30. P. Visco, A. Puglisi, A. Barrat, F. van Wijland and E. Trizac, Eur. Phys. J. B 51, 377 (2006), Energy fluctuations in vibrated and driven granular gases.

29. I. Bena, F. Coppex, M. Droz, P. Visco, A. Barrat, A. Puglisi, E. Trizac and F. van Wijland, Physica A 370, 179 (2006), Stationary state of a granular gas: fate of the usual H-functional.

28. A. Puglisi, P. Visco, E. Trizac and F. van Wijland, Phys. Rev. E 73, 021301 (2006), Dynamics of a tracer granular particle as a nonequilibrium Markov process.

27. P. Visco, A. Puglisi, A. Barrat, E. Trizac and F. van Wijland, J. Stat. Phys. 125, 533 (2006), Fluctuations of power injection in randomly driven granular gases.

26. V. Lecomte, C. Appert-Rolland and F. van Wijland, Phys. Rev. Lett. 95, 010601 (2005), Chaotic properties of systems with Markov dynamics.

25. P. Visco, A. Puglisi, A. Barrat, E. Trizac and F. van Wijland, Europhys. Lett. 72, 55 (2005), Injected power and entropy flow in a heated granular gas.

24. A. Puglisi, P. Visco, A. Barrat, E. Trizac and F. van Wijland, Phys. Rev. Lett. 95, 110202 (2005), Fluctuations of internal energy flow in a vibrated granular gas.

23. V. Lecomte, Z. Rácz and F. van Wijland, J. Stat. Mech, P02008 (2005), Energy flux distribution in a two-temperature Ising model.

22. R. Agra, E. Trizac and F. van Wijland, Eur. J. Phys. 27, 407 (2006), On the free energy within the mean-field approximation.

21. F. van Wijland and Z. Rácz, J. Stat. Phys. 118, 27 (2005), Large deviations in weakly interacting driven lattice gases.

20. R. Agra, F. van Wijland and E. Trizac, Phys. Rev. Lett. 93, 018304 (2004), Theory of orientational ordering in colloidal molecular  crystals.

19. H.-K. Janssen, F. van Wijland, O. Deloubrière and U.C. Täuber, Phys. Rev. E 70, 056114 (2004), Pair Contact Process with Diffusion: Failure of master equation field theory.

18. F. van Wijland, Physica A 332, 360 (2004), Phonon displacement distribution at T=0.

17. F. van Wijland, Brazilian Journal of Physics 33, 551 (2003), Infinitely-many absorbing states nonequilibrium phase transitions.

16. V. Eisler, Z. Racz et F. van Wijland, Phys. Rev. E 67, 056129 (2003), Transverse Ising chain with energy flux: Magnetization distributions.

15. F. van Wijland, Phys. Rev. Lett. 89, 190602 (2002), Universality class of a nonequilibrium phase transitions with infinitely many absorbing states.

14. F. van Wijland, J. Phys. A 35, 5391 (2002),Trapping of a random walk by diffusing traps.

13. O. Deloubrière and F. van Wijland, Phys. Rev. E 65, 046104 (2002), Simple absorbing state transition.

12. H.J. Hilhorst and F. van Wijland, Phys. Rev. E 65, 035103(R) (2002),  Equivalence of stationary state ensembles.

11. A. Barrat, T. Biben, E. Trizac, Z. Rácz and F. van Wijland, J. Phys. A 35, 463 (2002), On the velocity distributions of the one-dimensional inelastic gas.

10. F. van Wijland, Phys. Rev. E 63, 022101 (2001), Field theory for reaction-diffusion processes with hard-core particles.

9. A.M. Mariz, F. van Wijland, H.J. Hilhorst, S. R. Gomes Junior and C. Tsallis, J. Stat. Phys 102, 259 (2001), Statistics of the one-dimensional Riemann walk.

8. V. Brunel, K. Oerding and F. van Wijland , J. Phys. A 33, 1085 (2000), Fermionic field-theory for

directed percolation in 1+1 dimensions.

7. K. Oerding, F. van Wijland, J.-P. Leroy and H.J. Hilhorst, J. Stat. Phys. 99, 1365 (2000), Fluctuation-induced first-order transition in a nonequilibrium steady-state.

6. K. Oerding, H.K. Janssen, F. van Wijland and H.J. Hilhorst, Eur. Phys. J. B 7, 137 (1999), Lévy-flight spreading of epidemic processes leading to percolating clusters.

5. F. van wijland and K. Oerding, J. Phys. A 31, 7011 (1998), Global persistence in directed percolation.

4. F. van Wijland, H.J. Hilhorst et K. Oerding, Physica A 251, 179 (1998),Wilson renormalization of a reaction-diffusion process.

3. F. van Wijland et H.J. Hilhorst, J. Stat. Phys. 89, 119 (1997), Universal fluctuations in the support of the random walk.

2. F. van Wijland, S. Caser et H.J. Hilhorst, J. Phys. A 30, 507 (1997), Properties of the set of distinct sites visited by a two-dimensional random walk.

1. D.L. Leslie-Pelecky, F. van Wijland, C.N. Hoff, J.A. Cowen, A. Gavrin and C.L. Chien, J. Appl. Phys. 75, 6489 (1994), Comparison of the electron spin resonance linewidth of multilayered spin glass with insulating versus conducting interlayers.

Autres publications

5. A. Puglisi, P. Visco, A. Barrat, E. Trizac and F. van Wijland, proceedings of the Reggio Calabria symposium on Granular matter: mathematical modeling and physical instances (2005), Lecture Notes in Mathematics 1937 (2008, Springer), Fluctuations in granular gases.

4. A. Puglisi, P. Visco, A. Barrat, E. Trizac and F. van Wijland, Powders and Grains 2005 , R. Garcia-Rojo, H.J. Herrmann and S. McNamara Eds.,  (A.A.Balkema, Rotterdam, 2005), On the validity of Gallavotti-Cohen fluctuation relation in driven granular gases.

3. F. van Wijland,  European Journal of Physics 18, 408 (1997), Video review on The Nature

of Space and Time by S. Hawking and R. Penrose .

2. co-auteur de Dix problèmes corrigés, Centrale/Supélec, Ed.Vuibert (1994).

1. co-auteur de 1994 : L'esprit des concours, Ed. Média et Prépas (1993).