Current research interests: Statistical mechanics in and out of equilibrium,
Stochastic and information thermodynamics.
Keywords: Liquid state theory, Coulomb systems, Adsorption phenomena, Porous media, Disordered spin systems, Langevin dynamics, Timedelayed stochastic differential equations, Information theory and feedback control.
Publications

[1] Utilisation des fonctions mémoire dans l’étude de la conductivité électrique des solutions électrolytiques diluées, J.P. Badiali et M.L. Rosinberg, C.R. Acad. Sci. 6, 825 (1973).
[2] Structural properties of ionic systems in the restricted primitive model and in a model involving ionsolvent hard core repulsion, J.P. Badiali, J.C. Lestrade and M.L. Rosinberg, Chem. Phys. Lett. 156, 34 (1975).
[3] Ionsolvent interactions and ionic motion. Application to the limiting mobility in a hard sphere liquid, J.P. Badiali, J.C. Lestrade and M.L. Rosinberg, in Protons and Ions involved in Fast Dynamic Phenomena, Elsevier, Amsterdam (1978).
[4] A model for the calculation of surface energy and surface tension of liquid metals, S. Amokrane, J.P. Badiali, M.L. Rosinberg and J. Goodisman, J. Physique C8, 783 (1980).
[5] Image potential of a point dipole in the vicinity of a non perfect charged medium, J.P. Badiali and M.L. Rosinberg, J. Electroanal. Chem. 122, 45 (1981).
[6] Effect of solvent on properties of the liquid metal surface, J.P. Badiali, M.L. Rosinberg and J. Goodisman, J. Electroanal. Chem. 130, 31 (1981).
[7] Firstorder model for the surface properties of liquid metals : electroneutrality condition and interionic correlations, S. Amokrane, J.P. Badiali, M.L. Rosinberg and J. Goodisman, J. Chem. Phys 76, 3264 (1982).
[8] Mean spherical approximation for charged hard spheres near a charged hard wall in a neutralizing background, J.P. Badiali and M.L. Rosinberg, J. Chem. Phys. 76, 3264 (1982).
[9] Contribution of the metal to the differential capacity of an ideally polarisable electrode, J.P. Badiali, M.L. Rosinberg and J. Goodisman, J. Electroanal. Chem. 143, 73 (1983).
[10] Surface density profile of the onecomponent plasma, J.P. Badiali, M.L. Rosinberg, D. Levesque and J.J. Weis, J. Phys. C. 16, 2183 (1983).
[11] The metal in the polarisable interface : coupling with the solvent phase, J.P. Badiali, M.L. Rosinberg and J. Goodisman, J. Electroanal. Chem. 150, 25 (1983).
[12] Density functional calculations for liquid metal surfaces, J. Goodisman and M.L. Rosinberg, J. Phys. C: Solid State Phys., 16, 1143 (1983).
[13] On surface properties of the onecomponent plasma, M.L. Rosinberg, J.P. Badiali and J. Goodisman, J. Phys. C: Solid State Phys. 16, 4487 (1983).
[14] The meanspherical approximation for the surface density profile of the onecomponent plasma II, M.L. Rosinberg and J.P. Badiali, J. Chem. Phys. 78, 6325 (1983).
[15] A microscopic model for the liquid metalionic solution interface, J.P. Badiali, M.L. Rosinberg, F. Vericat and L. Blum, J. Electroanal. Chem. 158, 253 (1983).
[16] Structure and thermodynamics of noble liquid metals from the general pseudopotential theory, C. Regnaut, E. Fusco, M.L. Rosinberg and J.P. Badiali, J. non crystalline solids. 61, 207 (1984).
[17] Theoretical calculations on metallic surfaces : the OCP reference system, M.L. Rosinberg, V. Russier and J.P. Badiali, J. non crystalline solids. 62, 713 (1984).
[18] An exactly solvable model for ideally polarisable interfaces, M.L. Rosinberg and L. Blum, Chem. Phys. Lett. 106, 48 (1984).
[19] The ideally polarisable interface : a solvable model and general sumrules, M.L. Rosinberg and L. Blum, J. Chem. Phys. 81, 3700 (1984).
[20] The onecomponent plasma near a hard wall : surface tension and sumrules, V. Russier, J.P. Badiali and M.L. Rosinberg, J. Phys. C: Solid State Phys. 18, 707 (1985).
[21] The ideally polarisable interface : the metallic boundary limit, A. Alastuey, B. Jancovici, L. Blum, P. Forrester and M.L. Rosinberg, J. Chem. Phys. 83, 2366 (1985).
[22] The ideally polarisable interface : integral equations, M.L. Rosinberg, L. Blum and J.L. Lebowitz, J. Chem. Phys. 83, 892 (1985).
[23] Potential of meanforce on a ion near a wall in presence of a molecular solvent, J.P. Badiali, M.L. Rosinberg and V. Russier, Mol. Phys. 56, 105 (1985).
[24] A solvable model for localized adsorption in a Coulomb system, M.L. Rosinberg, J.L. Lebowitz and L. Blum, J. Stat. Phys. 44, 153 (1986).
[25] Localized adsorption at solidliquid interfaces : the sticky sitehard wall model, J.P. Badiali, L. Blum and M.L. Rosinberg, Chem. Phys. Lett.. 129, 149 (1986).
[26] Ionic solvation at the solidelectrolyte interface : a statistical mechanical approach, V. Russier, J.P. Badiali and M.L. Rosinberg, J. Electroanal. Chem. 220, 213 (1987).
[27] Modelization of the electrical doublelayer : structure of the iondipole mixture near a wall, M.L. Rosinberg, V. Russier, J.P. Badiali and M.E. Boudh’ir, Berichte der Bunsen. fur Phys. Chem. 91, 276 (1987).
[28] Adsorption of polar molecules at a wall : Monte carlo simulation and integral equations, V. Russier, M.L. Rosinberg, J.P. Badiali, D. Levesque and J.J. Weis, J. Chem. Phys. 87, 5012 (1987).
[29] A variational calculation of the static image plane position at a charged jellium interface, V. Russier and M.L. Rosinberg, J. Phys. C: Solid State Phys. 21, L333 (1988).
[30] A theoretical study of the solidelectrolyte solution interface : Structure of a hard sphere iondipole mixture near an uncharged hard wall, W. Dong, M.L. Rosinberg, A. Perera and G. Patey, J. Chem. Phys. 89, 4994 (1988).
[31] Contact theorems for models of the sticky electrode, L. Blum, M.L. Rosinberg and J.P. Badiali, J. Chem. Phys. 90, 1285 (1989).
[32] Packing effects at the solidliquid interface : Theory and computer simulation, E. Kierlik and M.L. Rosinberg, Mol. Phys. 68, 867 (1989).
[33] The role of packing effects at the liquidsolid interface : a model for a surface phase transition, E. Kierlik and M.L. Rosinberg, J. Phys. : Condensed Matter 2, 3081 (1990).
[34] Free energy density functional for the inhomogeneous hard sphere fluid : Application to interfacial adsorption, E. Kierlik and M.L. Rosinberg, Phys. Rev. A 42, 3382 (1990).
[35] Conformal invariance in onedimension and in a twocomponent loggas, P. Forrester and M.L. Rosinberg, Int. J. Modern Phys. B 4, 943 (1990).
[37] A model for a phase transition in the adsorbed film at a liquidstructured solid interface, E. Kierlik and M. L. Rosinberg, in Fundamentals of Adsorption 3, edited by A. B. Mersmann and S. E. Scholl, Engineering Foundation (1991).
The distribution of polar molecules and ions near a solid surface. The asymptotic behavior of the profile as a test of the HNC approximation, Q. Zhang, J.P. Badiali and M.L. Rosinberg, J. Molecular Liquids 48,129 (1991).
[38] A simple model for the competitive adsorption of anions and hydrogen on the (100) orientation of a platinum surface in acid medium : the 3state latticegas model, D Armand and M.L. Rosinberg, J. Electroanal. Chem. 302, 191 (1991).
[39] Density functional theory for inhomogeneous fluids : adsorption of binary mixtures, E. Kierlik and M.L. Rosinberg, Phys. Rev. A 44, 5025 (1991).
[40] A simple theoretical model for the hydrogen electrosorption on platinum in acid medium, D. Armand and M.L. Rosinberg, J. Chim. Phys.(Paris) 88, 1401 (1991).
[41] Binary vapor mixtures adsorbed on a graphite surface : a comparison of meanfield density functional theory with results from Monte Carlo simulations, E. Kierlik, M.L. Rosinberg, J. Finn and P.A. Monson, Mol. Phys. 75, 1435 (1992).
[42] The classical fluid of associating hard rods in an external field, E. Kierlik and M.L. Rosinberg, J. Stat. Phys. 68, 1037 (1992).
[43] A perturbation density functional theory for polyatomic fluids I : Rigid molecules, E. Kierlik and M.L. Rosinberg, J. Chem. Phys. 97, 9222 (1992).
[44] On the equivalence of two freeenergy models for the inhomogeneous hard sphere fluid, S. Phan, E. Kierlik, M.L. Rosinberg, B. Bildstein and G. Kahl, Phys. Rev. E 48, 618 (1993).
[45] A perturbation density functional theory for polyatomic fluids II : Flexible molecules, E. Kierlik and M.L. Rosinberg, J. Chem. Phys. 99, 3950 (1993).
[46] Equations of state for hard chain molecules, S. Phan, E. Kierlik, M.L. Rosinberg, H. Yu and G. Stell, J. Chem. Phys. 99, 5326 (1993).
[47] A perturbation density functional theory for polyatomic fluids III : Adsorption of hard chain molecules in slitlike pores, E. Kierlik and M.L. Rosinberg, J. Chem. Phys. 100, 1716 (1994).
[48] Thermodynamics of fluids in quenched disordered matrices, M.L. Rosinberg, G. Tarjus and G. Stell, J. Chem. Phys. 100, 5172 (1994).
[49] Local structure and orientational correlations in fluids composed of linear triatomic molecules, A. Yethiraj, R. Dickman, G. Szamel, E. Kierlik and M.L. Rosinberg, Mol. Phys. 82, 937 (1994).
[50] An equation of state for fused hard sphere molecules, S. Phan, E. Kierlik and M.L. Rosinberg, J. Chem. Phys. 101, 7997 (1994).
[51] Integral equations for a fluid near a random substrate, W. Dong, E. Kierlik and M.L. Rosinberg, Phys. Rev. E 50, 4752 (1994).
[52] Prewetting at a liquid mixture/solid interface : a comparison of Monte Carlo simulations with mean field density functional theory, E. Kierlik, M.L. Rosinberg, Y. Fan and P.A. Monson, J. Chem. Phys. 101, 10947 (1994).
[53] Liquidliquid equilibrium in a slitlike pore : A Monte carlo simulation and meanfield density functional theory, E. Kierlik, Y. Fan, P.A. Monson and M.L. Rosinberg, J. Chem. Phys. 102, 3172 (1995).
[54] Perturbation density functional theory and Monte Carlo simulations for the structure of hard triatomic fluids in slitlike pores, S. Phan, E. Kierlik, M.L. Rosinberg, A. Yethiraj and R. Dickman, J. Chem. Phys. 102, 2141 (1995).
[55] Critical behavior of a fluid in a disordered porous matrix. An OrnsteinZernike approach, E. Pitard, M.L. Rosinberg, G. Tarjus and G. Stell, Phys. Rev. Lett. 74, 4361 (1995).
[56] Pressure of a fluid in a porous matrix, E. Kierlik, P.A. Monson, M.L. Rosinberg and G. Tarjus, J. Chem. Phys. 103, 4256 (1995).
[57] Density functional theory for nonuniform polyatomic fluids, E. Kierlik, S. Phan and M.L. Rosinberg, in Chemical Applications of Density Functional Theory, edited by B.B. Laird, R.B. Ross and T. Ziegler, ACS Symposium Series 629 (1996).
[58] Thermodynamic of fluids in disordered porous materials, E. Pitard, M.L. Rosinberg and G. Tarjus, Molecular Simulation. 17, 339 (1996).
[59] Phase diagrams of a fluid confined in a disordered porous material, E. Kierlik, M.L. Rosinberg, G. Tarjus and P.A. Monson, J. Phys. : Condensed Matter 8, 9621 (1996).
[60] Phase diagrams of singlecomponent fluids in disordered porous materials : predictions from integralequation theory, E. Kierlik, M.L. Rosinberg, G. Tarjus and P.A. Monson, J. Chem. Phys. 106, 264 (1997).
[61] A selfconsistent OrnsteinZernike approximation for the sitediluted Ising model, E. Kierlik, M.L. Rosinberg and G. Tarjus, J. Stat. Phys. 89, 215 (1997).
[63] Mean spherical approximation for a lattice model of a fluid in disordered matrix, E. Kierlik, M.L. Rosinberg, G. Tarjus and E. Pitard, Mol. Phys. 95, 341 (1998).
Applications of modern statistical mechanics to adsorption in heterogeneous porous materials, E. Kierlik, M.L. Rosinberg, G. Tarjus, and P. A. Monson in Fundamentals of Adsorption 6, edited by F. Meunier, Elsevier, Paris (1998)
[64] A selfconsistent OrnsteinZernike approximation for the random field Ising model, E. Kierlik, M.L. Rosinberg and G. Tarjus, J. Stat. Phys. 94, 805 (1999).
[65] Liquidstate methods for disordered systems, M.L. Rosinberg, in New approaches to problems in liquid state theory, edited by C. Caccamo, J. P. Hansen and G. Stell, NATOASI series C, vol. 529, Kluwer (1999).
[66] A selfconsistent OrnsteinZernike approximation for the EdwardsAnderson spin glass model, E. Kierlik, M.L. Rosinberg and G. Tarjus, J. Stat. Phys. 100, 423 (2000).
[67] A thermodynamically selfconsistent theory for the BlumeCapel model, S. Grollau, E. Kierlik, M.L. Rosinberg and G. Tarjus, Phys. Rev. E 63, 041111 (2001).
[68] Equilibrium and outofequilibrium (hysteretic) behavior of fluids in disordered porous materials: theoretical predictions, E. Kierlik, M.L. Rosinberg, G. Tarjus, and P. Viot, Physical Chemistry Chemical Physics, 3, 1201 (2001).
[69] The ferromagnetic qstate Potts model on threedimensional lattices: a study for real values of q, S. Grollau, M.L. Rosinberg and G. Tarjus, Physica A 296, 460 (2001).
[70] Capillary condensation in disordered porous materials: hysteresis versus equilibrium behavior, E. Kierlik, P.A. Monson, M.L. Rosinberg, S. Sarkisov and G. Tarjus, Phys. Rev. Lett. 87, 055701 (2001).
[71] Adsorption of a fluid in an aerogel: integral equation approach, V. Krakoviack, E. Kierlik, M.L. Rosinberg, and G. Tarjus, J. Chem. Phys. 115, 11289 (2001).
[72] Lattice models of fluids confined in disordered porous media, E. Kierlik, P.A. Monson, M.L. Rosinberg, S. Sarkisov and G. Tarjus, in Fundamentals of Adsorption 7, edited by K. Kaneko, H. Kanoh, and Y. Hanzawa, IK International, (2002).
[73] Adsorption hysteresis and capillary condensation in disordered porous solids, E. Kierlik, P. A. Monson, M.L. Rosinberg, and G. Tarjus, J. Phys.: Condens. Matter. 14, 9295 (2002)
[74] Percolation, depinning, and avalanches in capillary condensation of gases in disordered porous solids, M.L. Rosinberg, E. Kierlik, and G. Tarjus, Europhys. Lett. 62 , 377 (2003).
[75] Local meanfield study of capillary condensation in silica aerogels, F. Detcheverry, E. Kierlik, M.L. Rosinberg, and G. Tarjus, Phys. Rev. E 68 , 061504 (2003).
[76] Hysteresis in capillary condensation of gases in disordered porous solids, F. Detcheverry, E. Kierlik, M.L. Rosinberg, and G. Tarjus, Physica B 343, 303 (2004).
[77] Mechanisms for gas adsorption and desorption in silica aerogels: the effect of temperature, F. Detcheverry, E. Kierlik, M.L. Rosinberg, and G. Tarjus, Langmuir 20, 8006 (2004).
[78] The physics of capillary condensation in disordered mesoporous materials: a unifying theoretical description, F. Detcheverry, E. Kierlik, M.L. Rosinberg, and G. Tarjus, Adsorption 11, 115 (2005).
[79] Hysteresis and avalanches in the T=0 randomfield Ising model with 2spinflip dynamics, E. Vives, M.L. Rosinberg, and G. Tarjus, Phys. Rev. B 71, 134424 (2005).
[80] Metastable states and T=0 hysteresis in the randomfield Ising model on random graphs, F. Detcheverry, M.L. Rosinberg, and G. Tarjus, Eur. Phys. J. B 44, 327 (2005).
[81] Helium condensation in aerogel: avalanches and disorderinduced phase transition, F. Detcheverry, E. Kierlik, M.L. Rosinberg, and G. Tarjus, Phys. Rev. E 72, 051506 (2005).
[82] Gas adsorption/desorption in silica aerogels: a theoretical study of scattering properties, F. Detcheverry, E. Kierlik, M.L. Rosinberg, and G. Tarjus, Phys. Rev. E 73, 041511 (2006).
[83] Influence of the driving mechanism on the response of systems with athermal dynamics: the exemple of the randomfield Ising model, X. Illa, M.L. Rosinberg, and E. Vives, Phys. Rev. B 74, 224403 (2006).
[84] The magnetizationdriven randomfield Ising model at T=0, X. Illa, M.L. Rosinberg, P. Shukla and E. Vives, Phys. Rev. B 74, 224404 (2006).
[85] Hysteresis behavior of the randomfield Ising model with 2spinflip dynamics: Exact results on a Bethe Lattice, X. Illa, M.L. Rosinberg, and G. Tarjus, Eur. Phys. J. B 54, 355 (2006).
[86] Numerical study of metastable states in the T=0 RFIM, F.J. PerezReche, M.L. Rosinberg, and G. Tarjus , Phys. Rev. B 77, 064422 (2008).
[87] Stable, metastable and unstable states in the meanfield RFIM at T=0, M.L. Rosinberg, G. Tarjus, and F. J. PerezReche, J. Stat. Mech. P10004 (2008).
[88] The T=0 randomfield Ising model on a Bethe lattice with large coordination number: hysteresis and metastable states, M.L. Rosinberg, G. Tarjus, and F.J. PerezReche, J. Stat. Mech. P03003 (2009).
[89] Hysteresis and complexity in the zerotemperature meanfield RFIM: the softspin version, M.L. Rosinberg and T. Munakata, Phys. Rev. B 79, 174207 (2009)..
[90] Hysteresis in the T=0 RFIM: beyond metastable dynamics, F. SalvatPujol, E. Vives, and M.L. Rosinberg, Phys. Rev. E 79, 061116 (2009).
[91] A statistical mechanical description of metastable states and hysteresis in the 3D softspin randomfield model at T=0, M.L. Rosinberg and G. Tarjus, J. Stat. Mech P12011 (2010).
[92] Stochastic dynamics of N bistable elements with global timedelayed interactions: towards an exact solution of the master equations for finite N, M. Kimizuka, T. Munakata, and M. L. Rosinberg, Phys. Rev. E 82, 041129 (2010).
[93] Recent topics in hysteresis and avalanches, M. L. Rosinberg and E. Vives, in Disorder and Straininduced Complexity in Functional Materials, Eds. T. Kakeshita, T. Fukuda, A. Saxena, and A. Planes (Springer Series in Materials Science, Vol. 148, 2011).
[94] Spontaneous imbibition in a slit pore: a latticegas dynamic meanfield study, E. Kierlik, F. Leoni, M. L Rosinberg, and G. Tarjus, Mol. Phys. 109, 1143 (2011).
[95] Spontaneous imbibition in disordered porous solids: a theoretical study of helium in silica aerogels, F. Leoni, E. Kierlik, M. L. Rosinberg, and G. Tarjus, Langmuir 27, 8160 (2011).
[96] The T=0 RFIM on a Bethe lattice: correlation functions along the hysteresis loop, X. Illa and M. L. Rosinberg, Phys. Rev. B 84, 064443 (2011).
[97] Hierachical Reference Theory of critical fluids in disordered porous media, G. Tarjus, M. L. Rosinberg, E. Kierlik, and M. Tissier, Mol. Phys. 109, 2863 (2011).
[98] Entropy production and fluctuation theorems under feedback control: the molecular refrigerator model revisited, T. Munakata and M.L. Rosinberg, J. Stat. Mech. P05010 (2012).
[99] Morphology transitions at depinning in a solvable model of interface growth in a random medium, H. Ohta, M.L. Rosinberg, and G. Tarjus, Euro. Phys. Lett. 104, 16003 (2013)
[100] Feedback cooling, measurement errors, and entropy production, T. Munakata and M.L. Rosinberg, J. Stat. Mech. P06014 (2013).
[101] Entropy production and fluctuation theorems for Langevin processes under continuous nonMarkovian feeddback control, T. Munakata and M.L. Rosinberg, Phys. Rev. Lett. 112, 180601 (2014)
[102] Stochastic thermodynamics of Langevin systems under timedelayed feedback control: 1. Secondlawlike inequalities, M.L. Rosinberg, T. Munakata, and G. Tarjus, Phys. Rev. E 91, 042114 (2015).
[103] Heat fluctuations for underdamped Langevin dynamics, M.L. Rosinberg, G. Tarjus, and T. Munakata, Euro. Phys. Lett. 113, 10007 (2016).
[104] Continuous information flow fluctuations, M.L. Rosinberg and J. Horowitz, Euro. Phys. Lett. 116, 10007 (2016).
[105] Stochastic thermodynamics of Langevin systems under timedelayed feedback control: 2. Nonequilibrium steadystate fluctuations, M.L. Rosinberg, T. Munakata, and G. Tarjus, Phys. Rev. E 95, 022123 (2017).
[106] Informationtheoretic analysis of the directional influence between cellular processes, S. Lahiri, P. Nghe, S. J. Tans, M. L. Rosinberg, and D. Lacoste, PLoS ONE 12(11): e0187431 (2017).
[107] Influence of time delay on information exchanges between coupled linear stochastic systems, M. L. Rosinberg, G. Tarjus, and T. Munakata, Phys. Rev. E 98, 032130 (2018).