Your search keyword '"Baity-Jesi M"' showing total 7 results

1. Temperature chaos is present in off-equilibrium spin-glass dynamics

Author

Janus Collaboration, Baity-Jesi, M., Calore, E., Cruz, A., Fernandez, L. A., Gil-Narvion, J. M., Pemartin, I. Gonzalez-Adalid, Gordillo-Guerrero, A., I��iguez, D., Maiorano, A., Marinari, E., Martin-Mayor, V., Moreno-Gordo, J., Mu��oz-Sudupe, A., Navarro, D., Paga, I., Parisi, G., Perez-Gaviro, S., Ricci-Tersenghi, F., Ruiz-Lorenzo, J. J., Schifano, S. F., Seoane, B., Tarancon, A., Tripiccione, R., and Yllanes, D.

Subjects

Spin glass, Thermodynamic equilibrium, QC1-999, Chaos theory, Dynamics, Glass, Spin glass, Supercomputers, Chaotic, FOS: Physical sciences, General Physics and Astronomy, Non-equilibrium thermodynamics, out of equilibrium dynamics, Astrophysics, 01 natural sciences, NO, 010305 fluids & plasmas, PE3_15, Fragility, chaos in temperature, Phase (matter), 0103 physical sciences, Janus, Statistical physics, 010306 general physics, Physics, spin glass models, Física, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Supercomputers, Chaos theory, Dynamics, Coherence length, Condensed Matter::Soft Condensed Matter, Nonlinear Sciences::Chaotic Dynamics, QB460-466, Glass

Abstract

We find a dynamic effect in the non-equilibrium dynamics of a spin glass that closely parallels equilibrium temperature chaos. This effect, that we name dynamic temperature chaos, is spatially heterogeneous to a large degree. The key controlling quantity is the time-growing spin-glass coherence length. Our detailed characterization of dynamic temperature chaos paves the way for the analysis of recent and forthcoming experiments. This work has been made possible thanks to the most massive simulation to date of non-equilibrium dynamics, carried out on the Janus~II custom-built supercomputer., Comment: Version accepted for publication in Communication Physics 10 pages, 9 figures

Published

2021

2. Aging Rate of Spin Glasses from Simulations Matches Experiments

Author

Janus Collaboration, Baity-Jesi, M., Calore, E., Cruz, A., Fernandez, L. A., Gil-Narvion, J. M., Gordillo-Guerrero, A., Iñiguez, D., Maiorano, A., Marinari, E., Martin-Mayor, V., Moreno-Gordo, J., Muñoz-Sudupe, A., Navarro, D., Parisi, G., Perez-Gaviro, S., Ricci-Tersenghi, F., Ruiz-Lorenzo, J. J., Schifano, S. F., Seoane, B., Tarancon, A., Tripiccione, R., and Yllanes, D.

Subjects

spin glasses, numerical simulations, disordered systems, Física-Modelos matemáticos, Spin glass, glass models, Crossover, FOS: Physical sciences, General Physics and Astronomy, Fixed point, spin glass, 01 natural sciences, 010305 fluids & plasmas, NO, 0103 physical sciences, Ising model, Janus, 010306 general physics, Condensed Matter - Statistical Mechanics, Physics, spin glass, Ising model, glass models, Statistical Mechanics (cond-mat.stat-mech), Condensed matter physics, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Exponent, Value (mathematics)

Abstract

Experiments on spin glasses can now make precise measurements of the exponent $z(T)$ governing the growth of glassy domains, while our computational capabilities allow us to make quantitative predictions for experimental scales. However, experimental and numerical values for $z(T)$ have differed. We use new simulations on the Janus II computer to resolve this discrepancy, finding a time-dependent $z(T, t_w)$, which leads to the experimental value through mild extrapolations. Furthermore, theoretical insight is gained by studying a crossover between the $T = T_c$ and $T = 0$ fixed points., Version accepted for publication in PRL. 12 pages, 9 figures

Published

2018

3. A statics-dynamics equivalence through the fluctuation-dissipation ratio provides a window into the spin-glass phase from nonequilibrium measurements

Author

Janus Collaboration, Baity-Jesi, M., Calore, E., Cruz, A., Fernandez, L. A., Gil-Narvion, J. M., Gordillo-Guerrero, A., I��iguez, D., Maiorano, A., Marinari, E., Martin-Mayor, V., Monforte-Garcia, J., Mu��oz-Sudupe, A., Navarro, D., Parisi, G., Perez-Gaviro, S., Ricci-Tersenghi, F., Ruiz-Lorenzo, J. J., Schifano, S. F., Seoane, B., Tarancon, A., Tripiccione, R., and Yllanes, D.

Subjects

spin glasses, Spin glass, Física-Modelos matemáticos, Computation, Non-equilibrium thermodynamics, FOS: Physical sciences, 01 natural sciences, glasses, Condensed Matter::Disordered Systems and Neural Networks, 010305 fluids & plasmas, NO, 0103 physical sciences, Statistical physics, Janus, 010306 general physics, Statics, Equivalence (measure theory), Condensed Matter - Statistical Mechanics, Mathematics, Multidisciplinary, Statistical Mechanics (cond-mat.stat-mech), Física, Disordered Systems and Neural Networks (cond-mat.dis-nn), Dissipation, Condensed Matter - Disordered Systems and Neural Networks, fluctuation-dissipation relation, statics-dynamics equivalence, out-of-equilibrium dynamics, Condensed Matter::Soft Condensed Matter, Physical Sciences, Probability distribution, Fluctuation-dissipation relation, Glasses, Out-of-equilibrium dynamics, Spin glasses, Statics-dynamics equivalence

Abstract

The unifying feature of glass formers (such as polymers, supercooled liquids, colloids, granulars, spin glasses, superconductors, ...) is a sluggish dynamics at low temperatures. Indeed, their dynamics is so slow that thermal equilibrium is never reached in macroscopic samples: in analogy with living beings, glasses are said to age. Here, we show how to relate experimentally relevant quantities with the experimentally unreachable low-temperature equilibrium phase. We have performed a very accurate computation of the non-equilibrium fluctuation-dissipation ratio for the three-dimensional Edwards-Anderson Ising spin glass, by means of large-scale simulations on the special-purpose computers Janus and Janus II. This ratio (computed for finite times on very large, effectively infinite, systems) is compared with the equilibrium probability distribution of the spin overlap for finite sizes. The resulting quantitative statics-dynamics dictionary, based on observables that can be measured with current experimental methods, could allow the experimental exploration of important features of the spin-glass phase without uncontrollable extrapolations to infinite times or system sizes., Comment: Version accepted for publication in PNAS. Reuploaded to fix a typo in the list of authors

Published

2017

4. Dynamical transition in the D=3 Edwards-Anderson spin glass in an external magnetic field

Author

Janus Collaboration, Baity-Jesi, M., Ba��os, R. Alvarez, Cruz, A., Fernandez, L. A., Gil-Narvion, J. M., Gordillo-Guerrero, I��iguez, D., Maiorano, A., Mantovani, F., Marinari, E., Martin-Mayor, V., Monforte-Garcia, J., Sudupe, A. Mu��oz, Navarro, D., Parisi, G., Perez-Gaviro, S., Pivanti, M., Ricci-Tersenghi, F., Ruiz-Lorenzo, J. J., Schifano, S. F., Seoane, B., Tarancon, A., Tripiccione, R., and Yllanes, D.

Subjects

Physics, Spin glass, Física-Modelos matemáticos, Condensed matter physics, Annealing (metallurgy), Crossover, FOS: Physical sciences, Física, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, 01 natural sciences, 010305 fluids & plasmas, Magnetic field, NO, Transition point, 0103 physical sciences, Ising spin, Janus, 010306 general physics, Spin Glass

Abstract

We study the off-equilibrium dynamics of the three-dimensional Ising spin glass in the presence of an external magnetic field. We have performed simulations both at fixed temperature and with an annealing protocol. Thanks to the Janus special-purpose computer, based on FPGAs, we have been able to reach times equivalent to 0.01 seconds in experiments. We have studied the system relaxation both for high and for low temperatures, clearly identifying a dynamical transition point. This dynamical temperature is strictly positive and depends on the external applied magnetic field. We discuss different possibilities for the underlying physics, which include a thermodynamical spin-glass transition, a mode-coupling crossover or an interpretation reminiscent of the random first-order picture of structural glasses., Comment: Version accepted in PRE. 23 pages, 23 figures

Published

2014

5. The three-dimensional Ising spin glass in an external magnetic field: The role of the silent majority

Author

Janus Collaboration, Baity-Jesi, M., Banos, R. A., Cruz, A., Fernandez, L. A., Gil-Narvion, J. M., Gordillo-Guerrero, A., Iniguez, D., Maiorano, A., Mantovani, F., Marinari, E., Martin-Mayor, V., Monforte-Garcia, J., Sudupe, A. Munoz, Navarro, D., Parisi, G., Perez-Gaviro, S., Pivanti, M., Ricci-Tersenghi, F., Ruiz-Lorenzo, J. J., Schifano, S. F., Seoane, B., Tarancon, A., Tripiccione, R., and Yllanes, D.

Subjects

Statistics and Probability, Phase transition, Spin glass, Física-Modelos matemáticos, disordered systems (theory), FOS: Physical sciences, Probability density function, spin glasses (theory), 01 natural sciences, NO, 010305 fluids & plasmas, 0103 physical sciences, Statistical physics, 010306 general physics, Spin Glass, Scaling, Physics, simulazioni Monte Carlo, Física, Statistical and Nonlinear Physics, Disordered Systems and Neural Networks (cond-mat.dis-nn), Scale invariance, Condensed Matter - Disordered Systems and Neural Networks, Random variate, Thermodynamic limit, Ising model, Statistics, Probability and Uncertainty

Abstract

We perform equilibrium parallel-tempering simulations of the 3D Ising Edwards-Anderson spin glass in a field. A traditional analysis shows no signs of a phase transition. Yet, we encounter dramatic fluctuations in the behaviour of the model: Averages over all the data only describe the behaviour of a small fraction of it. Therefore we develop a new approach to study the equilibrium behaviour of the system, by classifying the measurements as a function of a conditioning variate. We propose a finite-size scaling analysis based on the probability distribution function of the conditioning variate, which may accelerate the convergence to the thermodynamic limit. In this way, we find a non-trivial spectrum of behaviours, where a part of the measurements behaves as the average, while the majority of them shows signs of scale invariance. As a result, we can estimate the temperature interval where the phase transition in a field ought to lie, if it exists. Although this would-be critical regime is unreachable with present resources, the numerical challenge is finally well posed., 42 pages, 19 figures. Minor changes and added figure (results unchanged)

Published

2014

6. Critical parameters of the three-dimensional Ising spin glass

Author

Janus Collaboration, Baity-Jesi, M., Baños, R. A., Cruz, A., Fernandez, L. A., Gil-Narvion, J. M., Gordillo-Guerrero, A., Iñiguez, D., Maiorano, A., Mantovani, F., Marinari, E., Martin-Mayor, V., Monforte-Garcia, J., Sudupe, A. Muñoz, Navarro, D., Parisi, G., Perez-Gaviro, S., Pivanti, M., Ricci-Tersenghi, F., Ruiz-Lorenzo, J. J., Schifano, S. F., Seoane, B., Tarancon, A., Tripiccione, R., and Yllanes, D.

Subjects

Física-Modelos matemáticos, Yield (engineering), FOS: Physical sciences, 01 natural sciences, NO, 010305 fluids & plasmas, Dimension (vector space), 0103 physical sciences, Thermal, Ising spin, Janus, 010306 general physics, Scaling, Physics, Condensed matter physics, Monte Carlo Simulation, Física, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Exponent, Ising model, Ising Spin Glass

Abstract

We report a high-precision finite-size scaling study of the critical behavior of the three-dimensional Ising Edwards-Anderson model (the Ising spin glass). We have thermalized lattices up to L=40 using the Janus dedicated computer. Our analysis takes into account leading-order corrections to scaling. We obtain Tc = 1.1019(29) for the critical temperature, \nu = 2.562(42) for the thermal exponent, \eta = -0.3900(36) for the anomalous dimension and \omega = 1.12(10) for the exponent of the leading corrections to scaling. Standard (hyper)scaling relations yield \alpha = -5.69(13), \beta = 0.782(10) and \gamma = 6.13(11). We also compute several universal quantities at Tc., Comment: 9 pages, 5 figures

Published

2013

7. Reconfigurable computing for Monte Carlo simulations: Results and prospects of the Janus project

Author

Janus Collaboration, Baity-Jesi, M., Banos, R. A., Cruz, A., Fernandez, L. A., Gil-Narvion, J. M., Gordillo-Guerrero, A., Guidetti, M., Iniguez, D., Maiorano, A., Mantovani, F., Marinari, E., Martin-Mayor, V., Monforte-Garcia, J., Sudupe, A. Munoz, Navarro, D., Parisi, G., Pivanti, M., Perez-Gaviro, S., Ricci-Tersenghi, F., Ruiz-Lorenzo, J. J., Schifano, S. F., Seoane, B., Tarancon, A., Tellez, P., Tripiccione, R., and Yllanes, D.

Subjects

FOS: Computer and information sciences, FPGA, HPC, Monte Carlo, Spin Glass, Física-Modelos matemáticos, Monte Carlo method, FOS: Physical sciences, General Physics and Astronomy, Binary number, 01 natural sciences, 010305 fluids & plasmas, Computational science, Computer Science::Hardware Architecture, Hardware Architecture (cs.AR), 0103 physical sciences, General Materials Science, Janus, Physical and Theoretical Chemistry, 010306 general physics, Computer Science - Hardware Architecture, Massively parallel, Scaling, Ansatz, Physics, Física, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Reconfigurable computing, Parallel tempering

Abstract

We describe Janus, a massively parallel FPGA-based computer optimized for the simulation of spin glasses, theoretical models for the behavior of glassy materials. FPGAs (as compared to GPUs or many-core processors) provide a complementary approach to massively parallel computing. In particular, our model problem is formulated in terms of binary variables, and floating-point operations can be (almost) completely avoided. The FPGA architecture allows us to run many independent threads with almost no latencies in memory access, thus updating up to 1024 spins per cycle. We describe Janus in detail and we summarize the physics results obtained in four years of operation of this machine; we discuss two types of physics applications: long simulations on very large systems (which try to mimic and provide understanding about the experimental non-equilibrium dynamics), and low-temperature equilibrium simulations using an artificial parallel tempering dynamics. The time scale of our non-equilibrium simulations spans eleven orders of magnitude (from picoseconds to a tenth of a second). On the other hand, our equilibrium simulations are unprecedented both because of the low temperatures reached and for the large systems that we have brought to equilibrium. A finite-time scaling ansatz emerges from the detailed comparison of the two sets of simulations. Janus has made it possible to perform spin-glass simulations that would take several decades on more conventional architectures. The paper ends with an assessment of the potential of possible future versions of the Janus architecture, based on state-of-the-art technology., 19 pages, 3 figures

Published

2012