Your search keyword '"Giulia Pisegna"' showing total 6 results

1. Marginal speed confinement resolves the conflict between correlation and control in collective behaviour

Author

Andrea Cavagna, Antonio Culla, Xiao Feng, Irene Giardina, Tomas S. Grigera, Willow Kion-Crosby, Stefania Melillo, Giulia Pisegna, Lorena Postiglione, and Pablo Villegas

Subjects

Science

Abstract

Bird flocks are known to adjust the orientation and speed of individual birds giving rise to correlations that extend across very large groups. The authors show that marginal control provides an explanation of scale-free correlations of speed fluctuations in natural bird flocks of any sizes.

Published

2022

2. Equilibrium to off-equilibrium crossover in homogeneous active matter

Author

Andrea Cavagna, Luca Di Carlo, Irene Giardina, Tomás S. Grigera, and Giulia Pisegna

Subjects

Physics, QC1-999

Abstract

We study the crossover between equilibrium and off-equilibrium dynamical universality classes in the Vicsek model near its ordering transition. Starting from the incompressible hydrodynamic theory of Chen et al. [Critical phenomenon of the order-disorder transition in incompressible active fluids, New J. Phys. 17, 042002 (2015)NJOPFM1367-263010.1088/1367-2630/17/4/042002], we show that increasing the activity leads to a renormalization group (RG) crossover between the equilibrium ferromagnetic fixed point, with dynamical critical exponent z=2, and the off-equilibrium active fixed point, with z=1.7 (in d=3). We run simulations of the classic Vicsek model in the near-ordering regime and find that critical slowing down indeed changes with activity, displaying two exponents that are in remarkable agreement with the RG prediction. The equilibrium to off-equilibrium crossover is ruled by a characteristic length scale, beyond which active dynamics takes over. The larger the activity is, the smaller is such a length scale, suggesting the existence of a general trade-off between activity and the system's size in determining the dynamical universality class of active matter.

Published

2021

3. Proton Radiography by Multiple Coulomb Scattering with Nuclear Emulsion Detectors

Author

Saverio Braccini, Tommaso S. Carzaniga, Giulia Pisegna, and Paola Scampoli

Subjects

proton radiography, nuclear emulsion, instrumentation for hadron therapy, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

The possibility of performing proton radiography by using the proton angular spread due to Coulomb multiple scattering was investigated, for the first time, with an emulsion film detector. Two different phantoms were irradiated with the therapeutic proton beam at the Paul Scherrer Institut (PSI) in Villigen, Switzerland. The first one is a simple polymethylmethacrylate (PMMA) block having two different thicknesses (4 cm and 3 cm), and the second one is a PMMA cube with five aluminum rods embedded along a diagonal. Only one emulsion film was needed to perform the radiography, an important issue as the analysis of this kind of detector is time-consuming. Furthermore, the method showed an enhanced contrast when high atomic-number materials are traversed. This gives an advantage, when compared to proton range radiography.

Published

2019

4. Dynamical renormalization group for mode-coupling field theories with solenoidal constraint

Author

Giulia Pisegna, Tomás S. Grigera, Mattia Scandolo, Irene Giardina, Luca Di Carlo, and Andrea Cavagna

Subjects

Primary field, Field (physics), FOS: Physical sciences, 01 natural sciences, Article, 010305 fluids & plasmas, Dynamic renormalization group, Mode-coupling, Solenoidal field, Collective behaviour, 0103 physical sciences, Field theory (psychology), 010306 general physics, Condensed Matter - Statistical Mechanics, Mathematical Physics, Coupling constant, Physics, Solenoidal vector field, Statistical Mechanics (cond-mat.stat-mech), Física, Statistical and Nonlinear Physics, Renormalization group, Universality (dynamical systems), Constraint (information theory), Classical mechanics, Physics - Statistical Mechanics

Abstract

The recent inflow of empirical data about the collective behaviour of strongly correlated biological systems has brought field theory and the renormalization group into the biophysical arena. Experiments on bird flocks and insect swarms show that social forces act on the particles' velocity through the generator of its rotations, namely the spin, indicating that mode-coupling field theories are necessary to reproduce the correct dynamical behaviour. Unfortunately, a theory for three coupled fields - density, velocity and spin - has a prohibitive degree of intricacy. A simplifying path consists in getting rid of density fluctuations by studying incompressible systems. This requires imposing a solenoidal constraint on the primary field, an unsolved problem even for equilibrium mode-coupling theories. Here, we perform an equilibrium dynamic renormalization group analysis of a mode-coupling field theory subject to a solenoidal constraint; using the classification of Halperin and Hohenberg, we can dub this case as a solenoidal Model G. We demonstrate that the constraint produces a new vertex that mixes static and dynamical coupling constants, and that this vertex is essential to grant the closure of the renormalization group structure and the consistency of dynamics with statics. Interestingly, although the solenoidal constraint leads to a modification of the static universality class, we find that it does not change the dynamical universality class, a result that seems to represent an exception to the general rule that dynamical universality classes are narrower than static ones. Our results constitute a solid stepping stone in the admittedly large chasm towards developing an off-equilibrium mode-coupling theory of biological groups., Instituto de Física de Líquidos y Sistemas Biológicos

Published

2021

5. Renormalization group crossover in the critical dynamics of field theories with mode coupling terms

Author

Luca Grandinetti, Andrea Cavagna, Luca Di Carlo, Giulia Pisegna, Tomás S. Grigera, and Irene Giardina

Subjects

Field (physics), Biología, Crossover, FOS: Physical sciences, Bose-Einstein condensation, 01 natural sciences, Quantitative Biology - Quantitative Methods, 010305 fluids & plasmas, purl.org/becyt/ford/1 [https], collective behavior, Equations of motion, 0103 physical sciences, Physics - Biological Physics, dynamics of field theories, 010306 general physics, Quantitative Methods (q-bio.QM), Condensed Matter - Statistical Mechanics, Ciencias Exactas, Mathematical physics, Physics, Statistical Mechanics (cond-mat.stat-mech), Dynamical renormalization group, mode coupling theory, crossover, Física, purl.org/becyt/ford/1.3 [https], dissipation, Renormalization group, swarming, Dynamics, Biological Physics (physics.bio-ph), FOS: Biological sciences, Mode coupling, biological swarms, renormalization group, Statistical mechanics

Abstract

Motivated by the collective behavior of biological swarms, we study the critical dynamics of field theories with coupling between order parameter and conjugate momentum in the presence of dissipation. Under a fixed-network approximation, we perform a dynamical renormalization group calculation at one loop in the near-critical disordered region, and we show that the violation of momentum conservation generates a crossover between an unstable fixed point, characterized by a dynamic critical exponent z = d/2, and a stable fixed point with z = 2. Interestingly, the two fixed points have different upper critical dimensions. The interplay between these two fixed points gives rise to a crossover in the critical dynamics of the system, characterized by a crossover exponent κ = 4/d. The crossover is regulated by a conservation length scale R0, given by the ratio between the transport coefficient and the effective friction, which is larger as the dissipation is smaller: Beyond R0, the stable fixed point dominates, while at shorter distances dynamics is ruled by the unstable fixed point and critical exponent, a behavior which is all the more relevant in finite-size systems with weak dissipation. We run numerical simulations in three dimensions and find a crossover between the exponents z = 3/2 and z = 2 in the critical slowdown of the system, confirming the renormalization group results. From the biophysical point of view, our calculation indicates that in finite-size biological groups mode coupling terms in the equation of motion can significantly change the dynamical critical exponents even in the presence of dissipation, a step toward reconciling theory with experiments in natural swarms. Moreover, our result provides the scale within which fully conservative Bose-Einstein condensation is a good approximation in systems with weak symmetry-breaking terms violating number conservation, as quantum magnets or photon gases., Instituto de Física de Líquidos y Sistemas Biológicos

Published

2019

6. Dynamical renormalization group approach to the collective behaviour of swarms

Author

Tomás S. Grigera, Irene Giardina, Luca Grandinetti, Luca Di Carlo, Giulia Pisegna, and Andrea Cavagna

Subjects

Length scale, Collective behavior, Dissipative model, Transport coefficient, Biología, Crossover, General Physics and Astronomy, Collective dynamics, FOS: Physical sciences, Fixed point, 01 natural sciences, Quantitative Biology - Quantitative Methods, purl.org/becyt/ford/1 [https], 0103 physical sciences, quantitative methods, Swarming. active matter, biological physics, Physics - Biological Physics, 010306 general physics, Condensed Matter - Statistical Mechanics, Quantitative Methods (q-bio.QM), Mathematical physics, Physics, Statistical Mechanics (cond-mat.stat-mech), Física, Bose-Einstein condensates, quantitative biology, purl.org/becyt/ford/1.3 [https], Renormalization group, Critical behavior, Biological Physics (physics.bio-ph), statistical mechanics, physics, FOS: Biological sciences, Dissipative system, Couplings, renormalization group, active matter, Critical exponent

Abstract

We study the critical behavior of a model with nondissipative couplings aimed at describing the collective behavior of natural swarms, using the dynamical renormalization group under a fixed-network approximation. At one loop, we find a crossover between an unstable fixed point, characterized by a dynamical critical exponent z ¼ d=2, and a stable fixed point with z ¼ 2, a result we confirm through numerical simulations. The crossover is regulated by a length scale given by the ratio between the transport coefficient and the effective friction, so that in finite-size biological systems with low dissipation, dynamics is ruled by the unstable fixed point. In three dimensions this mechanism gives z ¼ 3=2, a value significantly closer to the experimental window, 1.0 ≤ z ≤ 1.3, than the value z ≈ 2 numerically found in fully dissipative models, either at or off equilibrium. This result indicates that nondissipative dynamical couplings are necessary to develop a theory of natural swarms fully consistent with experiments., Instituto de Física de Líquidos y Sistemas Biológicos

Published

2019