Your search keyword '"Succi S"' showing total 1,228 results

1. From non-equilibrium Green functions to Lattice Wigner: A toy model for quantum nanofluidics simulations

Author

Succi, S., Lauricella, M., and Tiribocchi, A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

Recent experiments of fluid transport in nano-channels have shown evidence of a dramatic reduction of friction due to the coupling between charge-fluctuations in polar fluids and electronic excitations in graphene solids, a phenomenon dubbed "negative quantum friction". In this paper, we present a semi-classical mesoscale Boltzmann-Wigner lattice kinetic model of quantum-nanoscale transport and perform a numerical study of the effects of the quantum interactions on the evolution of a one-dimensional nano-fluid subject to a periodic external potential. It is shown that the effects of quantum fluctuations become visible once the quantum length scale (Fermi wavelength) of the quasiparticles becomes comparable to the wavelength of the external potential. Under such conditions, quantum fluctuations are mostly felt on the odd kinetic moments, while the even ones remain nearly unaffected because they are "protected" by thermal fluctuations. It is hoped that the present Boltzmann-Wigner lattice model and extensions thereof may offer a useful tool for the computer simulation of quantum-nanofluidic transport phenomena., Comment: 9 pages, 6 figures

Published

2025

2. Lattice Boltzmann simulations for soft flowing matter

Author

Tiribocchi, A., Durve, M., Lauricella, M., Montessori, A., Tucny, J. M., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

Over the last decade, the Lattice Boltzmann method has found major scope for the simulation of a large spectrum of problems in soft matter, from multiphase and multi-component microfluidic flows, to foams, emulsions, colloidal flows, to name but a few. Crucial to many such applications is the role of supramolecular interactions which occur whenever mesoscale structures, such as bubbles or droplets, come in close contact, say of the order of tens of nanometers. Regardless of their specific physico-chemical origin, such near-contact interactions are vital to preserve the coherence of the mesoscale structures against coalescence phenomena promoted by capillarity and surface tension, hence the need of including them in Lattice Boltzmann schemes. Strictly speaking, this entails a complex multiscale problem, covering about six spatial decades, from centimeters down to tens of nanometers, and almost twice as many in time. Such a multiscale problem can hardly be taken by a single computational method, hence the need for coarse-grained models for the near-contact interactions. In this review, we shall discuss such coarse-grained models and illustrate their application to a variety of soft flowing matter problems, such as soft flowing crystals, strongly confined dense emulsions, flowing hierarchical emulsions, soft granular flows, as well as the transmigration of active droplets across constrictions. Finally, we conclude with a few considerations on future developments in the direction of quantum-nanofluidics, machine learning, and quantum computing for soft flows applications., Comment: 51 pages, 268 figures

Published

2024

3. Extrinsic and intrinsic effects setting viscosity in complex fluids and life processes: the role of fundamental physical constants

Author

Trachenko, K., Tello, P. G., Kauffman, S. A., and Succi, S.

Published

2025

4. Quantum wave representation of dissipative fluids

Author

Salasnich, L., Succi, S., and Tiribocchi, A.

Subjects

Physics - Fluid Dynamics, Quantum Physics

Abstract

We present a mapping between a Schr\"odinger equation with a shifted non-linear potential and the Navier-Stokes equation. Following a generalization of the Madelung transformations, we show that the inclusion of the Bohm quantum potential plus the laplacian of the phase field in the non-linear term leads to continuity and momentum equations for a dissipative incompressible Navier-Stokes fluid. An alternative solution, built using a complex quantum diffusion, is also discussed. The present models may capture dissipative effects in quantum fluids, such as Bose-Einstein condensates, as well as facilitate the formulation of quantum algorithms for classical dissipative fluids., Comment: 5 pages, 1 figure. Version accepted on International Journal of Modern Physics C

Published

2023

5. Spontaneous motion of a passive fluid droplet in an active microchannel

Author

Tiribocchi, A., Durve, M., Lauricella, M., Montessori, A., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

We numerically study the dynamics of a passive fluid droplet confined within a microchannel whose walls are covered with a thin layer of active gel. The latter represents a fluid of extensile material modelling, for example, a suspension of cytoskeletal filaments and molecular motors. Our results show that the layer is capable of producing a spontaneous flow triggering a rectilinear motion of the passive droplet. For a hybrid design (a single wall covered by the active layer), at the steady state the droplet attains an elliptical shape, resulting from an asymmetric saw-toothed structure of the velocity field. On the contrary, if the active gel covers both walls, the velocity field exhibits a fully symmetric pattern considerably mitigating morphological deformations. We further show that the structure of the spontaneous flow in the microchannel can be controlled by the anchoring conditions of the active gel at the wall. These findings are also confirmed by selected 3D simulations. Our results may stimulate further research addressed to design novel microfludic devices whose functioning relies on the collective properties of active gels., Comment: Accepted on Soft Matter

Published

2023

6. Direct Simulation of Fluid Transport at Solid Interfaces with a Multiscale Lattice-Boltzmann Finite-Volume Method

Author

Rotondi R., Succi S., and Bella G.

Subjects

hydrodynamics, transport phenomena, lattice boltzmann, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

It is shown that the combined use of a mesoscopic lattice Boltzmann solver with finite-volume techniques, both enriched with local-refinement (multiscale) capabilities, permits to describe transport phenomena at fluid-solid interfaces to a degree of detail which may help dispensing with empirical correlations.

Published

2004

7. The crucial role of adhesion in the transmigration of active droplets through interstitial orifices

Author

Tiribocchi, A., Durve, M., Lauricella, M., Montessori, A., Marenduzzo, D., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

Active fluid droplets are a class of soft materials exhibiting autonomous motion sustained by an energy supply. Such systems have been shown to capture motility regimes typical of biological cells and are ideal candidates as building-block for the fabrication of soft biomimetic materials of interest in pharmacology, tissue engineering and lab on chip devices. While their behavior is well established in unconstrained environments, much less is known about their dynamics under strong confinement. Here, we numerically study the physics of a droplet of active polar fluid migrating within a microchannel hosting a constriction with adhesive properties, and report evidence of a striking variety of dynamic regimes and morphological features, whose properties crucially depend upon droplet speed and elasticity, degree of confinement within the constriction and adhesiveness to the pore. Our results suggest that non-uniform adhesion forces are instrumental in enabling the crossing through narrow orifices, in contrast to larger gaps where a careful balance between speed and elasticity is sufficient to guarantee the transition. These observations may be useful for improving the design of artificial micro-swimmers, of interest in material science and pharmaceutics, and potentially for cell sorting in microfluidic devices., Comment: Post-peer-review version of an article published in Nature Communications

Published

2022

8. Curvature dynamics and long-range effects on fluid-fluid interfaces with colloids

Author

Tiribocchi, A., Bonaccorso, F., Lauricella, M., Melchionna, S., Montessori, A., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We investigate the dynamics of a phase-separating binary fluid, containing colloidal dumbbells anchored to the fluid-fluid interface. Extensive Lattice Boltzmann-Immersed Boundary method simulations reveal that the presence of soft dumbbells can significantly affect the curvature dynamics of the interface between phase-separating fluids, even though the coarsening dynamics is left nearly unchanged. In addition, our results show that the curvature dynamics exhibits distinct non-local effects, which might be exploited for the design of new soft mesoscale materials. We point out that the inspection of the statistical dynamics of the curvature can disclose new insights into local inhomogeneities of the binary fluid configuration, as a function of the volume fraction and aspect ratio of the dumbbells., Comment: 15 pages, 14 figures

Published

2022

9. Dynamics of polydisperse multiple emulsions in microfluidic channels

Author

Tiribocchi, A., Montessori, A., Durve, M., Bonaccorso, F., Lauricella, M., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

Multiple emulsions are a class of soft fluid in which small drops are immersed within a larger one and stabilized over long periods of time by a surfactant. We recently showed that, if a monodisperse multiple emulsion is subject to a pressure-driven flow, a wide variety of nonequilibrium steady states emerges at late times, whose dynamics relies on a complex interplay between hydrodynamic interactions and multibody collisions among internal drops. In this work, we use lattice Boltzmann simulations to study the dynamics of polydisperse double emulsions driven by a Poiseuille flow within a microfluidic channel. Our results show that their behavior is critically affected by multiple factors, such as initial position, polydispersity index, and area fraction occupied within the emulsion. While at low area fraction inner drops may exhibit either a periodic rotational motion (at low polydispersity) or arrange into nonmotile configurations (at high polydispersity) located far from each other, at larger values of area fraction they remain in tight contact and move unidirectionally. This decisively conditions their close-range dynamics, quantitatively assessed through a time-efficiency-like factor. Simulations also unveil the key role played by the capsule, whose shape changes can favor the formation of a selected number of nonequilibrium states in which both motile and nonmotile configurations are found., Comment: Post peer-review version. 11 pages, 6 figures. Movies upon request

Published

2022

10. Shear dynamics of polydisperse double emulsions

Author

Tiribocchi, A., Montessori, A., Bonaccorso, F., Lauricella, M., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

We numerically study the dynamics of a polydisperse double emulsion under a symmetric shear flow. We show that both dispersity and shear rate crucially affect the behavior of the innermost drops and of the surrounding shell. While at low/moderate values of shear rates the inner drops rotate periodically around a common center of mass triggered by the fluid vortex formed within the emulsion generally regardless of their polydispersity, at higher values such dynamics occurs only at increasing polydispersity, since monodisperse drops are found to align along the shear flow and become approximately motionless at late times. Our simulations also suggest that increasing polydispersity favours close-range contacts among cores and persistent collisions, while hindering shape deformations of the external droplet. A quantitative evaluation of these effects is also provided., Comment: 10 pages, 7 figures. Post peer-reviewed version accepted for publication on Physics of Fluids. Movies upon request

Published

2021

11. Playing with Casimir in the vacuum sandbox

Author

Kauffman, S., Succi, S., Tiribocchi, A., and Tello, P. G.

Subjects

Quantum Physics, High Energy Physics - Theory

Abstract

The Casimir effect continues to be a subject of discussion regarding its relationship, or the lack of it, with the vacuum energy of fluctuating quantum fields. In this note, we propose a Gedankenexperiment considering an imaginary process similar to a vacuum fluctuation in a typical static Casimir set up. The thought experiment leads to intriguing conclusions regarding the minimum distance between the plates when approaching the Planck scale. More specifically, it is found that distance between the plates cannot reach a value below $(L/L_P)^{2/3}$ Planck lengths, being $L_P$ the Planck length and $L$ the typical lateral extension of the plates. Additional findings allow the conclusion that the approach between the two plates towards this minimum separation distance is asymptotic.

Published

2021

12. Concentrated phase emulsion with multi-core morphology under shear: A numerical study

Author

Tiribocchi, A., Montessori, A., Bonaccorso, F., Lauricella, M., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

We numerically study the dynamic behavior under a symmetric shear flow of selected examples of concentrated phase emulsions with multi-core morphology confined within a microfluidic channel. A variety of new nonequilibrium steady states is reported. Under low shear rates, the emulsion is found to exhibit a solid-like behavior, in which cores display a periodic planetary-like motion with approximately equal angular velocity. At higher shear rates two steady states emerge, one in which all inner cores align along the flow and become essentially motionless and a further one in which some cores accumulate near the outer interface and produce a dynamical elliptical-shaped ring chain, reminiscent of a treadmilling-like structure, while others occupy the center of the emulsion. A quantitative description in terms of i) motion of the cores, ii) rate of deformation of the emulsion and iii) structure of the fluid flow within the channel is also provided., Comment: 11 pages, 15 figures

Published

2020

13. Beyond moments: relativistic Lattice-Boltzmann methods for radiative transport in computational astrophysics

Author

Weih, L. R., Gabbana, A., Simeoni, D., Rezzolla, L., Succi, S., and Tripiccione, R.

Subjects

Physics - Computational Physics, Astrophysics - High Energy Astrophysical Phenomena, General Relativity and Quantum Cosmology

Abstract

We present a new method for the numerical solution of the radiative-transfer equation (RTE) in multidimensional scenarios commonly encountered in computational astrophysics. The method is based on the direct solution of the Boltzmann equation via an extension of the Lattice Boltzmann (LB) equation and allows to model the evolution of the radiation field as it interacts with a background fluid, via absorption, emission, and scattering. As a first application of this method, we restrict our attention to a frequency independent ("grey") formulation within a special-relativistic framework, which can be employed also for classical computational astrophysics. For a number of standard tests that consider the performance of the method in optically thin, optically thick and intermediate regimes with a static fluid, we show the ability of the LB method to produce accurate and convergent results matching the analytic solutions. We also contrast the LB method with commonly employed moment-based schemes for the solution of the RTE, such as the M1 scheme. In this way, we are able to highlight that the LB method provides the correct solution for both non-trivial free-streaming scenarios and the intermediate optical-depth regime, for which the M1 method either fails or provides inaccurate solutions. When coupling to a dynamical fluid, on the other hand, we present the first self-consistent solution of the RTE with LB methods within a relativistic-hydrodynamic scenario. Finally, we show that besides providing more accurate results in all regimes, the LB method features smaller or comparable computational costs compared to the M1 scheme., Comment: 22 pages, 16 figures, matches version accepted in MNRAS

Published

2020

14. Micro-vorticity fluctuations affect the structure of thin fluid films

Author

Tiribocchi, A., Montessori, A., Miliani, S., Lauricella, M., La Rocca, M., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Computational Physics

Abstract

The dynamic interaction of complex fluid interfaces is highly sensitive to near-contact interactions occurring at the scale of ten of nanometers. Such interactions are difficult to analyse because they couple self-consistently to the dynamic morphology of the evolving interface, as well as to the hydrodynamics of the interstitial fluid film. In this work, we show that, above a given magnitude threshold, near-contact interactions trigger non-trivial micro-vorticity patterns, which in turn affect the effective near-contact interactions, giving rise to persistent fluctuating ripples at the fluid interface. In such regime, near-contact interactions may significantly affect the macroscopic arrangement of emulsion configurations, such as those arising in soft-flowing microfluidic crystals.

Published

2020

15. The vortex-driven dynamics of droplets within droplets

Author

Tiribocchi, A., Montessori, A., Lauricella, M., Bonaccorso, F., Succi, S., Aime, S., Milani, M., and Weitz, D. A.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

Understanding the fluid-structure interaction is crucial for an optimal design and manufacturing of soft mesoscale materials. Multi-core emulsions are a class of soft fluids assembled from cluster configurations of deformable oil-water double droplets (cores), often employed as building-blocks for the realisation of devices of interest in bio-technology, such as drug-delivery, tissue engineering and regenerative medicine. Here, we study the physics of multi-core emulsions flowing in microfluidic channels and report numerical evidence of a surprisingly rich variety of driven non-equilibrium states (NES), whose formation is caused by a dipolar fluid vortex triggered by the sheared structure of the flow carrier within the microchannel. The observed dynamic regimes range from long-lived NES at low core-area fraction, characterised by a planetary-like motion of the internal drops, to short-lived ones at high core-area fraction, in which a pre-chaotic motion results from multi-body collisions of inner drops, as combined with self-consistent hydrodynamic interactions. The onset of pre-chaotic behavior is marked by transitions of the cores from one vortex to another, a process that we interpret as manifestations of the system to maximize its entropy by filling voids, as they arise dynamically within the capsule., Comment: Post-peer-review version of an article published in Nature Communications. Movies upon request

Published

2020

16. Modelling drug delivery from multiple emulsions

Author

Pontrelli, G., Carr, E. J., Tiribocchi, A., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter, 65M08, 76R50, 92C05, I.6, J.2, J.6

Abstract

We present a mechanistic model of drug release from a multiple emulsion into an external surrounding fluid. We consider a single multi-layer droplet where the drug kinetics are described by a pure diffusive process through different liquid shells. The multi-layer problem is described by a system of diffusion equations coupled via interlayer conditions imposing continuity of drug concentration and flux. Mass resistance is imposed at the outer boundary through the application of a surfactant at the external surface of the droplet. The two-dimensional problem is solved numerically by finite volume discretization. Concentration profiles and drug release curves are presented for three typical round-shaped (circle, ellipse and bullet) droplets and the dependency of the solution on the mass transfer coefficient at the surface analyzed. The main result shows a reduced release time for an increased elongation of the droplets.

Published

2020

17. Dissipative hydrodynamics of relativistic shock waves in a Quark Gluon Plasma: comparing and benchmarking alternate numerical methods

Author

Gabbana, A., Plumari, S., Galesi, G., Greco, V., Simeoni, D., Succi, S., and Tripiccione, R.

Subjects

High Energy Physics - Phenomenology

Abstract

This paper presents numerical cross-comparisons and benchmark results for two different kinetic numerical methods, capable of describing relativistic dissipative fluid dynamics in a wide range of kinematic regimes, typical of relevant physics applications, such as transport phenomena in quark-gluon plasmas. We refer to relativistic lattice Boltzmann versus Montecarlo Test-Particle methods. Lacking any realistic option for accurate validation vis-a-vis experimental data, we check the consistency of our results against established simulation packages available in the literature. We successfully cross-compare the results of the two aforementioned numerical approaches for momentum integrated quantities like the hydrostatic and dynamical pressure profiles, the collective flow and the heat flux. These results corroborate the confidence on the robustness and correctness of these computational methods and on the accurate calibration of their numerical parameters with respect to the physical transport coefficients. Our numerical results are made available as supplemental material, with the aim of establishing a reference benchmark for other numerical approaches.

Published

2019

18. Mathematical modelling of drug delivery from pH-responsive nanocontainers

Author

Pontrelli, G., Toniolo, G., McGinty, S., Peri, D., Succi, S., and Chatgilialoglu, C.

Subjects

Physics - Medical Physics, Physics - Biological Physics, 35QXX, 65NXX, 65ZXX, G.1, J.2

Abstract

Drug delivery systems represent a promising strategy to treat cancer and to overcome the side effects of chemotherapy. In particular, polymeric nanocontainers have attracted major interest because of their structural and morphological advantages and the variety of polymers that can be used, allowing the synthesis of materials capable of responding to the biochemical alterations of the tumour microenvironment. While experimental methodologies can provide much insight, the generation of experimental data across a wide parameter space is usually prohibitively time consuming and/or expensive. To better understand the influence of varying design parameters on the drug release profile and drug kinetics involved, appropriately-designed mathematical models are of great benefit. Here, we developed a novel mathematical model to describe drug transport within, and release from, a hollow nanocontainer consisting of a core and a pH-responsive polymeric shell. The two-layer mathematical model fully accounts for drug dissolution, diffusion and interaction with polymer. We generated experimental drug release profiles using daunorubicin and [Cu(TPMA)(Phenantroline)](ClO_4)_2 as model drugs, for which the nanocontainers exhibited excellent encapsulation ability. The in vitro drug release behaviour was studied under different conditions, where the system proved capable of responding to the selected pH stimuli by releasing a larger amount of drug in an acidic than in the physiological environments. By comparing the results of the mathematical model with our experimental data, we were able to identify the model parameter values that best-fit the data and demonstrate that the model is capable of describing the phenomena at hand. The proposed methodology can be used to describe and predict the release profiles for a variety of drug delivery systems.

Published

2019

19. Novel non-equilibrium steady states in multiple emulsions

Author

Tiribocchi, A., Montessori, A., Aime, S., Milani, M., Lauricella, M., Succi, S., and Weitz, D.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

We numerically investigate the rheological response of a non-coalescing multiple emulsion under a symmetric shear flow. We find that the dynamics significantly depends on the magnitude of the shear rate and on the number of the encapsulated droplets, two key parameters whose control is fundamental to accurately select the resulting non-equilibrium steady states. The double emulsion, for instance, attains a static steady state in which the external droplet stretches under flow and achieves an elliptical shape (closely resembling the one observed in a sheared isolated fluid droplet), while the internal one remains essentially unaffected. Novel non-equilibrium steady states arise in a multiple emulsion. Under a low/moderate shear rates, for instance, the encapsulated droplets display a non-trivial planetary-like motion that considerably affects the shape of the external droplet. Some features of this dynamic behavior are partially captured by the Taylor deformation parameter and the stress tensor. Besides a theoretical interest on its own, our results can potentially stimulate further experiments, as most of the predictions could be tested in the lab by monitoring droplets shapes and position over time., Comment: 12 pages, 11 figures

Published

2019

20. Probing bulk viscosity in relativistic flows

Author

Gabbana, A., Simeoni, D., Succi, S., and Tripiccione, R.

Subjects

Physics - Fluid Dynamics, Physics - Computational Physics, Physics - Plasma Physics

Abstract

We derive an analytical connection between kinetic relaxation rate and bulk viscosity of a relativistic fluid in d spatial dimensions, all the way from the ultra-relativistic down to the near non-relativistic regime. Our derivation is based on both Chapman-Enskog asymptotic expansion and Grad's method of moments. We validate our theoretical results against a benchmark flow, providing further evidence of the correctness of the Chapman-Enskog approach; we define the range of validity of this approach and provide evidence of mounting departures at increasing Knudsen number. Finally, we present numerical simulations of transport processes in quark gluon plasmas, with special focus on the effects of bulk viscosity which might prove amenable to future experimental verification.

Published

2019

21. Relativistic Lattice Boltzmann Methods: Theory and Applications

Author

Gabbana, A., Simeoni, D., Succi, S., and Tripiccione, R.

Subjects

High Energy Physics - Lattice, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology, High Energy Physics - Theory, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

We present a systematic account of recent developments of the relativistic Lattice Boltzmann method (RLBM) for dissipative hydrodynamics. We describe in full detail a unified, compact and dimension-independent procedure to design relativistic LB schemes capable of bridging the gap between the ultra-relativistic regime, $k_{\rm B} T \gg mc^2$, and the non-relativistic one, $k_{\rm B} T \ll mc^2$. We further develop a systematic derivation of the transport coefficients as a function of the kinetic relaxation time in $d=1,2,3$ spatial dimensions. The latter step allows to establish a quantitative bridge between the parameters of the kinetic model and the macroscopic transport coefficients. This leads to accurate calibrations of simulation parameters and is also relevant at the theoretical level, as it provides neat numerical evidence of the correctness of the Chapman-Enskog procedure. We present an extended set of validation tests, in which simulation results based on the RLBMs are compared with existing analytic or semi-analytic results in the mildly-relativistic ($k_{\rm B} T \sim mc^2$) regime for the case of shock propagations in quark-gluon plasmas and laminar electronic flows in ultra-clean graphene samples. It is hoped and expected that the material collected in this paper may allow the interested readers to reproduce the present results and generate new applications of the RLBM scheme.

Published

2019

22. On the impact of controlled wall roughness shape on the flow of a soft-material

Author

Pelusi, F., Sbragaglia, M., Scagliarini, A., Lulli, M., Bernaschi, M., and Succi, S.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We explore the impact of geometrical corrugations on the near-wall flow properties of a soft-material driven in a confined rough microchannel. By means of numerical simulations, we perform a quantitative analysis of the relation between the flow rate $\Phi$ and the wall stress $\sigma_w$ for a number of setups, by changing both the roughness values as well as the roughness shape. Roughness suppresses the flow, with the existence of a characteristic value of $\sigma_w$ at which flow sets in. Just above the onset of flow, we quantitatively analyze the relation between $\Phi$ and $\sigma_w$. While for smooth walls a linear dependency is observed, steeper behaviours are found to set in by increasing wall roughness. The variation of the steepness, in turn, depends on the shape of the wall roughness, wherein gentle steepness changes are promoted by a variable space localization of the roughness.

Published

2019

23. Relativistic dissipation obeys Chapman-Enskog asymptotics: analytical and numerical evidence as a basis for accurate kinetic simulations

Author

Gabbana, A., Simeoni, D., Succi, S., and Tripiccione, R.

Subjects

Nuclear Theory, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

We present an analytical derivation of the transport coefficients of a relativistic gas in (2+1) dimensions for both Chapman-Enskog (CE) asymptotics and Grad's expansion methods. Moreover, we develop a systematic calibration method, connecting the relaxation time of relativistic kinetic theory to the transport parameters of the associated dissipative hydrodynamic equations. Comparison between the analytical results and numerical simulations, shows that the CE method correctly captures dissipative effects, while Grad's method does not. The resulting calibration procedure based on the CE method opens the way to the quantitative kinetic description of dissipative relativistic fluid dynamics under fairly general conditions, namely flows with strongly non-linearities, in non-ideal geometries, across both ultra-relativistic and near-non-relativistic regimes.

Published

2019

24. Fast kinetic simulator for relativistic matter

Author

Ambruş, V. E., Bazzanini, L., Gabbana, A., Simeoni, D., Succi, S., and Tripiccione, R.

Published

2022

25. Prospects for the detection of electronic pre-turbulence in graphene

Author

Gabbana, A., Polini, M., Succi, S., Tripiccione, R., and Pellegrino, F. M. D.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Based on extensive numerical simulations, accounting for electrostatic interactions and dissipative electron-phonon scattering, we propose experimentally realizable geometries capable of sustaining electronic pre-turbulence in graphene samples. In particular, pre-turbulence is predicted to occur at experimentally attainable values of the Reynolds number between 10 and 50, over a broad spectrum of frequencies between 10 and 100 GHz.

Published

2018

26. Numerical evidence of electron hydrodynamic whirlpools in graphene samples

Author

Gabbana, A., Mendoza, M., Succi, S., and Tripiccione, R.

Subjects

Physics - Computational Physics

Abstract

We present an extension of recent relativistic Lattice Boltzmann methods based on Gaussian quadratures for the study of fluids in (2+1) dimensions. The new method is applied to the analysis of electron flow in graphene samples subject to electrostatic drive; we show that the flow displays hydro-electronic whirlpools in accordance with recent analytical calculations as well as experimental results.

Published

2018

27. Microscale modelling of dielectrophoresis assembly processes

Author

Tiribocchi, A., Montessori, A., Lauricella, M., Bonaccorso, F., Brown, K. A., and Succi, S.

Published

2021

28. Kinetic approach to relativistic dissipation

Author

Gabbana, A., Mendoza, M., Succi, S., and Tripiccione, R.

Subjects

Physics - Computational Physics

Abstract

Despite a long record of intense efforts, the basic mechanisms by which dissipation emerges from the microscopic dynamics of a relativistic fluid still elude a complete understanding. In particular, no unique pathway from kinetic theory to hydrodynamics has been identified as yet, with different approaches leading to different values of the transport coefficients. In this Letter, we approach the problem by matching data from lattice kinetic simulations with analytical predictions. Our numerical results provide neat evidence in favour of the Chapman-Enskog procedure, as suggested by recently theoretical analyses, along with qualitative hints at the basic reasons why the Chapman-Enskog expansion might be better suited than Grad's method to capture the emergence of dissipative effects in relativistic fluids.

Published

2017

29. Towards a unified lattice kinetic scheme for relativistic hydrodynamics

Author

Gabbana, A., Mendoza, M., Succi, S., and Tripiccione, R.

Subjects

Physics - Computational Physics

Abstract

We present a systematic derivation of relativistic lattice kinetic equations for finite-mass particles, reaching close to the zero-mass ultra-relativistic regime treated in the previous literature. Starting from an expansion of the Maxwell-Juettner distribution on orthogonal polynomials, we perform a Gauss-type quadrature procedure and discretize the relativistic Boltzmann equation on space-filling Cartesian lattices. The model is validated through numerical comparison with standard benchmark tests and solvers in relativistic fluid dynamics such as Boltzmann approach multiparton scattering (BAMPS) and previous relativistic lattice Boltzmann models. This work provides a significant step towards the formulation of a unified relativistic lattice kinetic scheme, covering both massive and near-massless particles regimes.

Published

2017

30. Lattice Boltzmann simulations capture the multiscale physics of soft flowing crystals

Author

Montessori, A., Tiribocchi, A., Bonaccorso, F., Lauricella, M., and Succi, S.

Published

2020

31. Probing bulk viscosity in relativistic flows

Author

Gabbana, A., Simeoni, D., Succi, S., and Tripiccione, R.

Published

2020

32. Extended friction elucidates the breakdown of fast water transport in graphene oxide membranes

Author

Montessori, A., Amadei, C. A., Falcucci, G., Sega, M., Vecitis, C. D., and Succi, S.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Soft Condensed Matter

Abstract

The understanding of water transport in graphene oxide (GO) membranes stands out as a major theoretical problem in graphene research. Notwithstanding the intense efforts devoted to the subject in the recent years, a consolidated picture of water transport in GO membranes is yet to emerge. By performing mesoscale simulations of water transport in ultrathin GO membranes, we show that even small amounts of oxygen functionalities can lead to a dramatic drop of the GO permeability, in line with experimental findings. The coexistence of bulk viscous dissipation and spatially extended molecular friction results in a major decrease of both slip and bulk flow, thereby suppressing the fast water transport regime observed in pristine graphene nanochannels. Inspection of the flow structure reveals an inverted curvature in the near-wall region, which connects smoothly with a parabolic profile in the bulk region. Such inverted curvature is a distinctive signature of the coexistence between single-particle Langevin friction and collective hydrodynamics. The present mesoscopic model with spatially extended friction may offer a computationally efficient tool for future simulations of water transport in nanomaterials., Comment: 10 pages,10 figures

Published

2016

33. A Lattice Boltzmann Method for relativistic rarefied flows in [formula omitted] dimensions

Author

Bazzanini, L., Gabbana, A., Simeoni, D., Succi, S., and Tripiccione, R.

Published

2021

34. Mathematical modelling of drug delivery from pH-responsive nanocontainers

Author

Pontrelli, G., Toniolo, G., McGinty, S., Peri, D., Succi, S., and Chatgilialoglu, C.

Published

2021

35. DSMC-LBM mapping scheme for rarefied and non-rarefied gas flows

Author

Di Staso, G., Clercx, H. J. H, Succi, S., and Toschi, F.

Subjects

Physics - Fluid Dynamics, 76P05, 82B80, 82B40

Abstract

We present the formulation of a kinetic mapping scheme between the Direct Simulation Monte Carlo (DSMC) and the Lattice Boltzmann Method (LBM) which is at the basis of the hybrid model used to couple the two methods in view of efficiently and accurately simulate isothermal flows characterized by variable rarefaction effects. Owing to the kinetic nature of the LBM, the procedure we propose ensures to accurately couple DSMC and LBM at a larger Kn number than usually done in traditional hybrid DSMC-Navier-Stokes equation models. We show the main steps of the mapping algorithm and illustrate details of the implementation. Good agreement is found between the moments of the single particle distribution function as obtained from the mapping scheme and from independent LBM or DSMC simulations at the grid nodes where the coupling is imposed. We also show results on the application of the hybrid scheme based on a simpler mapping scheme for plane Poiseuille flow at finite Kn number. Potential gains in the computational efficiency assured by the application of the coupling scheme are estimated for the same flow., Comment: Submitted to Journal of Computational Science

Published

2015

36. Poiseuille flow in curved spaces

Author

Debus, J. -D., Mendoza, M., Succi, S., and Herrmann, H. J.

Subjects

Physics - Fluid Dynamics, Astrophysics - Cosmology and Nongalactic Astrophysics, Condensed Matter - Statistical Mechanics, Physics - Computational Physics

Abstract

We investigate Poiseuille channel flow through intrinsically curved media, equipped with localized metric perturbations. To this end, we study the flux of a fluid driven through the curved channel in dependence of the spatial deformation, characterized by the parameters of the metric perturbations (amplitude, range and density). We find that the flux depends only on a specific combination of parameters, which we identify as the average metric perturbation, and derive a universal flux law for the Poiseuille flow. For the purpose of this study, we have improved and validated our recently developed lattice Boltzmann model in curved space by considerably reducing discrete lattice effects.

Published

2015

37. Energy dissipation in flows through curved spaces

Author

Debus, J. -D., Mendoza, M., Succi, S., and Herrmann, H. J.

Subjects

Physics - Fluid Dynamics, Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology, Physics - Biological Physics, Physics - Computational Physics

Abstract

Fluid dynamics in intrinsically curved geometries is encountered in many physical systems in nature, ranging from microscopic bio-membranes all the way up to general relativity at cosmological scales. Despite the diversity of applications, all of these systems share a common feature: the free motion of particles is affected by inertial forces originating from the curvature of the embedding space. Here we reveal a fundamental process underlying fluid dynamics in curved space: the free motion of fluids, in the complete absence of solid walls or obstacles, exhibits loss of energy due exclusively to the intrinsic curvature of space. We find that local sources of curvature generate viscous stresses as a result of the inertial forces. The curvature-induced viscous forces are shown to cause hitherto unnoticed and yet appreciable energy dissipation, which might play a significant role for a variety of physical systems involving fluid dynamics in curved spaces.

Published

2015

38. Short-lived lattice quasiparticles for strongly interacting fluids

Author

Mendoza, M. and Succi, S.

Subjects

Condensed Matter - Strongly Correlated Electrons, Nonlinear Sciences - Cellular Automata and Lattice Gases, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

It is shown that lattice kinetic theory based on short-lived quasiparticles proves very effective in simulating the complex dynamics of strongly interacting fluids (SIF). In particular, it is pointed out that the shear viscosity of lattice fluids is the sum of two contributions, one due to the usual interactions between particles (collision viscosity) and the other due to the interaction with the discrete lattice (propagation viscosity). Since the latter is {\it negative}, the sum may turn out to be orders of magnitude smaller than each of the two contributions separately, thus providing a mechanism to access SIF regimes at ordinary values of the collisional viscosity. This concept, as applied to quantum superfluids in one-dimensional optical lattices, is shown to reproduce shear viscosities consistent with the AdS-CFT holographic bound on the viscosity/entropy ratio. This shows that lattice kinetic theory continues to hold for strongly coupled hydrodynamic regimes where continuum kinetic theory may no longer be applicable., Comment: 10 pages, 2 figures

Published

2015

39. Lattice Boltzmann model for resistive relativistic magnetohydrodynamics

Author

Mohseni, F., Mendoza, M., Succi, S., and Herrmann, H. J.

Subjects

Physics - Computational Physics, Astrophysics - Solar and Stellar Astrophysics, Physics - Fluid Dynamics, Physics - Plasma Physics

Abstract

In this paper, we develop a lattice Boltzmann model for relativistic magnetohydrodynamics (MHD). Even though the model is derived for resistive MHD, it is shown that it is numerically robust even in the high conductivity (ideal MHD) limit. In order to validate the numerical method, test simulations are carried out for both ideal and resistive limits, namely the propagation of Alfv\'en waves in the ideal MHD and the evolution of current sheets in the resistive regime, where very good agreement is observed comparing to the analytical results. Additionally, two-dimensional magnetic reconnection driven by Kelvin-Helmholtz instability is studied and the effects of different parameters on the reconnection rate are investigated. It is shown that the density ratio has negligible effect on the magnetic reconnection rate, while an increase in shear velocity decreases the reconnection rate. Additionally, it is found that the reconnection rate is proportional to $\sigma^{-\frac{1}{2}}$, $\sigma$ being the conductivity, which is in agreement with the scaling law of the Sweet-Parker model. Finally, the numerical model is used to study the magnetic reconnection in a stellar flare. Three-dimensional simulation suggests that the reconnection between the background and flux rope magnetic lines in a stellar flare can take place as a result of a shear velocity in the photosphere., Comment: 16 pages, 12 figures

Published

2015

40. Lattice Boltzmann Model for Electronic Structure Simulations

Author

Mendoza, M., Herrmann, H. J., and Succi, S.

Subjects

Physics - Chemical Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics, Physics - Computational Physics, Quantum Physics

Abstract

Recently, a new connection between density functional theory and kinetic theory has been proposed. In particular, it was shown that the Kohn-Sham (KS) equations can be reformulated as a macroscopic limit of the steady-state solution of a suitable single-particle kinetic equation. By using a discrete version of this new formalism, the exchange and correlation energies of simple atoms and the geometrical configuration of the methane molecule were calculated accurately. Here, we discuss the main ideas behind the lattice kinetic approach to electronic structure computations, offer some considerations for prospective extensions, and also show additional numerical results, namely the geometrical configuration of the water molecule., Comment: 10 pages, 3 figures

Published

2015

41. Cooling Effect of the Richtmyer-Meshkov Instability

Author

Mohseni, F., Mendoza, M., Succi, S., and Herrmann, H. J.

Subjects

Physics - Fluid Dynamics, Astrophysics - High Energy Astrophysical Phenomena, Physics - Computational Physics, Physics - Plasma Physics

Abstract

We provide numerical evidence that the Richtmyer-Meshkov (RM) instability contributes to the cooling of a relativistic fluid. Due to the presence of jet particles traveling throughout the medium, shock waves are generated in the form of Mach cones. The interaction of multiple shock waves can trigger the RM instability, and we have found that this process leads to a down-cooling of the relativistic fluid. To confirm the cooling effect of the instability, shock tube Richtmyer-Meshkov instability simulations are performed. Additionally, in order to provide an experimental observable of the RM instability resulting from the Mach cone interaction, we measure the two particle correlation function and highlight the effects of the interaction. The simulations have been performed with an improved version of the relativistic lattice Boltzmann model, including general equations of state and external forces., Comment: 10 pages, 6 figures

Published

2015

42. Cooperativity flows and Shear-Bandings: a statistical field theory approach

Author

Benzi, R., Sbragaglia, M., Bernaschi, M., Succi, S., and Toschi, F.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Cooperativity effects have been proposed to explain the non-local rheology in the dynamics of soft jammed systems. Based on the analysis of the free-energy model proposed by L. Bocquet, A. Colin \& A. Ajdari ({\em Phys. Rev. Lett.} {\bf 103}, 036001 (2009)), we show that cooperativity effects resulting from the non-local nature of the fluidity (inverse viscosity), are intimately related to the emergence of shear-banding configurations. This connection materializes through the onset of inhomogeneous compact solutions (compactons), wherein the fluidity is confined to finite-support subregions of the flow and strictly zero elsewhere. Compactons coexistence with regions of zero fluidity ("non-flowing vacuum") is shown to be stabilized by the presence of mechanical noise, which ultimately shapes up the equilibrium distribution of the fluidity field, the latter acting as an order parameter for the flow-noflow transitions occurring in the material., Comment: 33 pages, 10 figures

Published

2015

43. High-Order Kinetic Relaxation Schemes as High-Accuracy Poisson Solvers

Author

Mendoza, M., Succi, S., and Herrmann, H. J.

Subjects

Physics - Computational Physics, Astrophysics - Instrumentation and Methods for Astrophysics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Plasma Physics

Abstract

We present a new approach to find accurate solutions to the Poisson equation, as obtained from the steady-state limit of a diffusion equation with strong source terms. For this purpose, we start from Boltzmann's kinetic theory and investigate the influence of higher order terms on the resulting macroscopic equations. By performing an appropriate expansion of the equilibrium distribution, we provide a method to remove the unnecessary terms up to a desired order and show that it is possible to find, with high level of accuracy, the steady-state solution of the diffusion equation for sizeable Knudsen numbers. In order to test our kinetic approach, we discretise the Boltzmann equation and solve the Poisson equation, spending up to six order of magnitude less computational time for a given precision than standard lattice Boltzmann methods., Comment: 16 pages, 6 figures

Published

2015

44. Quantum Simulator for Transport Phenomena in Fluid Flows

Author

Mezzacapo, A., Sanz, M., Lamata, L., Egusquiza, I. L., Succi, S., and Solano, E.

Subjects

Quantum Physics, Physics - Fluid Dynamics

Abstract

Transport phenomena still stand as one of the most challenging problems in computational physics. By exploiting the analogies between Dirac and lattice Boltzmann equations, we develop a quantum simulator based on pseudospin-boson quantum systems, which is suitable for encoding fluid dynamics transport phenomena within a lattice kinetic formalism. It is shown that both the streaming and collision processes of lattice Boltzmann dynamics can be implemented with controlled quantum operations, using a heralded quantum protocol to encode non-unitary scattering processes. The proposed simulator is amenable to realization in controlled quantum platforms, such as ion-trap quantum computers or circuit quantum electrodynamics processors., Comment: 8 pages, 3 figures

Published

2015

45. Three Carleman routes to the quantum simulation of classical fluids

Author

Sanavio, C., primary, Scatamacchia, R., additional, de Falco, C., additional, and Succi, S., additional

Published

2024

46. Mesoscale modelling of soft flowing crystals

Author

Montessori, A., Lauricella, M., and Succi, S.

Published

2019

47. Internal dynamics and activated processes in Soft-Glassy materials

Author

Benzi, R., Sbragaglia, M., Scagliarini, A., Perlekar, P., Bernaschi, M., Succi, S., and Toschi, F.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Plastic rearrangements play a crucial role in the characterization of soft-glassy materials, such as emulsions and foams. Based on numerical simulations of soft-glassy systems, we study the dynamics of plastic rearrangements at the hydrodynamic scales where thermal fluctuations can be neglected. Plastic rearrangements require an energy input, which can be either provided by external sources, or made available through time evolution in the coarsening dynamics, in which the total interfacial area decreases as a consequence of the slow evolution of the dispersed phase from smaller to large droplets/bubbles. We first demonstrate that our hydrodynamic model can quantitatively reproduce such coarsening dynamics. Then, considering periodically oscillating strains, we characterize the number of plastic rearrangements as a function of the external energy-supply, and show that they can be regarded as activated processes induced by a suitable "noise" effect. Here we use the word noise in a broad sense, referring to the internal non-equilibrium dynamics triggered by spatial random heterogeneities and coarsening. Finally, by exploring the interplay between the internal characteristic time-scale of the coarsening dynamics and the external time-scale associated with the imposed oscillating strain, we show that the system exhibits the phenomenon of stochastic resonance, thereby providing further credit to the mechanical activation scenario., Comment: 21 Pages, 9 figures

Published

2014

48. Direct evidence of plastic events and dynamic heterogeneities in soft-glasses

Author

Benzi, R., Sbragaglia, M., Perlekar, P., Bernaschi, M., Succi, S., and Toschi, F.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

By using fluid-kinetic simulations of confined and concentrated emulsion droplets, we investigate the nature of space non-homogeneity in soft-glassy dynamics and provide quantitative measurements of the statistical features of plastic events in the proximity of the yield-stress threshold. Above the yield stress, our results show the existence of a finite stress correlation scale, which can be mapped directly onto the {\it cooperativity scale}, recently introduced in the literature to capture non-local effects in the soft-glassy dynamics. In this regime, the emergence of a separate boundary (wall) rheology with higher fluidity than the bulk, is highlighted in terms of near-wall spontaneous segregation of plastic events. Near the yield stress, where the cooperative scale cannot be estimated with sufficient accuracy, the system shows a clear increase of the stress correlation scale, whereas plastic events exhibit intermittent clustering in time, with no preferential spatial location. A quantitative measurement of the space-time correlation associated with the motion of the interface of the droplets is key to spot the long-range amorphous order at the yield stress threshold.

Published

2014

49. Formal analogy between the Dirac equation in its Majorana form and the discrete-velocity version of the Boltzmann kinetic equation

Author

Fillion-Gourdeau, F., Herrmann, H. J., Mendoza, M., Palpacelli, S., and Succi, S.

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

We point out a formal analogy between the Dirac equation in Majorana form and the discrete-velocity version of the Boltzmann kinetic equation. By a systematic analysis based on the theory of operator splitting, this analogy is shown to turn into a concrete and efficient computational method, providing a unified treatment of relativistic and non-relativistic quantum mechanics. This might have potentially far-reaching implications for both classical and quantum computing, because it shows that, by splitting time along the three spatial directions, quantum information (Dirac-Majorana wavefunction) propagates in space-time as a classical statistical process (Boltzmann distribution)., Comment: 5 pages, 4 figures

Published

2013

50. Relativistic effects on the Richtmyer-Meshkov instability

Author

Mohseni, F., Mendoza, M., Succi, S., and Herrmann, H. J.

Subjects

Astrophysics - High Energy Astrophysical Phenomena, Physics - Fluid Dynamics, Physics - Plasma Physics

Abstract

Theoretical and numerical analysis of the relativistic effects on the Richtmyer-Meshkov (RM) instability reveals new and potentially very useful effects. We find that, in contrast with the non- relativistic case, the growth rate of the RM instability depends strongly on the equation of state of the fluid, opening up the possibility to infer equations of state from experimental observations of the RM instability. As opposed to the non-relativistic case, we also discover that, above a critical value of the fluid velocity, the growth rate of the instability counter-intuitively decreases due to the Lorentz's factor, and vanishes in the ultrarelativistic limit, as the speed of the particles approaches the speed of light. Both effects might prove very useful for leading-edge applications, such as the study of the equation of state of quark-gluon matter, and the design of fast ignition inertial confinement fusion (ICF) schemes. We perform a linear stability analysis to characterize the instability, for an arbitrary equation of state, and implement numerical simulations to study the instability in the non-linear regime, using the equation of state of an ideal gas. Furthermore, based on the numerical results, we propose a general expression that characterizes the long term evolution of the instability., Comment: 6 pages, 4 figures

Published

2013