Your search keyword '"HERRMANN, H. J."' showing total 1,287 results

1. Fluctuation-Dissipation Relations in the imbalanced Wilson-Cowan model

Author

Nandi, M. K., De Candia, A., Sarracino, A., Herrmann, H. J., and de Arcangelis, L.

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics

Abstract

The relation between spontaneous and stimulated brain activity is a fundamental question in neuroscience, which has received wide attention in experimental studies. Recently, it has been suggested that the evoked response to external stimuli can be predicted from temporal correlations of spontaneous activity. Previous theoretical results, confirmed by the comparison with MEG data for human brains, were obtained for the Wilson-Cowan model in the condition of balance of excitation and inhibition, signature of a healthy brain. Here we extend previous studies to imbalanced conditions, by examining a region of parameter space around the balanced fixed point. Analytical results are compared to numerical simulations of Wilson-Cowan networks. We evidence that in imbalance conditions the functional form of the time correlation and response functions can show several behaviors, exhibiting also an oscillating regime caused by the emergence of complex eigenvalues. The analytical predictions are fully in agreement with numerical simulations, validating the role of cross-correlations in the response function. Furthermore, we identify the leading role of inhibitory neurons in controlling the overall activity of the system, tuning the level of excitability and imbalance., Comment: 16 pages, 7 figures

Published

2023

2. Thermodynamic analog of integrate-and-fire neuronal networks by maximum entropy modelling

Author

Simões, T. S. A. N., Filho, C. I. N. Sampaio, Herrmann, H. J., Andrade, Jr., J. S., and de Arcangelis, L.

Published

2024

3. Self-organized criticality in cumulus clouds

Author

Najafi, M. N., Cheraghalizadeh, J., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

The shape of clouds has proven to be essential for classifying them. Our analysis of images from fair weather cumulus clouds reveals that, besides by turbulence they are driven by self-organized criticality (SOC). Our observations yield exponents that support the fact the clouds, when projected to two dimensions (2D), exhibit conformal symmetry compatible with $c=-2$ conformal field theory (CFT), in contrast to 2D turbulence which has $c=0$ CFT. By using a combination of the Navier-Stokes equation, diffusion equations and a coupled map lattice (CML) we successfully simulated cloud formation, and obtained the same exponents.

Published

2020

4. Frustrated bearings

Author

Pires, R. S., Moreira, A. A., Herrmann, H. J., and Andrade Jr, J. S.

Subjects

Condensed Matter - Soft Condensed Matter, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Physics - Classical Physics

Abstract

In a bearing state, touching spheres (disks in two dimensions) roll on each other without slip. Here we frustrate a system of touching spheres by imposing two different bearing states on opposite sides and search for the configurations of lowest energy dissipation. If the dissipation between contacts of spheres is viscous (with random damping constants), the angular momentum continuously changes from one bearing state to the other. For Coulomb friction (with random friction coefficients) in two dimensions, a sharp line separates the two bearing states and we show that this line corresponds to the minimum cut. Astonishingly however, in three dimensions, intermediate bearing domains, that are not synchronized with either side, are energetically more favorable than the minimum-cut surface. Instead of a sharp cut, the steady state displays a fragmented structure. This novel type of state of minimum dissipation is characterized by a spanning network of slipless contacts that reaches every sphere. Such a situation becomes possible because in three dimensions bearing states have four degrees of freedom., Comment: 5 pages, 4 figures

Published

2020

5. The elastic backbone phase transition in the Ising model

Author

Najafi, M. N., Cheraghalizadeh, J., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

The two-dimensional (zero magnetic field) Ising model is known to undergo a second order para-ferromagnetic phase transition, which is accompanied by a correlated percolation transition for the Fortuin-Kasteleyn (FK) clusters. In this paper we uncover that there exists also a second temperature $T_{\text{eb}}

Published

2020

6. Dynamics of extended Schelling models

Author

Vieira, A. P., Goles, E., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics, Computer Science - Multiagent Systems, Nonlinear Sciences - Cellular Automata and Lattice Gases

Abstract

We explore extensions of Schelling's model of social dynamics, in which two types of agents live on a checkerboard lattice and move in order to optimize their own satisfaction, which depends on how many agents among their neighbors are of their same type. For each number $n$ of same-type nearest neighbors we independently assign a binary satisfaction variable $s_{k}$ which is equal to one only if the agent is satisfied with that condition, and is equal to zero otherwise. This defines 32 different satisfaction rules, which we investigate in detail, focusing on pattern formation and measuring segregation with the help of an "energy" function which is related to the number of neighboring agents of different types and plays no role in the dynamics. We consider the checkerboard lattice to be fully occupied and the dynamics consists of switching the locations of randomly selected unsatisfied agents of opposite types. We show that, starting from a random distribution of agents, only a small number of rules lead to (nearly) fully segregated patterns in the long run, with many rules leading to chaotic steady-state behavior. Nevertheless, other interesting patterns may also be dynamically generated, such as "anti-segregate d" patterns as well as patterns resembling sponges.

Published

2020

7. Geometry-induced non-equilibrium phase transition in sandpiles

Author

Najafi, M. N., Cheraghalizadeh, J., Lukovic, M., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

We study the sandpile model on three-dimensional spanning Ising clusters with the temperature $T$ treated as the control parameter. By analyzing the three dimensional avalanches and their two-dimensional projections (which show scale-invariant behavior for all temperatures), we uncover two universality classes with different exponents (an ordinary BTW class, and SOC$_{T=\infty}$), along with a tricritical point (at $T_c$, the critical temperature of the host) between them. The transition between these two criticalities is induced by the transition in the support. The SOC$_{T=\infty}$ universality class is characterized by the exponent of the avalanche size distribution $\tau^{T=\infty}=1.27\pm 0.03$, consistent with the exponent of the size distribution of the Barkhausen avalanches in amorphous ferromagnets (Phys. Rev. L 84, 4705 (2000)). The tricritical point is characterized by its own critical exponents. In addition to the avalanche exponents, some other quantities like the average height, the spanning avalanche probability (SAP) and the average coordination number of the Ising clusters change significantly the behavior at this point, and also exhibit power-law behavior in terms of $\epsilon\equiv \frac{T-T_c}{T_c}$, defining further critical exponents. Importantly the finite size analysis for the activity (number of topplings) per site shows the scaling behavior with exponents $\beta=0.19\pm 0.02$ and $\nu=0.75\pm 0.05$. A similar behavior is also seen for the SAP and the average avalanche height. The fractal dimension of the external perimeter of the two-dimensional projections of avalanches is shown to be robust against $T$ with the numerical value $D_f=1.25\pm 0.01$.

Published

2019

8. Self-organization and Nonuniversal Anomalous Scaling in Non-Newtonian Turbulence

Author

Seybold, H. J., Carmona, H. A., Herrmann, H. J., and Andrade, J. S.

Subjects

Physics - Fluid Dynamics

Abstract

We investigate through Direct Numerical Simulations (DNS) the statistical properties of turbulent flows in the inertial subrange for non-Newtonian power-law fluids. The structural invariance found for the vortex size distribution is achieved through a self-organized mechanism at the microscopic scale of the turbulent motion that adjusts, according to the rheological properties of the fluid, the ratio between the viscous dissipations inside and outside the vortices. Moreover, the deviations from the K41 theory of the structure functions' exponents reveal that the anomalous scaling exhibits a systematic nonuniversal behavior with respect to the rheological properties of the fluids., Comment: 5 pages, 4 figures

Published

2018

9. Critical neural networks with short and long term plasticity

Author

van Kessenich, L. Michiels, Luković, M., de Arcangelis, L., and Herrmann, H. J.

Subjects

Nonlinear Sciences - Adaptation and Self-Organizing Systems, Quantitative Biology - Neurons and Cognition

Abstract

In recent years self organised critical neuronal models have provided insights regarding the origin of the experimentally observed avalanching behaviour of neuronal systems. It has been shown that dynamical synapses, as a form of short-term plasticity, can cause critical neuronal dynamics. Whereas long-term plasticity, such as hebbian or activity dependent plasticity, have a crucial role in shaping the network structure and endowing neural systems with learning abilities. In this work we provide a model which combines both plasticity mechanisms, acting on two different time-scales. The measured avalanche statistics are compatible with experimental results for both the avalanche size and duration distribution with biologically observed percentages of inhibitory neurons. The time-series of neuronal activity exhibits temporal bursts leading to 1/f decay in the power spectrum. The presence of long-term plasticity gives the system the ability to learn binary rules such as XOR, providing the foundation of future research on more complicated tasks such as pattern recognition., Comment: 8 pages, 7 figures

Published

2017

10. The influence of statistical properties of Fourier coefficients on random surfaces

Author

de Castro, C. P., Lukovic, M., Andrade, R. F. S., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Many examples of natural systems can be described by random Gaussian surfaces. Much can be learned by analyzing the Fourier expansion of the surfaces, from which it is possible to determine the corresponding Hurst exponent and consequently establish the presence of scale invariance. We show that this symmetry is not affected by the distribution of the modulus of the Fourier coefficients. Furthermore, we investigate the role of the Fourier phases of random surfaces. In particular, we show how the surface is affected by a non-uniform distribution of phases.

Published

2017

11. Critical phenomena of a hybrid phase transition in cluster merging dynamics

Author

Choi, K., Lee, Deokjae, Cho, Y. S., Thiele, J. C., Herrmann, H. J., and Kahng, B.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Recently, a hybrid percolation transitions (HPT) that exhibits both a discontinuous transition and critical behavior at the same transition point has been observed in diverse complex systems. In spite of considerable effort to develop the theory of HPT, it is still incomplete, particularly when the transition is induced by cluster merging dynamics. Here, we aim to develop a theoretical framework of the HPT induced by such dynamics. We find that two correlation-length exponents are necessary for characterizing the giant cluster and finite clusters, respectively. Finite-size scaling method for the HPT is also introduced. The conventional formula of the fractal dimension in terms of the critical exponents is not valid. Neither the giant nor finite clusters are fractals but they have fractal boundaries., Comment: 8 pages, 6 figures, 1 table

Published

2017

12. Thermal gas rectification using a sawtooth channel

Author

Solorzano, S., Araujo, N. A. M., and Herrmann, H. J.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We study the rectification of a two-dimensional thermal gas in a channel of asymmetric dissipative walls. For an ensemble of smooth Lennard-Jones particles, our numerical simulations reveal a non-monotonic dependence of the flux on the thermostat temperature, channel asymmetry, and particle density, with three distinct regimes. Theoretical arguments are developed to shed light on the functional dependence of the flux on the model parameters.

Published

2017

13. The complex social network of surnames: A comparison between Brazil and Portugal

Author

Ferreira, G. D., Viswanathan, G. M., da Silva, L. R., and Herrmann, H. J.

Subjects

Physics - Physics and Society, Computer Science - Social and Information Networks

Abstract

We present a study of social networks based on the analysis of Brazilian and Portuguese family names (surnames). We construct networks whose nodes are names of families and whose edges represent parental relations between two families. From these networks we extract the connectivity distribution, clustering coefficient, shortest path and centrality. We find that the connectivity distribution follows an approximate power law. We associate the number of hubs, centrality and entropy to the degree of miscegenation in the societies in both countries. Our results show that Portuguese society has a higher miscegenation degree than Brazilian society. All networks analyzed lead to approximate inverse square power laws in the degree distribution. We conclude that the thermodynamic limit is reached for small networks (3 or 4 thousand nodes). The assortative mixing of all networks is negative, showing that the more connected vertices are connected to vertices with lower connectivity. Finally, the network of surnames presents some small world characteristics., Comment: 13 pages, 5 figures

Published

2017

14. Segregation of charged particles in shear induced diffusion

Author

Yoshimatsu, R., Araújo, N. A. M., Shinbrot, T., and Herrmann, H. J.

Subjects

Physics - Computational Physics, Condensed Matter - Soft Condensed Matter

Abstract

We study segregation of a binary mixture of similarly charged particles under shear using particle-based simulations. We simulate particle dynamics using a discrete-element model including electrostatic interactions and find that particles segregate according to their net charge. Particles that are charged twice as strong as other particles of the same electrical sign are seen more at insulating boundaries with which we shear the system. Weakly charged particles, on the other hand, stay more in the center of the sheared bed. We propose a simple model based on electrostatic potential energy to understand this segregation. The model shows that the segregated system we observe in our simulations is indeed the most favorable configuration in terms of electrostatic potential energy. Our simulations further show that for a given packing fraction there is an optimal shear velocity where the segregation maximally intensifies. We show that this maximum results from a competition between diffusional and Coulomb fluxes. For a larger shear velocity, diffusion suppresses segregation.

Published

2017

15. Cutting self-similar space-filling sphere packings

Author

Stäger, D. V. and Herrmann, H. J.

Subjects

Condensed Matter - Soft Condensed Matter, Condensed Matter - Other Condensed Matter

Abstract

Any space-filling packing of spheres can be cut by a plane to obtain a space-filling packing of disks. Here, we deal with space-filling packings generated using inversive geometry leading to exactly self-similar fractal packings. First, we prove that cutting along a random hyperplane leads in general to a packing with a fractal dimension of the one of the uncut packing minus one. Second, we find special cuts which can be constructed themselves by inversive geometry. Such special cuts have specific fractal dimensions, which we demonstrate by cutting a three- and a four-dimensional packing. The increase in the number of found special cuts with respect to a cutoff parameter suggests the existence of infinitely many topologies with distinct fractal dimensions., Comment: 10 pages, 15 figures

Published

2016

16. Synaptic plasticity and neuronal refractory time cause scaling behaviour of neuronal avalanches

Author

van Kessenich, L. Michiels, de Arcangelis, L., and Herrmann, H. J.

Subjects

Quantitative Biology - Neurons and Cognition, Nonlinear Sciences - Adaptation and Self-Organizing Systems

Abstract

Neuronal avalanches measured in vitro and in vivo in different cortical networks consistently exhibit power law behaviour for the size and duration distributions with exponents typical for a mean field self-organized branching process. These exponents are also recovered in neuronal network simulations implementing various neuronal dynamics on different network topologies. They can therefore be considered a very robust feature of spontaneous neuronal activity. Interestingly, this scaling behaviour is also observed on regular lattices in finite dimensions, which raises the question about the origin of the mean field behaviour observed experimentally. In this study we provide an answer to this open question by investigating the effect of activity dependent plasticity in combination with the neuronal refractory time in a neuronal network. Results show that the refractory time hinders backward avalanches forcing a directed propagation. Hebbian plastic adaptation plays the role of sculpting these directed avalanche patterns into the topology of the network slowly changing it into a branched structure where loops are marginal., Comment: 9 pages, 4 figures, to be published in Scientific Reports

Published

2016

17. Self-similar space-filling sphere packings in three and four dimensions

Author

Stäger, D. V. and Herrmann, H. J.

Subjects

Condensed Matter - Other Condensed Matter, Mathematics - Metric Geometry

Abstract

Inversive geometry can be used to generate exactly self-similar space-filling sphere packings. We present a construction method in two dimensions and generalize it to search for packings in higher dimensions. We newly discover 29 three-dimensional and 13 four-dimensional topologies of which 10 and 5, respectively, are bearings. To distinguish and characterize the packing topologies, we numerically estimate their fractal dimensions and we analyze their contact networks.

Published

2016

18. How the site degree influences quantum probability on inhomogeneous substrates

Author

Souza, A. M. C., Andrade, R. F. S., Araújo, N. A. M., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

We investigate the effect of the node degree and energy $E$ on the electronic wave function for regular and irregular structures, namely, regular lattices, disordered percolation clusters, and complex networks. We evaluate the dependence of the quantum probability for each site on its degree. For bi-regular structures, we prove analytically that the probability $P_k(E)$ of finding the particle on any site with $k$ neighbors is independent of $E$. For more general structures, the dependency of $P_k(E)$ on $E$ is discussed by taking into account exact results on a one-dimensional semi-regular chain: $P_k(E)$ is large for small values of $E$ when $k$ is also small, and its maximum values shift towards large values of $|E|$ with increasing $k$. Numerical evaluations of $P_k(E)$ for two different types of percolation clusters and the Apollonian network suggest that this feature might be generally valid, Comment: 19 pages, 6 figures, original article

Published

2016

19. Crumpling Damaged Graphene

Author

Giordanelli, I., Mendoza, M., Andrade, Jr., J. S., Gomes, M. A. F., and Herrmann, H. J.

Subjects

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

Abstract

Through molecular mechanics we find that non-covalent interactions modify the fractality of crumpled damaged graphene. Pristine graphene membranes are damaged by adding random vacancies and carbon-hydrogen bonds. Crumpled membranes exhibit a fractal dimension of $ 2.71 \pm 0.02$ when all interactions between carbon atoms are considered, and $2.30 \pm 0.05$ when non-covalent interactions are suppressed. The transition between these two values, obtained by switching on/off the non-covalent interactions of equilibrium configurations, is shown to be reversible and independent on thermalisation. In order to explain this transition, we propose a theoretical model that is compatible with our numerical findings. Finally, we also compare damaged graphene membranes with other crumpled structures, as for instance, polymerised membranes and paper sheets, that share similar scaling properties.

Published

2016

20. Connectivity disruption sparks explosive epidemic spreading

Author

Böttcher, L., Woolley-Meza, O., Goles, E., Helbing, D., and Herrmann, H. J.

Subjects

Physics - Physics and Society

Abstract

We investigate the spread of an infection or other malfunction of cascading nature when a system component can recover only if it remains reachable from a functioning central component. We consider the susceptible-infected-susceptible model, typical of mathematical epidemiology, on a network. Infection spreads from infected to healthy nodes, with the addition that infected nodes can only recover when they remain connected to a predefined central node, through a path that contains only healthy nodes. In this system, clusters of infected nodes will absorb their noninfected interior because no path exists between the central node and encapsulated nodes. This gives rise to the simultaneous infection of multiple nodes. Interestingly, the system converges to only one of two stationary states: either the whole population is healthy or it becomes completely infected. This simultaneous cluster infection can give rise to discontinuous jumps of different sizes in the number of failed nodes. Larger jumps emerge at lower infection rates. The network topology has an important effect on the nature of the transition: we observed hysteresis for networks with dominating local interactions. Our model shows how local spread can abruptly turn uncontrollable when it disrupts connectivity at a larger spatial scale.

Published

2016

21. Conformal Invariance of Graphene Sheets

Author

Giordanelli, I., Posé, N., Mendoza, M., and Herrmann, H. J.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Computational Physics

Abstract

Suspended graphene sheets exhibit correlated random deformations that can be studied under the framework of rough surfaces with a Hurst (roughness) exponent $0.72 \pm 0.01$. Here, we show that, independent of the temperature, the iso-height lines at the percolation threshold have a well-defined fractal dimension and are conformally invariant, sharing the same statistical properties as Schramm-Loewner evolution (SLE$_{\kappa}$) curves with $\kappa=2.24\pm0.07$. Interestingly, iso-height lines of other rough surfaces are not necessarily conformally invariant even if they have the same Hurst exponent, e.g. random Gaussian surfaces. We have found that the distribution of the modulus of the Fourier coefficients plays an important role on this property. Our results not only introduce a new universality class and place the study of suspended graphene membranes within the theory of critical phenomena, but also provide hints on the long-standing question about the origin of conformal invariance in iso-height lines of rough surfaces.

Published

2016

22. Field Driven Charging Dynamics of a Fluidized Granular Bed

Author

Yoshimatsu, R., Araújo, N. A. M., Shinbrot, T., and Herrmann, H. J.

Subjects

Physics - Computational Physics, Condensed Matter - Soft Condensed Matter

Abstract

A simplified model has previously described the inductive charging of colliding identical grains in the presence of an external electric field. Here we extend that model by including heterogeneous surface charge distributions, grain rotations and electrostatic interactions between grains. We find from this more realistic model that strong heterogeneities in charging can occur in agitated granular beds, and we predict that shielding due to these heterogeneities can dramatically alter the charging rate in such beds.

Published

2016

23. Gender gap in the ERASMUS mobility program

Author

Böttcher, L., Araújo, N. A. M., Nagler, J., Mendes, J. F. F., Helbing, D., and Herrmann, H. J.

Subjects

Physics - Physics and Society

Abstract

Studying abroad has become very popular among students. The ERASMUS mobility program is one of the largest international student exchange programs in the world, which has supported already more than three million participants since 1987. We analyzed the mobility pattern within this program in 2011-12 and found a gender gap across countries and subject areas. Namely, for almost all participating countries, female students are over-represented in the ERASMUS program when compared to the entire population of tertiary students. The same tendency is observed across different subject areas. We also found a gender asymmetry in the geographical distribution of hosting institutions, with a bias of male students in Scandinavian countries. However, a detailed analysis reveals that this latter asymmetry is rather driven by subject and consistent with the distribution of gender ratios among subject areas.

Published

2016

24. Emergence of core-peripheries in networks

Author

Verma, T., Russmann, F., Araújo, N. A. M., Nagler, J., and Herrmann, H. J.

Subjects

Physics - Physics and Society, Physics - Data Analysis, Statistics and Probability

Abstract

A number of important transport networks, such as the airline and trade networks of the world, exhibit a characteristic core-periphery structure, wherein a few nodes are highly interconnected and the rest of the network frays into a tree. Mechanisms underlying the emergence of core-peripheries, however, remain elusive. Here, we demonstrate that a simple pruning process based on removal of underutilized links and redistribution of loads can lead to the emergence of core-peripheries. Links are assumed beneficial if they either carry a sufficiently large load or are essential for global connectivity. This incentivized redistribution process is controlled by a single parameter which balances connectivity and profit. The obtained networks exhibit a highly resilient and connected core with a frayed periphery. The balanced network shows a higher resilience than the World Airline Network or the World Trade Network, revealing a pathway towards robust structural features through pruning.

Published

2016

25. Model for the growth of the World Airline Network

Author

Verma, T., Araújo, N. A. M., Nagler, J., Andrade Jr., J. S., and Herrmann, H. J.

Subjects

Physics - Physics and Society

Abstract

We propose a probabilistic growth model for transport networks which employs a balance between popularity of nodes and the physical distance between nodes. By comparing the degree of each node in the model network and the WAN, we observe that the difference between the two is minimized for $\alpha\approx 2$. Interestingly, this is the value obtained for the node-node correlation function in the WAN. This suggests that our model explains quite well the growth of airline networks., Comment: 4 pages, 3 figures

Published

2016

26. Critical fragmentation properties of random drilling: How many random holes need to be drilled to collapse a wooden cube?

Author

Schrenk, K. J., Hilário, M. R., Sidoravicius, V., Araújo, N. A. M., Herrmann, H. J., Thielmann, M., and Teixeira, A.

Subjects

Condensed Matter - Statistical Mechanics, Mathematics - Probability

Abstract

A solid wooden cube fragments into pieces as we sequentially drill holes through it randomly. This seemingly straightforward observation encompasses deep and nontrivial geometrical and probabilistic behavior that is discussed here. Combining numerical simulations and rigorous results, we find off-critical scale-free behavior and a continuous transition at a critical density of holes that significantly differs from classical percolation.

Published

2016

27. Hybrid Percolation Transition in Cluster Merging Processes: Continuously Varying Exponents

Author

Cho, Y. S., Lee, J. S., Herrmann, H. J., and Kahng, B.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Consider growing a network, in which every new connection is made between two disconnected nodes. At least one node is chosen randomly from a subset consisting of $g$ fraction of the entire population in the smallest clusters. Here we show that this simple strategy for improving connection exhibits a phase transition barely studied before, namely a hybrid percolation transition exhibiting the properties of both first-order and second-order phase transitions. The cluster size distribution of finite clusters at a transition point exhibits power-law behavior with a continuously varying exponent $\tau$ in the range $2 < \tau(g) \le 2.5$. This pattern reveals a necessary condition for a hybrid transition in cluster aggregation processes, which is comparable to the power-law behavior of the avalanche size distribution arising in models with link-deleting processes in interdependent networks., Comment: 5 pages, 3 figures

Published

2015

28. 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

29. 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

30. Coupled DEM-LBM method for the free-surface simulation of heterogeneous suspensions

Author

Leonardi, A., Wittel, F. K., Mendoza, M., and Herrmann, H. J.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

The complexity of the interactions between the constituent granular and liquid phases of a suspension requires an adequate treatment of the constituents themselves. A promising way for numerical simulations of such systems is given by hybrid computational frameworks. This is naturally done, when the Lagrangian description of particle dynamics of the granular phase finds a correspondence in the fluid description. In this work we employ extensions of the Lattice-Boltzmann Method for non-Newtonian rheology, free surfaces, and moving boundaries. The models allows for a full coupling of the phases, but in a simplified way. An experimental validation is given by an example of gravity driven flow of a particle suspension.

Published

2015

31. Schramm-Loewner Evolution and isoheight lines of correlated landscapes

Author

Pose, N., Schrenk, K. J., Araujo, N. A. M., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Real landscapes are usually characterized by long-range height-height correlations, which are quantified by the Hurst exponent $H$. We analyze the statistical properties of the isoheight lines for correlated landscapes of $H\in [-1,1]$. We show numerically that, for $H\leq 0$ the statistics of these lines is compatible with $SLE$ and that established analytic results are recovered for $H=-1$ and $H=0$. This result suggests that for negative $H$, in spite of the long-range nature of correlations, the statistics of isolines is fully encoded in a Brownian motion with a single parameter in the continuum limit. By contrast, for positive $H$ we find that the one-dimensional time series encoding the isoheight lines is not Markovian and therefore not consistent with $SLE$.

Published

2015

32. 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

33. En route to a multi-model scheme for clinker comminution with chemical grinding aids

Author

Mishra, R. K., Geissbuhler, D., Carmona, H. A., Wittel, F. K., Sawley, M. L., Weibel, M., Gallucci, E., Herrmann, H. J., Heinz, H., and Flatt, R. J.

Subjects

Physics - Chemical Physics

Abstract

We present a multi-model simulation approach, targeted at understanding the behavior of comminution and the effect of grinding aids (GAs) in industrial cement mills. On the atomistic scale we use Molecular Dynamics (MD) simulations with validated force field models to quantify elastic and structural properties, cleavage energies as well as the organic interactions with mineral surfaces. Simulations based on the Discrete Element Method (DEM) are used to integrate the information gained from MD simulations into the clinker particle behavior at larger scales. Computed impact energy distributions from DEM mill simulations can serve as a link between large-scale industrial and laboratory sized mills. They also provide the required input for particle impact fragmentation models. Such a multi-scale, multi-model methodology paves the way for a structured approach to the design of chemical additives aimed at improving mill performance., Comment: 9 pages in Advances in Applied Ceramics 2015

Published

2015

34. 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

35. 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

36. Analysis of the velocity field of granular hopper flow

Author

Magalhães, F. G. R., Atman, A. P. F., Moreira, J. G., and Herrmann, H. J.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We report the analysis of radial characteristics of the flow of granular material through a conical hopper. The discharge is simulated for various orifice sizes and hopper opening angles. Velocity profiles are measured along two radial lines from the hopper cone vertex: along the main axis of the cone and along its wall. An approximate power law dependence on the distance from the orifice is observed for both profiles, although differences between them can be noted. In order to quantify these differences, we propose a Local Mass Flow index that is a promising tool in the direction of a more reliable classification of the flow regimes in hoppers.

Published

2015

37. Stochastic Loewner Evolution Relates Anomalous Diffusion and Anisotropic Percolation

Author

Credidio, H. F., Moreira, A. A., Herrmann, H. J., and Andrade, J. S.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

We disclose the origin of anisotropic percolation perimeters in terms of the Stochastic Loewner Evolution (SLE) process. Precisely, our results from extensive numerical simulations indicate that the perimeters of multi-layered and directed percolation clusters at criticality are the scaling limits of the Loewner evolution of an anomalous Brownian motion, being subdiffusive and superdiffusive, respectively. The connection between anomalous diffusion and fractal anisotropy is further tested by using long-range power-law correlated time series (fractional Brownian motion) as driving functions in the evolution process. The fact that the resulting traces are distinctively anisotropic corroborates our hypothesis. Under the conceptual framework of SLE, our study therefore reveals new perspectives for mathematical and physical interpretations of non-Markovian processes in terms of anisotropic paths at criticality and vice-versa., Comment: 5 pages, 4 figures

Published

2015

38. Prediction and control of slip-free rotation states in sphere assemblies

Author

Stäger, D. V., Araújo, N. A. M., and Herrmann, H. J.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We study fixed assemblies of touching spheres that can individually rotate. From any initial state, sliding friction drives an assembly toward a slip-free rotation state. For bipartite assemblies, which have only even loops, this state has at least four degrees of freedom. For exactly four degrees of freedom, we analytically predict the final state, which we prove to be independent of the strength of sliding friction, from an arbitrary initial one. With a tabletop experiment, we show how to impose any slip-free rotation state by only controlling two spheres, regardless of the total number.

Published

2015

39. 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

40. Complex networks from space-filling bearings

Author

Kranz, J. J., Araújo, N. A. M., Andrade Jr., J. S., and Herrmann, H. J.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Two dimensional space-filling bearings are dense packings of disks that can rotate without slip. We consider the entire first family of bearings for loops of size four and propose a hierarchical construction of their contact network. We provide analytic expressions for the clustering coefficient and degree distribution, revealing bipartite scale-free behavior with tunable degree exponent depending on the bearing parameters. We also analyze their average shortest path and percolation properties.

Published

2015

41. Granular front formation in free-surface flow of concentrated suspensions

Author

Leonardi, A., Cabrera, M., Wittel, F. K., Kaitna, R., Mendoza, M., Wu, W., and Herrmann, H. J.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

Granular fronts are a common yet unexplained phenomenon emerging during the gravity driven free-surface flow of concentrated suspensions. They are usually believed to be the result of fluid convection in combination with particle size segregation. However, suspensions composed of uniformly sized particles also develop a granular front. Within a large rotating drum, a stationary recirculating avalanche is generated. The flowing material is a mixture of a visco-plastic fluid obtained from a kaolin-water dispersion, with spherical ceramic particles denser than the fluid. The goal is to mimic the composition of many common granular-fluid materials, like fresh concrete or debris flow. In these materials, granular and fluid phases have the natural tendency to segregate due to particle settling. However, through the shearing caused by the rotation of the drum, a reorganization of the phases is induced, leading to the formation of a granular front. By tuning the material properties and the drum velocity, it is possible to control this phenomenon. The setting is reproduced in a numerical environment, where the fluid is solved by a Lattice-Boltzmann Method, and the particles are explicitly represented using the Discrete Element Method. The simulations confirm the findings of the experiments, and provide insight into the internal mechanisms. Comparing the time-scale of particle settling with the one of particle recirculation, a non-dimensional number is defined, and is found to be effective in predicting the formation of a granular front., Comment: The first two authors contributed equally to this paper, and should be regarded as co-first authors

Published

2015

42. Watersheds in disordered media

Author

Araújo, N. A. M., Schrenk, K. J., Herrmann, H. J., and Andrade Jr, J. S.

Subjects

Physics - Geophysics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics

Abstract

What is the best way to divide a rugged landscape? Since ancient times, watersheds separating adjacent water systems that flow, for example, toward different seas, have been used to delimit boundaries. Interestingly, serious and even tense border disputes between countries have relied on the subtle geometrical properties of these tortuous lines. For instance, slight and even anthropogenic modifications of landscapes can produce large changes in a watershed, and the effects can be highly nonlocal. Although the watershed concept arises naturally in geomorphology, where it plays a fundamental role in water management, landslide, and flood prevention, it also has important applications in seemingly unrelated fields such as image processing and medicine. Despite the far-reaching consequences of the scaling properties on watershed-related hydrological and political issues, it was only recently that a more profound and revealing connection has been disclosed between the concept of watershed and statistical physics of disordered systems. This review initially surveys the origin and definition of a watershed line in a geomorphological framework to subsequently introduce its basic geometrical and physical properties. Results on statistical properties of watersheds obtained from artificial model landscapes generated with long-range correlations are presented and shown to be in good qualitative and quantitative agreement with real landscapes.

Published

2014

43. ADHERENCE AND ACCEPTANCE OF A NEW ORAL NUTRITIONAL SUPPLEMENT IN CANCER PATIENTS - A PILOT STUDY IN CROSSOVER DESIGN.

Author

HARDT, L. M., KONTUREK, P. C., HERRMANN, H. J., RELJIC, D., KUGLER, L., MEYER, J., NEURATH, M. F., and ZOPF, Y.

Subjects

BODY composition, DIETARY supplements, NUTRITIONAL status, QUALITY of life, MEDICAL prescriptions

Abstract

Oral nutritional supplements (ONS) play a key role in the therapy of cancer-cachexia, but adherence to ONS-intake remains challenging. To improve adherence, a wide variety of ONS is crucial. We compared the acceptance and adherence of a commercial liquid ONS (LS) with a newly developed, energy- and protein-rich, semisolid, fruit-gum based product (FG) in oncological patients. Forty cancer patients with indication for artificial nutritional therapy were randomly assigned to LS and FG in crossover design for 4 weeks with a 1-week washout phase in-between. Adherence to ONS was recorded with MARS-D questionnaire. Sensory properties were evaluated and safety monitoring was performed. Energy and nutrient intake, nutrition and performance status and quality of life remained stable in both groups throughout the study (all p-values for the comparison between baseline and after 9 weeks were >0.05). Taste (p=0.004), smell (p=0.025) and enjoyment (p=0.027) of the LS were rated significantly better compared to FG and a higher adherence (p=0.005) for the LS was found. Nevertheless, patients were very interested about the new alternative of ONS, so that 16 of the study participants would buy it or strive for a medical prescription. The balanced, protein-rich ONS based on fruit gum is an innovative formulation that stabilizes nutritional status and might therefore extend the options for nutritional support in cancer patients in the future. However, the sensory properties must first be further improved to increase acceptance and adherence. [ABSTRACT FROM AUTHOR]

Published

2024

44. Thermodynamic analog of integrate-and-fire neuronal networks by maximum entropy modelling

Author

Simões, T. S. A. N., primary, Filho, C. I. N. Sampaio, additional, Herrmann, H. J., additional, Andrade, J. S., additional, and de Arcangelis, L., additional

Published

2024

45. Dean Instability in Double-Curved Channels

Author

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

Subjects

Physics - Fluid Dynamics

Abstract

We study the Dean instability in curved channels using the lattice Boltzmann model for generalized metrics. For this purpose, we first improve and validate the method by measuring the critical Dean number at the transition from laminar to vortex flow for a streamwise curved rectangular channel, obtaining very good agreement with the literature values. Taking advantage of the easy implementation of arbitrary metrics within our model, we study the fluid flow through a double-curved channel, using ellipsoidal coordinates, and study the transition to vortex flow in dependence of the two perpendicular curvature radii of the channel. We observe not only transitions to 2-cell vortex flow, but also to 4-cell and even 6-cell vortex flow, and we find that the critical Dean number at the transition to 2-cell vortex flow exhibits a minimum when the two curvature radii are approximately equal., Comment: accepted by Phys. Rev. E

Published

2014

46. Nutritional status and body composition in patients with glioblastoma

Author

Hardt, L., primary, Herz, D., additional, Reljic, D., additional, Herrmann, H.-J., additional, Neurath, M.F., additional, and Zopf, Y., additional

Published

2023

47. Differences in body composition analysis using two market leaders of BIA devices: implications for research and clinical practice

Author

Herz, D., primary, Hardt, L., additional, Reljic, D., additional, Herrmann, H.-J., additional, Neurath, M.F., additional, and Zopf, Y., additional

Published

2023

48. Modelling the influence of photospheric turbulence on solar flare statistics

Author

Mendoza, M., Kaydul, A., de Arcangelis, L., Andrade Jr., J. S., and Herrmann, H. J.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Condensed Matter - Statistical Mechanics, Physics - Computational Physics, Physics - Fluid Dynamics, Physics - Plasma Physics

Abstract

Solar flares stem from the reconnection of twisted magnetic field lines in the solar photosphere. The energy and waiting time distributions of these events follow complex patterns that have been carefully considered in the past and that bear some resemblance with earthquakes and stockmarkets. Here we explore in detail the tangling motion of interacting flux tubes anchored in the plasma and the energy ejections resulting when they recombine. The mechanism for energy accumulation and release in the flow is reminiscent of self-organized criticality. From this model we suggest the origin for two important and widely studied properties of solar flare statistics, including the time-energy correlations. We first propose that the scale-free energy distribution of solar flares is largely due to the twist exerted by the vorticity of the turbulent photosphere. Second, the long-range temporal and time-energy correlations appear to arise from the tube-tube interactions. The agreement with satellite measurements is encouraging., Comment: 24 pages, 8 figures

Published

2014

49. Mandala Networks: ultra-robust, ultra-small-world and highly sparse graphs

Author

Filho, C. I. N. Sampaio, Moreira, A. A., Andrade, R. F. S., Herrmann, H. J., and Andrade Jr, J. S.

Subjects

Physics - Physics and Society, Computer Science - Social and Information Networks

Abstract

The increasing demands in security and reliability of infrastructures call for the optimal design of their embedded complex networks topologies. The following question then arises: what is the optimal layout to fulfill best all the demands? Here we present a general solution for this problem with scale-free networks, like the Internet and airline networks. Precisely, we disclose a way to systematically construct networks which are 100$\%$ robust against random failures as well as to malicious attacks. Furthermore, as the sizes of these networks increase, their shortest paths become asymptotically invariant and densities of links go to zero, making them ultra-small worlds and highly sparse, respectively. The first property is ideal for communication and navigation purposes, while the second is interesting economically., Comment: 8 pages, 5 figures

Published

2014

50. Flood avalanches in a semiarid basin with a dense reservoir network

Author

Peter, Samuel J., de Araújo, J. C., Araújo, N. A. M., and Herrmann, H. J.

Subjects

Physics - Data Analysis, Statistics and Probability, Condensed Matter - Statistical Mechanics, Physics - Geophysics

Abstract

This study investigates flood avalanches in a dense reservoir network in the semiarid north-eastern Brazil. The population living in this area strongly depends on the availability of the water from this network. Water is stored during intense wet-season rainfall events and evaporates from the reservoir surface during the dry season. These seasonal changes are the driving forces behind the water dynamics in the network. The reservoir network and its connectivity properties during flood avalanches are investigated with a model called ResNetM, which simulates each reservoir explicitly. It runs on the basis of daily calculated water balances for each reservoir. A spilling reservoir contributes with water to the reservoir downstream, which can trigger avalanches affecting, in some cases, large fractions of the network. The main focus is on the study of the relation between the total amount of water stored and the largest observable cluster of connected reservoirs that overspill in the same day. It is shown that the thousands of small and middle-sized reservoirs are eminent for the retention of water upstream the large ones. Therefore, they prevent large clusters at a low level of water. Concerning connectivity measures, the actual reservoir network, which evolved without an integrated plan, performed better (i.e., generated smaller avalanches for similar amount of stored water) than numerous stochastically generated artificial reservoir networks on the same river network.

Published

2014