399 research outputs found
Effect of habitat degradation on competition, carrying capacity, and species assemblage stability
In human-impacted rivers, nutrient pollution
has the potential to disrupt biodiversity organisation
and ecosystem functioning, prompting calls for
effective monitoring and management. Pollutants,
together with natural variations, can modify the
isotopic signature of aquatic organisms. Accordingly,
we explored the potential of isotopic variations as an
indicator of drainage basin influences on river food
webs. We assessed stable N and C isotopes within six
food webs along a river affected by multiple pollution
sources. CORINE land cover maps and Digital
Elevation Models (DEMs) were also applied to
understand the impact on surface waters of anthropogenic
pressures affecting the catchment. N isotopic
signatures of taxa fell in association with ammonium
inputs from agriculture, indicating that nitrogen pollution
was related to synthetic fertilizers. Isotopic
variations were consistent across trophic levels, highlighting
site-specific communities and identifying taxa
exposed to pollutants. This allowed us to locate point
sources of disturbance, suggesting that food web
structure plays a key role in pollutant compartmentalisation
along the river. Thematic maps and DEMs
helped understand how the anthropogenic impact on
river biota is mediated by hydro-geomorphology.
Thus, the integration of site-scale analyses of
stable isotopes and land use represents a promising
research pathway for explorative nutrient pollution
monitoring in human-impacted rivers
Glassy features of crystal plasticity
Crystal plasticity occurs by deformation bursts due to the avalanche-like
motion of dislocations. Here we perform extensive numerical simulations of a
three-dimensional dislocation dynamics model under quasistatic
stress-controlled loading. Our results show that avalanches are power-law
distributed, and display peculiar stress and sample size dependence: The
average avalanche size grows exponentially with the applied stress, and the
amount of slip increases with the system size. These results suggest that
intermittent deformation processes in crystalline materials exhibit an extended
critical-like phase in analogy to glassy systems, instead of originating from a
non-equilibrium phase transition critical point.Comment: 6 pages, 4 figures, Supplemental Material as an ancillary file,
accepted for publication in Phys. Rev.
Time- and depth-wise trophic niche shifts in Antarctic benthos
Climate change is expected to affect resource-consumer interactions underlying stability in polar food webs. Polar benthic organisms have adapted to the marked seasonality characterising their habitats by concentrating foraging and reproductive activity in summer months, when inputs from sympagic and pelagic producers increase. While this enables the persistence of biodiverse food webs, the mechanisms underlying changes in resource use and nutrient transfer are poorly understood. Thus, our understanding of how temporal and spatial variations in the supply of resources may affect food web structure and functioning is limited. By means of C and N isotopic analyses of two key Antarctic benthic consumers (Adamussium colbecki, Bivalvia, and Sterechinus neumayeri, Echinoidea) and Bayesian mixing models, we describe changes in trophic niche and nutrient transfer across trophic levels associated with the long- and short-term diet and body size of specimens sampled in midsummer in both shallow and deep waters. Samplings occurred soon after the sea-ice broke up at Tethys Bay, an area characterised by extreme seasonality in sea-ice coverage and productivity in the Ross Sea. In the long term, the trophic niche was broader and variation between specimens was greater, with intermediate-size specimens generally consuming a higher number of resources than small and large specimens. The coupling of energy channels in the food web was consequently more direct than in the short term. Sediment and benthic algae were more frequently consumed in the long term, before the sea-ice broke up, while consumers specialised on sympagic algae and plankton in the short term. Regardless of the time scale, sympagic algae were more frequently consumed in shallow waters, while plankton was more frequently consumed in deep waters. Our results suggest a strong temporal relationship between resource availability and the trophic niche of benthic consumers in Antarctica. Potential climate-driven changes in the timing and quality of nutrient inputs may have profound implications for the structure of polar food webs and the persistence of their constituent species, which have adapted their trophic niches to a highly predictable schedule of resource inputs
The inelastic hard dimer gas: a non-spherical model for granular matter
We study a two-dimensional gas of inelastic smooth hard dimers. Since the
collisions between dimers are dissipative, being characterized by a coefficient
of restitution , and no external driving force is present, the energy
of the system decreases in time and no stationary state is achieved. However,
the resulting non equilibrium state of the system displays several interesting
properties in close analogy with systems of inelastic hard spheres, whose
relaxational dynamics has been thoroughly explored. We generalise to inelastic
systems a recently method introduced [G.Ciccotti and G.Kalibaeva, J. Stat.
Phys. {\bf 115}, 701 (2004)] to study the dynamics of rigid elastic bodies made
up of different spheres hold together by rigid bonds. Each dimer consists of
two hard disks of diameter , whose centers are separated by a fixed distance
. By describing the rigid bonds by means of holonomic constraints and
deriving the appropriate collision rules between dimers, we reduce the dynamics
to a set of equations which can be solved by means of event driven simulation.
After deriving the algorithm we study the decay of the total kinetic energy,
and of the ratio between the rotational and the translational kinetic energy of
inelastic dimers. We show numerically that the celebrated Haff's homogeneous
cooling law , describing how the kinetic energy of an inelastic hard
sphere system with constant coefficient of restitution decreases in time, holds
even in the case of these non spherical particles. We fully characterize this
homogeneous decay process in terms of appropriate decay constants and confirm
numerically the scaling behavior of the velocity distributions.Comment: 21 pages, 6 figures and 2 tables, submitted to JC
Cholesterol impairment contributes to neuroserpin aggregation
Intraneural accumulation of misfolded proteins is a common feature of several
neurodegenerative pathologies including Alzheimer's and Parkinson's diseases,
and Familial Encephalopathy with Neuroserpin Inclusion Bodies (FENIB). FENIB is
a rare disease due to a point mutation in neuroserpin which accelerates protein
aggregation in the endoplasmic reticulum (ER). Here we show that cholesterol
depletion induced either by prolonged exposure to statins or by inhibiting the
sterol regulatory binding-element protein (SREBP) pathway also enhances
aggregation of neuroserpin proteins. These findings can be explained
considering a computational model of protein aggregation under non-equilibrium
conditions, where a decrease in the rate of protein clearance improves
aggregation. Decreasing cholesterol in cell membranes affects their biophysical
properties, including their ability to form the vesicles needed for protein
clearance, as we illustrate by a simple mathematical model. Taken together,
these results suggest that cholesterol reduction induces neuroserpin
aggregation, even in absence of specific neuroserpin mutations. The new
mechanism we uncover could be relevant also for other neurodegenerative
diseases associated with protein aggregation.Comment: 7 figure
The inelastic Takahashi hard-rod gas
We study a one-dimensional fluid of hard-rods interacting each other via
binary inelastic collisions and a short ranged square-well potential. Upon
tuning the depth and the sign of the well, we investigate the interplay between
dissipation and cohesive or repulsive forces. Molecular dynamics simulations of
the cooling regime indicate that the presence of this simple interparticle
interaction is sufficient to significantly modify the energy dissipation rates
expected by the Haff's law for the free cooling. The simplicity of the model
makes it amenable to an analytical approach based on the Boltzmann-Enskog
transport equation which allows deriving the behaviour of the granular
temperature. Furthermore, in the elastic limit, the model can be solved exactly
to provide a full thermodynamic description. A meaningful theoretical
approximation explaining the properties of the inelastic system in interaction
with a thermal bath can be directly extrapolated from the properties of the
corresponding elastic system, upon a proper re-definition of the relevant
observables. Simulation results both in the cooling and driven regime can be
fairly interpreted according to our theoretical approach and compare rather
well to our predictions.Comment: 14 pages RevTex, 9 eps figure
A functional perspective on personality
Personality psychology has made enormous progresses over the years by accumulating empirical evidence on how patterns of stable individual differences in behaviours can be clustered systematically at different levels of abstraction (i.e. traits and facets) and how they can predict important consequential outcomes. At the same time, functionally orientated researchers have accumulated a vast body of knowledge on environment-behaviour relations and the underlying behavioural principles, that is, abstract descriptions of the way in which behaviour is a function of elements in the past and present environment. We explore a functional perspective on personality that attempts to bridge the two domains and to exploit the best of both worlds. From this functional perspective, personality refers to the impact of the individual on different types of environment-behaviour relations as well as on the way other factors moderate those relations. We discuss the potential of this functional perspective on personality to organise existing scientific knowledge and inspire future research
Mental disorders as complex networks:An introduction and overview of a network approach to psychopathology
Mental disorders have traditionally been conceptualized as latent variables, which impact observable symptomatology. Recent alternative approaches, however, view mental disorders as systems of mutually reinforcing symptoms, and utilize network models to analyze the structure of these symptom-symptom interactions. This paper gives an introduction to and overview of the network approach to psychopathology, as it has developed over the past years
String ratchets: ac driven asymmetric kinks.
We simulated numerically the time evolution of a one-kink bearing, damped elastic string sitting on noiseless periodic substrates of two types: (I) asymmetric, time independent, (II) symmetric, periodically deformable. An asymmetric kink subjected to an ac drive is shown to drift steadily with finite average speed independent of its initial kinetic conditions. In the overdamped regime the resulting net kink transport can be attributed to the rectification of the Brownian motion of a pointlike particle with oscillating mass. For intermediate to low damping completely different features show up, due to the finite size of the objects being transported; in particular, the kink current hits a maximum for an optimal value of the damping constant, resonates at the kink internal-mode frequency and, finally, reverses sign within a certain range of the drive parameters
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