Caterina Scoglio scite author profile

Electric power-systems are one of the most important critical infrastructures. In recent years, they have been exposed to extreme stress due to the increasing demand, the introduction of distributed renewable energy sources, and the development of extensive interconnections. We investigate the phenomenon of abrupt breakdown of an electric power-system under two scenarios: load growth (mimicking the ever-increasing customer demand) and power fluctuations (mimicking the effects of renewable sources). Our results on real, realistic and synthetic networks indicate that increasing the system size causes breakdowns to become more abrupt; in fact, mapping the system to a solvable statistical-physics model indicates the occurrence of a first order transition in the large size limit. Such an enhancement for the systemic risk failures (black-outs) with increasing network size is an effect that should be considered in the current projects aiming to integrate national power-grids into “super-grids”.

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On the existence of a threshold for preventive behavioral responses to suppress epidemic spreading

Sahneh

Chowdhury

Scoglio

2012

Sci Rep

137

125

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The spontaneous behavioral responses of individuals to the progress of an epidemic are recognized to have a significant impact on how the infection spreads. One observation is that, even if the infection strength is larger than the classical epidemic threshold, the initially growing infection can diminish as the result of preventive behavioral patterns adopted by the individuals. In order to investigate such dynamics of the epidemic spreading, we use a simple behavioral model coupled with the individual-based SIS epidemic model where susceptible individuals adopt a preventive behavior when sensing infection. We show that, given any infection strength and contact topology, there exists a region in the behavior-related parameter space such that infection cannot survive in long run and is completely contained. Several simulation results, including a spreading scenario in a realistic contact network from a rural district in the State of Kansas, are presented to support our analytical arguments.

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An individual-based approach to SIR epidemics in contact networks

Youssef

Scoglio

2011

Journal of Theoretical Biology

140

112

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Predicting the Impact of Biocorona Formation Kinetics on Interspecies Extrapolations of Nanoparticle Biodistribution Modeling

Sahneh

Scoglio

Monteiro‐Riviere

et al. 2014

Nanomedicine (Lond.)

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A network-based meta-population approach to model Rift Valley fever epidemics

Xue

Scott

Cohnstaedt

et al. 2012

Journal of Theoretical Biology

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