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Abstract
The interest in non-Markovian dynamics within the complex systems community has recently blossomed, due to a new wealth of time-resolved data pointing out the bursty dynamics of many natural and human interactions, manifested in an inter-event time between consecutive interactions showing a heavy-tailed distribution. In particular, empirical data has shown that the bursty dynamics of temporal networks can have deep consequences on the behavior of the dynamical processes running on top of them. Here, we study the case of random walks, as a paradigm of diffusive processes, unfolding on temporal networks generated by a non-Poissonian activity driven dynamics. We derive analytic expressions for the steady state occupation probability and first passage time distribution in the infinite network size and strong aging limits, showing that the random walk dynamics on non-Markovian networks are fundamentally different from what is observed in Markovian networks. We found a particularly surprising behavior in the limit of diverging average inter-event time, in which the random walker feels the network as homogeneous, even though the activation probability of nodes is heterogeneously distributed. Our results are supported by extensive numerical simulations. We anticipate that our findings may be of interest among the researchers studying non-Markovian dynamics on time-evolving complex topologies.
Highlights
Temporal networks [1, 2] constitute a recent new description of complex systems, that, moving apart from the classical static paradigm of network science [3], in which nodes and edges do not change in time, consider dynamic connections that can be created, destroyed or rewired at different time scales
We present the application of this formalism for the standard Poissonian activity driven model in section 4, recovering previously known results, which are in stark contrast with those obtained for the non-Markovian non-Poissoinan activity driven (NoPAD) model
In this paper we have explored the behavior of a passive node-centric random walk unfolding on nonMarkovian temporal networks generated by the NoPAD model, which considers a power-law form yc (t ) ~-1-a of the inter-event time distribution between consecutive activation events of nodes with activity c
Summary
Empirical data has shown that the bursty dynamics attribution to the author(s) and the title of of temporal networks can have deep consequences on the behavior of the dynamical processes the work, journal citation running on top of them. We derive analytic expressions for the steady state occupation probability and first passage time distribution in the infinite network size and strong aging limits, showing that the random walk dynamics on non-. We found a surprising behavior in the limit of diverging average inter-event time, in which the random walker feels the network as homogeneous, even though the activation probability of nodes is heterogeneously distributed. We anticipate that our findings may be of interest among the researchers studying non-Markovian dynamics on time-evolving complex topologies
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