In this paper we introduce a description of the equilibrium state of a bond percolation process on random graphs using the exact method of generating functions. This allows us to find the expected size of the giant connected component (GCC) of two sequential bond percolation processes in which the bond occupancy probability of the second process is modulated (increased or decreased) by a node being inside or outside of the GCC created by the first process. In the context of epidemic spreading this amounts to both an antagonistic partial immunity and a synergistic partial coinfection interaction between the two sequential diseases. We examine configuration model networks with tunable clustering. We find that the emergent evolutionary behavio...
We consider cumulative merging percolation (CMP), a long-range percolation process describing the it...
We present a bond percolation model for community clustered networks with an arbitrarily specified j...
We introduce a new 1-dependent percolation model to describe and analyze the spread of an epidemic o...
In this paper we introduce a description of the equilibrium state of a bond percolation process on r...
In this paper we examine the structure of random networks that have undergone bond percolation an ar...
We investigate the effects of heterogeneous and clustered contact patterns on the timescale and fina...
The interaction between multiple pathogens spreading on networks connecting a given set of nodes pre...
Networks provide a mathematically rich framework to represent social contacts sufficient for the tra...
We introduce a formalism for computing bond percolation properties of a class of correlated and clus...
Considerable attention has been paid, in recent years, to the use of networks in modeling complex re...
Coinfection is the process by which a host that is infected with a pathogen becomes infected by a se...
peer-reviewedMany of the systems we observe in nature, in societies, or in infrastructures are in th...
The size and shape of the region affected by an outbreak is relevant to under stand the dynamics of ...
The spread of infectious diseases fundamentally depends on the pattern of contacts between individua...
While disease propagation is a main focus of network science, its coevolution with treatment has yet...
We consider cumulative merging percolation (CMP), a long-range percolation process describing the it...
We present a bond percolation model for community clustered networks with an arbitrarily specified j...
We introduce a new 1-dependent percolation model to describe and analyze the spread of an epidemic o...
In this paper we introduce a description of the equilibrium state of a bond percolation process on r...
In this paper we examine the structure of random networks that have undergone bond percolation an ar...
We investigate the effects of heterogeneous and clustered contact patterns on the timescale and fina...
The interaction between multiple pathogens spreading on networks connecting a given set of nodes pre...
Networks provide a mathematically rich framework to represent social contacts sufficient for the tra...
We introduce a formalism for computing bond percolation properties of a class of correlated and clus...
Considerable attention has been paid, in recent years, to the use of networks in modeling complex re...
Coinfection is the process by which a host that is infected with a pathogen becomes infected by a se...
peer-reviewedMany of the systems we observe in nature, in societies, or in infrastructures are in th...
The size and shape of the region affected by an outbreak is relevant to under stand the dynamics of ...
The spread of infectious diseases fundamentally depends on the pattern of contacts between individua...
While disease propagation is a main focus of network science, its coevolution with treatment has yet...
We consider cumulative merging percolation (CMP), a long-range percolation process describing the it...
We present a bond percolation model for community clustered networks with an arbitrarily specified j...
We introduce a new 1-dependent percolation model to describe and analyze the spread of an epidemic o...