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Models of First-Passage Percolation

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Probability on Discrete Structures

Part of the book series: Encyclopaedia of Mathematical Sciences ((EMS,volume 110))

Abstract

First-passage percolation (FPP) was introduced by Hammersley and Welsh in 1965 (see [26]) as a model of fluid flow through a randomly porous material. Envision a fluid injected into the material at a fixed site: as time elapses, the portion of the material that is wet expands in a manner that is a complicated function of the material’s random structure. In the standard FPP model, the spatial randomness of the material is represented by a family of non-negative i.i.d. random variables indexed by the nearest neighbor edges of the Z d lattice. (We take d ≥ 2 throughout this chapter.) If edge e has endpoints u, vZ d (so |uv| = 1, where | · | denotes the usual Euclidean norm) then the associated quantity τ(e) represents the time it takes fluid to flow from site u to site v, or the reverse, along the edge e. If the sequence of edges r = (e 1,..., e n ) forms a path from uZ d to vZ d, then T(r) ≡ ∑ i τ(e i ) represents the time it takes fluid to flow from u to v along the path r. For any u, vZ d, we further define the passage time from u to v as

$$T\left( {u,v} \right) \equiv \inf \left\{ {T\left( r \right):the\,edgesinrformapathfromutov} \right\}.$$
(1.1)

Research supported by NSF Grant DMS-02-03943.

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  1. Cornell University Department of Mathematics, Malott Hall 310, 14853-4201, Ithaca, NY, USA

    Harry Kesten

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Howard, C.D. (2004). Models of First-Passage Percolation. In: Kesten, H. (eds) Probability on Discrete Structures. Encyclopaedia of Mathematical Sciences, vol 110. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-09444-0_3

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