The critical contact process on a homogeneous tree

Gregory J. Morrow; Rinaldo B. Schinazi; Yu Zhang

doi:10.2307/3215251

Abstract

We prove that the expected number of particles of the critical contact process on a homogeneous tree is bounded above. This is the first graph for which the behavior of the expected number of particles of the critical contact process is known. As an easy corollary of our result we get that the critical contact process dies out on any homogeneous tree. This completes the work of Pemantle (1992).

References

Bezuidenhout, C. and Grimmett, G. (1990) The critical contact process dies out. Ann. Prob. 18, 1462–1482.Google Scholar

Durrett, R. (1988) Lecture Notes on Particle Systems and Percolation. Wadsworth and Brooks Cole, Menlo Park, CA.Google Scholar

Durrett, R. (1991) Probability: Theory and Examples. Wadsworth and Brooks Cole, Menlo Park, CA.Google Scholar

Liggett, T. (1985) Interacting Particle Systems. Springer-Verlag, New York.Google Scholar

Madras, N. and Schinazi, R. (1992) Branching random walks on trees. Stoch. Proc. Appl. 42, 255–267.Google Scholar

Morrow, G. Schinazi, R. and Zhang, Y. (1992) Continuity of the survival probability for the contact process on a tree. Unpublished manuscript.Google Scholar

Pemantle, R. (1992) The contact process on trees. Ann. Prob. 20, 2089–2116.CrossRef Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Liggett, Thomas M. 1996. Multiple transition points for the contact process on the binary tree. The Annals of Probability, Vol. 24, Issue. 4,

Stacey, A. M. 1996. The existence of an intermediate phase for the contact process on trees. The Annals of Probability, Vol. 24, Issue. 4,

Salzano, Marcia and Schonmann, Roberto H. 1997. The second lowest extremal invariant measure of the contact process. The Annals of Probability, Vol. 25, Issue. 4,

Wu, C. Chris 1997. Inhomogeneous contact processes on trees. Journal of Statistical Physics, Vol. 88, Issue. 5-6, p. 1399.

Liggett, Thomas M. 1997. Stochastic models of interacting systems. The Annals of Probability, Vol. 25, Issue. 1,

Newman, Charles M. and Wu, C. Chris 1997. Percolation and contact processes with low-dimensional inhomogeneity. The Annals of Probability, Vol. 25, Issue. 4,

Salzano, Marcia and Schonmann, Roberto H. 1998. A new proof that for the contact process on homogeneous trees local survival implies complete convergence. The Annals of Probability, Vol. 26, Issue. 3,

Liggett, Thomas M. 1999. Stochastic Interacting Systems: Contact, Voter and Exclusion Processes. Vol. 324, Issue. , p. 31.

Schonmann, Roberto H. 1999. Perplexing Problems in Probability. p. 53.

Salzano, Marcia and Schonmann, Roberto H. 1999. The Second Lowest Extremal Invariant Measure of the Contact Process II. The Annals of Probability, Vol. 27, Issue. 2,

Lyons, Russell 2000. Phase transitions on nonamenable graphs. Journal of Mathematical Physics, Vol. 41, Issue. 3, p. 1099.

Lalley, Steven P. and Sellke, Thomas M. 2002. Anisotropic contact processes on homogeneous trees. Stochastic Processes and their Applications, Vol. 101, Issue. 2, p. 163.

Durrett, Rick and Jung, Paul 2007. Two phase transitions for the contact process on small worlds. Stochastic Processes and their Applications, Vol. 117, Issue. 12, p. 1910.

Swart, Jan M. 2009. The Contact Process Seen from a Typical Infected Site. Journal of Theoretical Probability, Vol. 22, Issue. 3, p. 711.

Gollo, Leonardo L. Kinouchi, Osame and Copelli, Mauro 2012. Statistical physics approach to dendritic computation: The excitable-wave mean-field approximation. Physical Review E, Vol. 85, Issue. 1,

Varghese, Chris and Durrett, Rick 2013. Phase transitions in the quadratic contact process on complex networks. Physical Review E, Vol. 87, Issue. 6,

Schinazi, Rinaldo B. 2014. Classical and Spatial Stochastic Processes. p. 251.

Lalley, Steven and Su, Wei 2017. Contact processes on random regular graphs. The Annals of Applied Probability, Vol. 27, Issue. 4,

Mu, Y. X. and Zhang, Y. 2020. On some threshold-one attractive interacting particle systems on homogeneous trees. Journal of Applied Probability, Vol. 57, Issue. 3, p. 866.

Article contents

The critical contact process on a homogeneous tree

Abstract

Keywords

MSC classification

Access options

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The critical contact process on a homogeneous tree

Abstract

Keywords

MSC classification

Access options

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests