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Synchrony and second-order spatial correlation in host–parasitoid systems

  1. Ottar N. Bjørnstad1,*,
  2. Jordi Bascompte2

Article first published online: 26 MAR 2002

DOI: 10.1046/j.0021-8790.2001.00560.x

Issue

Journal of Animal Ecology

Journal of Animal Ecology

Volume 70, Issue 6, pages 924–933, November 2001

Additional Information

How to Cite

Bjørnstad, O. N. and Bascompte, J. (2001), Synchrony and second-order spatial correlation in host–parasitoid systems. Journal of Animal Ecology, 70: 924–933. doi: 10.1046/j.0021-8790.2001.00560.x

Author Information

  1. 1

    Departments of Entomology and Biology, 501 ASI Building, Penn State University, University Park, PA 16802, USA; and

  2. 2

    Estación Biológica de Doñana, CSIC. Apdo. 1056, E-41080 Sevilla, Spain

* Ottar N. Bjørnstad, Department of Entomology, 501 ASI Building, Penn State University, University Park, PA 16802, USA (e-mail onb1@psu.edu).

Publication History

  1. Issue published online: 26 MAR 2002
  2. Article first published online: 26 MAR 2002
  3. Received 6 February 2001; revision received 1 June 2001

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Keywords:

  • coupled map lattice models;
  • cross-correlation;
  • non-parametric covariance function;
  • reaction–diffusion;
  • spatial dynamics

Summary

  • 1
    Recent theoretical studies on population synchrony have focused on the role of dispersal, environmental correlation and density dependence in single species. Trophic interactions have received less attention. We explored how trophic interactions affect spatial synchrony.
  • 2
    We considered a host–parasitoid coupled map lattice to understand how the self-organizing spatial patterns generated by such dynamics affect synchrony. In particular, we calculated the spatial correlation functions (SCF) associated with travelling waves, spatial chaos and crystal lattices.
  • 3
    Travelling waves were associated with cyclic SCF (called second-order SCF) that differed greatly from those seen in spatial chaos or crystal lattices. Such U-shaped patterns of spatial synchrony, which have not been predicted by single-species models, have been reported recently in real data. Thus, the shape of the SCF can provide a test for trophically generated spatiotemporal dynamics.
  • 4
    We also calculated the cross-correlation function between the parasitoid and the host. Relatively high parasitoid mobility resulted in high within-patch synchrony of the dynamics of the two species. However, with relatively high host mobility, the parasitoid dynamics began to lag spatially behind those of the host.
  • 5
    We speculated that this spatial lag between the host and parasitoid is the ultimate source of travelling waves, because the spatial cross-correlation in turn affects host dynamics.
  • 6
    A new method to estimate the spatial cross-correlation function between two species was developed as an integral part of the study.
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