Papers
Topics
Authors
Recent
Search
2000 character limit reached

Topological conditions drive stability in meta-ecosystems

Published 8 May 2024 in q-bio.PE and cond-mat.dis-nn | (2405.05390v2)

Abstract: On a global level, ecological communities are being perturbed at an unprecedented rate by human activities and environmental instabilities. Yet, we understand little about what factors facilitate or impede long-term persistence of these communities. While observational studies indicate that increased biodiversity must, somehow, be driving stability, theoretical studies have argued the exact opposite viewpoint instead. This encouraged many researchers to participate in the ongoing diversity-stability debate. Within this context, however, there has been a severe lack of studies that consider spatial features explicitly, even though nearly all habitats are spatially embedded. To this end, we study here the linear stability of meta-ecosystems on networks that describe how discrete patches are connected by dispersal between them. By combining results from random-matrix theory and network theory, we are able to show that there are three distinct features that underlie stability: edge density, tendency to triadic closure, and isolation or fragmentation. Our results appear to further indicate that network sparsity does not necessarily reduce stability, and that connections between patches are just as, if not more, important to consider when studying the stability of large ecological systems.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (44)
  1. H. P. Jones and O. J. Schmitz, Rapid Recovery of Damaged Ecosystems, PLOS ONE 4, e5653 (2009).
  2. R. M. May, Will a Large Complex System be Stable?, Nature 238, 413 (1972).
  3. S. Allesina and S. Tang, Stability criteria for complex ecosystems, Nature 483, 205 (2012).
  4. S. Allesina and S. Tang, The stability–complexity relationship at age 40: A random matrix perspective, Popul Ecol 57, 63 (2015).
  5. J. Grilli, T. Rogers, and S. Allesina, Modularity and stability in ecological communities, Nat Commun 7, 12031 (2016).
  6. S. Pettersson, V. M. Savage, and M. N. Jacobi, Stability of ecosystems enhanced by species-interaction constraints, Phys. Rev. E 102, 062405 (2020).
  7. A. B. Franklin, B. R. Noon, and T. L. George, What is habitat fragmentation?, Studies in avian biology 25, 20 (2002).
  8. L. J. Gilarranz and J. Bascompte, Spatial network structure and metapopulation persistence, Journal of Theoretical Biology 297, 11 (2012).
  9. D. Gravel, F. Massol, and M. A. Leibold, Stability and complexity in model meta-ecosystems, Nat Commun 7, 12457 (2016).
  10. J. W. Baron and T. Galla, Dispersal-induced instability in complex ecosystems, Nat Commun 11, 6032 (2020).
  11. S. Pettersson and M. N. Jacobi, Spatial heterogeneity enhance robustness of large multi-species ecosystems, PLOS Computational Biology 17, e1008899 (2021).
  12. G. Garcia Lorenzana, A. Altieri, and G. Biroli, Interactions and Migration Rescuing Ecological Diversity, PRX Life 2, 013014 (2024).
  13. I. Hanski and O. Ovaskainen, The metapopulation capacity of a fragmented landscape, Nature 404, 755 (2000).
  14. G. M. Viswanathan, E. P. Raposo, and M. G. E. da Luz, Lévy flights and superdiffusion in the context of biological encounters and random searches, Physics of Life Reviews 5, 133 (2008).
  15. L. Stone, The feasibility and stability of large complex biological networks: A random matrix approach, Sci Rep 8, 8246 (2018).
  16. S. Allesina and J. Grilli, Models for large ecological communities—a random matrix approach, in Theoretical Ecology: Concepts and Applications, edited by K. S. McCann and G. Gellner (Oxford University Press, 2020) p. 0.
  17. T. Tao, V. Vu, and M. Krishnapur, Random matrices: Universality of ESDs and the circular law, The Annals of Probability 38, 2023 (2010).
  18. G. Barabás, M. J. Michalska-Smith, and S. Allesina, Self-regulation and the stability of large ecological networks, Nat Ecol Evol 1, 1870 (2017).
  19. L. J. Gilarranz, Generic Emergence of Modularity in Spatial Networks, Sci Rep 10, 8708 (2020).
  20. J. Grilli, G. Barabás, and S. Allesina, Metapopulation Persistence in Random Fragmented Landscapes, PLOS Computational Biology 11, e1004251 (2015).
  21. M. E. J. Newman, Random Graphs with Clustering, Phys. Rev. Lett. 103, 058701 (2009).
  22. M. Newman, Networks (Oxford University Press, 2018).
  23. A. Ghavasieh and M. De Domenico, Diversity of information pathways drives sparsity in real-world networks, Nat. Phys. , 1 (2024).
  24. H. M. Kurkjian, The Metapopulation Microcosm Plate: A modified 96-well plate for use in microbial metapopulation experiments, Methods in Ecology and Evolution 10, 162 (2019).
  25. C. D. Larsen and A. L. Hargreaves, Miniaturizing landscapes to understand species distributions, Ecography 43, 1625 (2020).
  26. D. J. Watts and S. H. Strogatz, Collective dynamics of ‘small-world’ networks, Nature 393, 440 (1998).
  27. I. Hanski, Metapopulation dynamics, Nature 396, 41 (1998).
  28. D. Mouillot, Niche-Assembly vs. Dispersal-Assembly Rules in Coastal Fish Metacommunities: Implications for Management of Biodiversity in Brackish Lagoons, Journal of Applied Ecology 44, 760 (2007), 4539295 .
  29. L. H. L. Loke and R. A. Chisholm, Unveiling the transition from niche to dispersal assembly in ecology, Nature 618, 537 (2023).
  30. P. L. Wennekes, J. Rosindell, and R. S. Etienne, The Neutral—Niche Debate: A Philosophical Perspective, Acta Biotheor 60, 257 (2012).
  31. J. Dall and M. Christensen, Random geometric graphs, Phys. Rev. E 66, 016121 (2002).
  32. C. Herrmann, M. Barthélemy, and P. Provero, Connectivity distribution of spatial networks, Phys. Rev. E 68, 026128 (2003).
  33. H. Althagafi and S. Petrovskii, Metapopulation Persistence and Extinction in a Fragmented Random Habitat: A Simulation Study, Mathematics 9, 2202 (2021).
  34. A. M. Turing, The chemical basis of morphogenesis, Bltn Mathcal Biology 52, 153 (1990).
  35. J. A. Dunne, R. J. Williams, and N. D. Martinez, Food-web structure and network theory: The role of connectance and size, Proceedings of the National Academy of Sciences 99, 12917 (2002).
  36. S. Allesina and M. Pascual, Food web models: A plea for groups, Ecology Letters 12, 652 (2009).
  37. L. Poley, J. W. Baron, and T. Galla, Generalized Lotka-Volterra model with hierarchical interactions, Phys. Rev. E 107, 024313 (2023a).
  38. S. Tang and S. Allesina, Reactivity and stability of large ecosystems, Frontiers in Ecology and Evolution 2 (2014).
  39. S. Janson, On Edge Exchangeable Random Graphs, J Stat Phys 173, 448 (2018).
  40. M. E. J. Newman, S. H. Strogatz, and D. J. Watts, Random graphs with arbitrary degree distributions and their applications, Phys. Rev. E 64, 026118 (2001).
  41. M. E. J. Newman, Properties of highly clustered networks, Phys. Rev. E 68, 026121 (2003).
  42. M. E. J. Newman and D. J. Watts, Scaling and percolation in the small-world network model, Phys. Rev. E 60, 7332 (1999).
  43. E. Barter and T. Gross, Spatial effects in meta-foodwebs, Sci Rep 7, 9980 (2017).
  44. W. E. Arnoldi, The principle of minimized iterations in the solution of the matrix eigenvalue problem, Quart. Appl. Math. 9, 17 (1951).

Summary

No one has generated a summary of this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Summarize

Paper to Video (Beta)

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Generate

Continue Learning

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Collections

Sign up for free to add this paper to one or more collections.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up

Tweets

Sign up for free to view the 3 tweets with 14 likes about this paper.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up for Free