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Which species distribution models are more (or less) likely to project broad-scale, climate-induced shifts in species ranges?

Author

Listed:
  • Beaumont, Linda J.
  • Graham, Erin
  • Duursma, Daisy Englert
  • Wilson, Peter D.
  • Cabrelli, Abigail
  • Baumgartner, John B.
  • Hallgren, Willow
  • Esperón-Rodríguez, Manuel
  • Nipperess, David A.
  • Warren, Dan L.
  • Laffan, Shawn W.
  • VanDerWal, Jeremy

Abstract

Species distribution models (SDMs) frequently project substantial declines in the spatial extent of climatically suitable habitat in response to scenarios of future climate change. Such projections are highly disconcerting. Yet, considerable variation can occur in the direction and magnitude of range changes projected by different SDM methods, even when predictive performance is similar. In this study, we assessed whether particular methods have a tendency to predict substantial loss or gain of suitable habitat. In particular, we asked, “are 14 SDM methods equally likely to predict extreme changes to the future extent of suitable habitat for 220 Australian mammal species?”. We defined five non-mutually exclusive categories of ‘extreme’ change, based on stability or loss of current habitat, or the dislocation of current and future habitat: a) no future habitat (range extinction); b) low stability of current habitat (≤10% remains); c) no gain of habitat in new locations; d) all future habitat is in new locations (i.e. completely displaced from current habitat); and e) substantial increase in size of habitat (future habitat is ≥100% larger than current). We found that some SDM methods were significantly more likely than others to predict extreme changes. In particular, distance-based models were significantly less likely than other methods to predict substantial increases in habitat size; Random Forest models and Surface Range Envelopes were significantly more likely to predict a complete loss of current habitat, and future range extinction. Generalised Additive Models and Generalised Linear Models rarely predicted range extinction; future habitat completely disjunct from current habitat was predicted more frequently than expected by Classification Tree Analysis and less frequently by Maxent. Random Forest generally predicted extreme range changes more frequently than other SDM methods. Our results identify trends among different methods with respect to tendency to predict extreme range changes. These are of significance for climate-impact assessments, with implications for transferability of models to novel environments. Our findings emphasise the need to explore and justify the use of different models and their parameterisations, and to develop approaches to assist with optimisation of models.

Suggested Citation

  • Beaumont, Linda J. & Graham, Erin & Duursma, Daisy Englert & Wilson, Peter D. & Cabrelli, Abigail & Baumgartner, John B. & Hallgren, Willow & Esperón-Rodríguez, Manuel & Nipperess, David A. & Warren, , 2016. "Which species distribution models are more (or less) likely to project broad-scale, climate-induced shifts in species ranges?," Ecological Modelling, Elsevier, vol. 342(C), pages 135-146.
    • Handle: RePEc:eee:ecomod:v:342:y:2016:i:c:p:135-146
    DOI: 10.1016/j.ecolmodel.2016.10.004
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    1. John Harte & Annette Ostling & Jessica L. Green & Ann Kinzig, 2004. "Climate change and extinction risk," Nature, Nature, vol. 430(6995), pages 34-34, July.
    2. Crimmins, Shawn M. & Dobrowski, Solomon Z. & Mynsberge, Alison R., 2013. "Evaluating ensemble forecasts of plant species distributions under climate change," Ecological Modelling, Elsevier, vol. 266(C), pages 126-130.
    3. Watling, James I. & Brandt, Laura A. & Bucklin, David N. & Fujisaki, Ikuko & Mazzotti, Frank J. & Romañach, Stephanie S. & Speroterra, Carolina, 2015. "Performance metrics and variance partitioning reveal sources of uncertainty in species distribution models," Ecological Modelling, Elsevier, vol. 309, pages 48-59.
    4. repec:asg:wpaper:1015 is not listed on IDEAS
    5. Guo, Chuanbo & Lek, Sovan & Ye, Shaowen & Li, Wei & Liu, Jiashou & Li, Zhongjie, 2015. "Uncertainty in ensemble modelling of large-scale species distribution: Effects from species characteristics and model techniques," Ecological Modelling, Elsevier, vol. 306(C), pages 67-75.
    6. Chris D. Thomas & Alison Cameron & Rhys E. Green & Michel Bakkenes & Linda J. Beaumont & Yvonne C. Collingham & Barend F. N. Erasmus & Marinez Ferreira de Siqueira & Alan Grainger & Lee Hannah & Lesle, 2004. "Extinction risk from climate change," Nature, Nature, vol. 427(6970), pages 145-148, January.
    7. Giovanni Rapacciuolo & David B Roy & Simon Gillings & Richard Fox & Kevin Walker & Andy Purvis, 2012. "Climatic Associations of British Species Distributions Show Good Transferability in Time but Low Predictive Accuracy for Range Change," PLOS ONE, Public Library of Science, vol. 7(7), pages 1-11, July.
    8. R. Warren & J. VanDerWal & J. Price & J. A. Welbergen & I. Atkinson & J. Ramirez-Villegas & T. J. Osborn & A. Jarvis & L. P. Shoo & S. E. Williams & J. Lowe, 2013. "Quantifying the benefit of early climate change mitigation in avoiding biodiversity loss," Nature Climate Change, Nature, vol. 3(7), pages 678-682, July.
    9. Richard H. Moss & Jae A. Edmonds & Kathy A. Hibbard & Martin R. Manning & Steven K. Rose & Detlef P. van Vuuren & Timothy R. Carter & Seita Emori & Mikiko Kainuma & Tom Kram & Gerald A. Meehl & John F, 2010. "The next generation of scenarios for climate change research and assessment," Nature, Nature, vol. 463(7282), pages 747-756, February.
    10. Moreno-Amat, Elena & Mateo, Rubén G. & Nieto-Lugilde, Diego & Morueta-Holme, Naia & Svenning, Jens-Christian & García-Amorena, Ignacio, 2015. "Impact of model complexity on cross-temporal transferability in Maxent species distribution models: An assessment using paleobotanical data," Ecological Modelling, Elsevier, vol. 312(C), pages 308-317.
    11. Oecd, 2009. "Climate Change and Africa," OECD Journal: General Papers, OECD Publishing, vol. 2009(1), pages 5-35.
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    2. Yen Pham & Kathryn Reardon-Smith & Shahbaz Mushtaq & Geoff Cockfield, 2019. "The impact of climate change and variability on coffee production: a systematic review," Climatic Change, Springer, vol. 156(4), pages 609-630, October.
    3. Coppée, Thomas & Paquet, Jean-Yves & Titeux, Nicolas & Dufrêne, Marc, 2022. "Temporal transferability of species abundance models to study the changes of breeding bird species based on land cover changes," Ecological Modelling, Elsevier, vol. 473(C).
    4. Hallgren, W. & Santana, F. & Low-Choy, S. & Zhao, Y. & Mackey, B., 2019. "Species distribution models can be highly sensitive to algorithm configuration," Ecological Modelling, Elsevier, vol. 408(C), pages 1-1.
    5. Kolluru, Venkatesh & John, Ranjeet & Saraf, Sakshi & Chen, Jiquan & Hankerson, Brett & Robinson, Sarah & Kussainova, Maira & Jain, Khushboo, 2023. "Gridded livestock density database and spatial trends for Kazakhstan," EconStor Open Access Articles and Book Chapters, ZBW - Leibniz Information Centre for Economics, vol. 10, pages 1-15.
    6. Sabira Sultana & John B Baumgartner & Bernard C Dominiak & Jane E Royer & Linda J Beaumont, 2020. "Impacts of climate change on high priority fruit fly species in Australia," PLOS ONE, Public Library of Science, vol. 15(2), pages 1-19, February.

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