A Global Habitat/Migration Model For Gray Whales

Introduction

Historically, the gray whale (Eschrichtius robustus) once occupied northern Pacific and northern Atlantic oceanic territories, but for the past several hundred years they have been extinct in the Atlantic. Habitat suitability modeling can be used to predict the potential habitat for a species by observing species’ presence locations and correlating them with environmental variables. A new modeling technique was used to predict the potential habitat of gray whales throughout the northern hemisphere by using observational data available from sightings along the eastern Pacific coast of North America. The model shows potential continuous habitat for gray whales along the coasts of northern Asia, eastern North America, and from Europe to northern Africa. Area under the curve (AUC) values ranged from 0.93 to 0.99. Future refinements could include new recent and historical observation data, applying new environmental variables, and performing uncertainty analyses.

Separate Images Connected Habitat

Background

Gray whales (Eschrichtius robustus) are a large species of baleen whale that once inhabited the northern Pacific and Atlantic oceans. The whales were extinct in the Atlantic by the late 1700’s, but survived in the Pacific. The eastern Pacific population has recovered to over 20,000 individuals, since bans on hunting were put into place, but the western Pacific population remains at several hundred individuals. Gray whales feed primarily during the summer months in higher latitudes and migrate south to calve and mate during winter months. Feeding occurs in relatively shallow coastal waters and includes benthic and epibenthic invertebrates (Swartz et al. 2006). Potential habitat modeling (also known as species distribution modeling) can be used to identify the environmental niche that a species inhabits. These models can be used to predict the potential habitat of a species (Elith & Leathwick, 2009). There are a few models available that allow modeling based on presence only data (e.g. Phillips et al., 2006). These can be difficult to interpret based on biological theory and can be hard to visualize in environmental space (Graham, & Hijmans, 2006). Our goal was to model gray whales throughout their current and potential habitat.

Methods

Coordinates of gray whale observations were divided into months and correlated with values from two environmental predictor layers within the sample area: bathymetry and sea surface temperature. A Bezier surface was centered over the point of highest sighting occurrence density, and eight additional control points at 10% density were placed around this center point. A sigmoidal transfer function was used to create probability densities ranging from 1 (highest density) to 0 (periphery of the model). The control points for the Bezier surface where then manually positioned to optimize the AUC values while maintaining a model that matches the expected niche of gray whales.

Maps for each of the 12 months can be found below. Each map shows predicted habitat, original sample points, and an inset with the environmental space and the predicted model. These models where used to create 12 monthly northern hemisphere habitat probability maps, and then combined to create the entire northern hemisphere potential habitat map. Connectivity was assessed by applying a 20km buffer to the modeled areas and removing pockets of no overlap and isolation. The maps where then combined into a single GIF animation. The animation and individual image are available above.

Results

Occurrences in environmental space showed that gray whales prefer areas with shallow water. The potential habitat was similar in the summer and fall when gray whales feed along the large coastal shelf surrounding Alaska and, although fewer, along the coast of California. During the winter and spring, all of the observations were along the coast of the lower 48 states and Mexico, but depth of habitat varied more than during the fall and winter. The monthly models produced Area Under the Curve (AUC) values from 0.93 to 0.99 and appeared to correlate well to documented behavior of gray whales. The combined map produced potential connected habitat along the eastern and western coasts of both the Pacific and Atlantic oceans.

Separate Images

MONTH	# of Control Points	AUC value	# of Occurrences
1	4	0.996	573
2	4	0.994	267
3	4	0.993	498
4	4	0.99	106
5	4	0.983	81
6	4	0.924	62
7	4	0.957	204
8	4	0.977	252
9	4	0.965	116
10	4	0.937	32
11	4	0.99	19
12	4	0.962	46

Conclusion

The model shows gray whale potential habitat throughout their existing and historical range. The Hudson Bay and the Barents sea are not documented as gray whale habitat, but these seem plausible. While the model produces a reasonable map of potential gray whale habitat, additional data should be compiled and further modeling performed to refine the model results. This type of modeling is potentially important to evaluate areas for management of gray whales and can be extended to include climate change scenarios.

References

Elith, J. & Leathwick, J.R. (2009) Species distribution models: Ecological explanation and prediction across space and time. Annual Review of Ecology Evolution and Systematics, 40:677-697
Graham, C.H. & Hijmans, R.J. (2006) A comparison of methods for mapping species ranges and species richness. Global Ecology and Biogeography, 15:578-587
Phillips, S.J., Anderson, R.P. & Schapire, R.E. (2006) Maximum entropy modeling of species geographic distributions. Ecological Modelling, 190:231-259
Swartz, S.L., B.L. Taylor, & D.J. Rugh. (2006) Gray whale Eschrichtius robustus population and stock identity. Mammal Review, 36:66-84.

Acknowledgements

The National Science Foundation grant #OCI-0636210 and the United States Geological Survey provided funding for this project while the International Biological Information System (ibis.colostate.edu) at Colorado State University provided logistic and technical support.