Why do pilot whales sometimes crash-land ashore?

Why do pilot whales sometimes crash-land ashore?

This week David Hocking, Research Fellow at Australia’s School of Biological Sciences, Monash University, and our Curator Vertebrates Felix Marx wrote the following short article for Monash Lens, the University’s in-house journal, on the ongoing pilot whale mass stranding in Tasmania. It is reprinted here in its entirety. 

A pilot whale stranded on a beach with the ocean in the foreground
Pilot whale stranded on the shoreline of Macquarie Harbour. Photo by Patrick Gee, The Mercury

There is some doubt as to the reason why they [dolphins] cast themselves on the land, for they say that sometimes they appear to do this without any cause.
– Aristotle, Historia Animalium (transl. Richard Cresswell)

This week the usually quiet spot of Macquarie Harbour on Tasmania’s west coast became the scene of what may be Australia’s largest ever whale stranding. 470 long-finned pilot whales came ashore, and despite rescue efforts by volunteers and the Tasmania Parks and Wildlife Service, almost 400 of them have died.

The scale of this tragedy is heart-wrenching, yet this is not the first time that pilot whales have stranded en masse in our region. In 1918, a staggering 1,000 whales came ashore on the Chatham Islands to the east of New Zealand. In 2017, more than 400 whales stranded at Farewell Spit in New Zealand’s South Island. And in Tasmania, about 200 animals stranded on King Island in 2009.

So, what are pilot whales? And why do so many of them meet their doom ashore?

Deep-sea suckers

Despite their name and respectable body length (5–7 m), pilot whales are actually members of the dolphin family. There are two species, distinguished primarily by the length of their flippers, number of teeth, and shape of the skull. The animals that stranded in Tasmania belong to the ‘long-finned’ variety (Globicephala melas) commonly found in the North Atlantic and Southern Ocean.

Pilot whales are excellent divers and forage at depths of up to 1 km. To navigate and find food in this dark environment, they rely on a sophisticated type of biosonar known as echolocation. They primarily target squid, and tend to suck in – rather than bite – their prey.

Like many other dolphins, pilot whales are highly social. They live in stable family groups or ‘pods’ comprising 20 to 100 animals, although much larger numbers have also been recorded. Females can live past 60 years, and (based on observations on the short-finned species, Globicephala macrorhynchus) are among the few animals known to experience menopause.

People on a rescue boat heading away from the camera on the ocean
Rescuers have been using boats to survey the scene and escort survivors to deeper water. Photo by Patrick Gee, The Mercury

Do navigational errors lead these pilots ashore?

Why whales strand has perplexed observers since the days of Aristotle. In truth, there is probably no single answer. Disease and old age likely play an important role, but they cannot easily explain why pilot whales strand in such large numbers, and often in the same spot. For example, in 2009, 80 pilot whales came ashore in Hamelin Bay, Western Australia. Nine years later, another 150 whales stranded on the same beach.

Similar strandings hotspots occur elsewhere and seem to have something in common: gently sloping sandy beaches that can reflect echolocation clicks away from the animal that produced them. With no echoes returning from the beach, you could be forgiven for thinking that the area ahead of you is open water.

For oceangoing pilot whales (and other deep divers like sperm whales), this situation may quickly become confusing. Once drawn into shallows, perhaps in pursuit of food, they struggle to find their way out again. Combine this situation with natural traps like sand spits and a rapidly receding tide, and you have all the ingredients for a whale-sized disaster.

Why do so many whales strand at once?

Tragically, mass stranded pilot whales may fall victim to one of their greatest assets: strong familial ties and social bonds. When one of them gets into trouble, others stick around in an effort to stay together. Whether sick, dying or simply confused, one animal getting lost in the shallows may lead many others into danger.

Strong social ties also can hamper rescue efforts. Surprisingly, refloated whales often don’t just swim off. Instead, they turn around and head back to their family on the beach. The impulse to remain with their pod seems greater than their own survival instinct. To manage this risk, whales are often refloated and herded into deeper water in groups.

Ten people trying to move a pilot whale off the beach.
Rescuers using special equipment to safely move these heavy animals without injuring them. Photo courtesy of Tasmania Police

Is there much we can do?

Most mass strandings elicit an immediate response, and a rescue effort that may last several days. We have learnt much about how to handle the animals while on the beach, and the best techniques for returning them to sea. As of now, rescuers in Tasmania have successfully returned 70 animals to the safety of deeper water. This is equivalent to a whole bus load of individuals that can now continue their lives thanks to this monumental effort.


David P. Hocking
Research Fellow, School of Biological Sciences, Monash University, Australia

Felix G. Marx
Curator of Vertebrates, Museum of New Zealand Te Papa Tongarewa, New Zealand


  1. Has there been any research into determining the effectiveness of moorings with sonar reflectors in shallow areas known to be dangerous for these animals as stranding-deterrents? Could such virtual-fences help minimize future stranding events?

  2. One aspect of why marine mammals go ‘astray’ sometimes to become stranded or lost in rivers is the possibility that it is an atavistic behavior in the sense that these animals still retain some aspect of their historical behavior patterns that results in trouble in the present where there is land instead of sea as may have been the case in the past. This has been proposed in the scientific literature and is not too far fetched when one keeps in mind how parochial birds are with their nesting sites that may persist even when subject to tectonic displacement or even uplift (such as with ‘marine’ species having upland or subalpine nesting habits).

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