Emperor penguin chicks hatch into one of Earth’s most inhospitable places–the frozen world of Antarctica. Childhood in this environment is harsh and lasts only about five months, when their formerly doting parents leave the fledglings to fend for themselves.
New research by the Woods Hole Oceanographic Institution (WHOI) and colleagues reveals the previously unknown behaviors of juvenile Emperor penguins in their critical early months when they leave their birth colony and first learn how to swim, dive, and find food. The paper, published Jan. 17, 2019, in the journal Marine Ecology Progress Series, also highlights the unique connection between juvenile diving behaviors and a layer of the ocean, known as the thermocline, where warmer surface waters meet cooler deep waters below and where their prey likely gather in groups.
“This study provides insights into an important, but poorly understood, part of their life cycle, which is essential to being able to better predict the species’ response to future climate change,” says Sara Labrousse, a postdoctoral investigator at WHOI and lead author of the paper.
Researchers from Centre d’Etudes Biologiques de Chize? in France tagged 15 juvenile penguins before the animals left their colony in Terre Adélie during 2013 and 2014 fieldwork in December, when the weather usually starts to warm and the ice begins to break up, creating open waters near the nesting site.
The researchers attached tags to the lower backs of healthy chicks that had the best chances of survival. The tags recorded the penguins’ movements and transmitted diving and location data via satellite. More than 62,000 dives were recorded.
The tags revealed that the juvenile penguins initially moved far north to reach open water areas and warmer waters.
“This is when they are essentially learning how to swim,” says Labrousse. “That’s not something that their parents teach them. When they first go in the water, they are very awkward and unsure of themselves. They are not the fast and graceful swimmers their parents are.”
The tags showed that once the juvenile Emperor penguins became more experienced at diving, they headed south, entered the sea ice zone where they spent the winter months making deeper dives within sea ice.
“That was something that surprised us because we didn’t previously know how long they were staying within the sea ice,” Labrousse says. “It turns out that they spend most of the winter diving beneath the sea ice.”
The thermocline starts to deepen in autumn. The animals’ deeper dives likely were related to the depth of the thermocline and the seasonal change in the distribution of their prey, krill and other fish from the surface to the depths, Labrousse says. The deepest dive recorded by the tags was to 264 meters.
“The next step in this research would be to utilize tags that could record death at-sea,” says Labrousse. “That would give us data on their survival rates, which we don’t have for this study.”
Tags stopped recording dives after less than one day on two individuals, while one individual’s tag stopped after 31 days. The tags on the remaining 12 penguins, recorded trips lasting from 86 to 344 days.
“In those cases when the tags stop transmitting, we don’t know whether something happened to the animal or if it was due to a battery or other technical problem with the tag,” Labrousse adds.
Emperor penguins are the largest species of penguins. They are particularly vulnerable to climate change because their life cycles are so dependent on sea ice. Their breeding cycle begins in March (autumn in Antarctica) when the sea ice is thick enough to support their colony.
After laying a single egg each, the females leave the colony to catching fish and fatten up so they can feed their chicks. The males stay behind and cradle the egg on the tops of their feet, tucked under their brooding pouch for warmth and protection. Too little sea ice during this time can reduce the availability of breeding sites and prey; too much sea ice means longer hunting trips for adults, which in turn means lower feeding rates for chicks.
“Juveniles stay at sea for five or six years before they return to the colony to mate,” says Stephanie Jenouvrier, biologist at WHOI and coauthor of the study. “We need to better understand the dynamics of what happens during the time the juveniles are away from the colony. Understanding how they will respond to the changing landscape in terms of breeding and other life history stages is key to predict population responses and species persistence to future climate change.”
This research was supported by the French Polar Institute, the European Research Council, and the National Science Foundation. Additional coauthors are: Florian Orgeret, Christophe Barbraud, Charles A. Bost, and Henri Weimerskirch of the Centre d’Etudes Biologiques de Chize?; Jean-Baptiste Salle?e of Sorbonne Universite?s; and Andrew R. Solow of WHOI.
The Woods Hole Oceanographic Institution is a private, non-profit organization on Cape Cod, Mass., dedicated to marine research, engineering, and higher education. Established in 1930 on a recommendation from the National Academy of Sciences, its primary mission is to understand the oceans and their interaction with the Earth as a whole, and to communicate a basic understanding of the oceans’ role in the changing global environment. For more information, please visit http://www.whoi.edu.