Dinosaurs from the North Pole: Live at Prince Creek

When we think about dinosaurs, we probably imagine them walking through a dense, tropical jungle or wandering in a warm, foggy swamp. But as a matter of fact, some dinosaur species lived in very high latitudes, as the ones found in the Prince Creek formation. This Alaskan geologic formation is one of the most important sources of arctic dinosaurs, as many fossils have been found in it. In this entry, we’ll describe some of these dinosaurs from the North Pole, and we’ll explain some of the difficulties they had to endure in order to survive in the northernmost point of the planet.

ALASKA 75 MILLION YEARS AGO

The Prince Creek formation is situated in the north of Alaska and dates from around 80-60 million years ago, at the end of the Cretaceous, the last period of the Mesozoic. At that time, North America was divided by the Western Interior Seaway; the eastern continent or Appalachia, and the western continent or Laramidia, north of which the Prince Creek formation was deposited.

Map of North America at the end of the Cretaceous period, with the Prince Creek formation marked in red, from the article New Horned Dinosaurs from Utah Provide Evidence for Intracontinental Dinosaur Endemism.

At the end of the Cretaceous period, the Prince Creek formation was further north than it is today. Yet, at that time the Earth was going through a greenhouse effect phase, so the climate was a little warmer than it is today. It is thought that the mean annual temperature at Prince Creek was about 5°C, with summer maximums at about 18-20°C. Still, the difference in temperature between summer and winter would have been quite remarkable (currently, at the same latitude, it’s about 56°C).

Even if temperatures were not as low as the ones of present-day Alaska, the dinosaurs of Prince Creek had to endure long, dark winter months. Yet, the slightly higher temperatures and the proximity to the sea, produced a higher diversity of plant species. Observing the fossilized flora, we know that the landscape was that of a polar woodland, with angiosperm-dominated forests and a large number of fern, moss and fungus species, with some areas of seasonally-flooded grasslands.

Drawing by Julio Lacerda of Prince Creek’s landscape and wildlife.

As for the fauna, palaeontologists were surprised at the great number of big animals found. The fact that dinosaurs were found in such high latitudes is what makes us think that these were endotherm animals that generated their own body heat. Also in Prince Creek, there aren’t any fossils of other ectotherm reptiles like turtles, crocodiles or snakes, which are usually found in other United States deposits of the same period. Currently, dinosaurs are thought to be neither endotherm nor ectotherm, but mesotherm animals, which generated body heat metabolically, but were unable to control its temperature or keep it stable.

TOUGH HERBIVORES

The relatively abundant vegetation, allowed the presence of a great diversity of plant-eating dinosaurs in such high latitudes. While the smaller herbivores had little trouble because of their low energetic requirements, the larger herbivores probably had more difficulties in order to find enough food, especially during the harsh winter months. The dinosaur fossil found at the highest latitude is Ugrunaaluk (literally “ancient grazer” in Inupiaq language from northern Alaska) a hadrosaurid or “duck-billed dinosaur”. This ornithopod measured up to 10 metres long and weighed around 3 tonnes, making it one of the largest animals in Prince Creek.

Reconstruction by James Havens of a herd of Ugrunaaluk kuukpikensis, moving under the polar lights.

Ugrunaaluk were herbivorous animals that lived in groups. Even if many author think that these animals performed long migrations like today’s birds and mammals in order to avoid the lack of food during the winter, some others argue that young Ugrunaaluk (which had a less active metabolism than current endotherms) would had been unable to endure such long journeys. Ugrunaaluk probably moved to areas were the vegetation better tolerated the severity of winter, even if it’s thought that these great herbivores survived during the dark winters feeding on bark, ferns and probably aquatic vegetation during the coldest months.

The other great Prince Creek plant-eater was Pachyrhinosaurus (literally “thick-nosed lizard”) a ceratopsid widely-distributed through the United States, with a large protuberance on its nose which may have been used as a weapon during intraspecific combats, and a pair of laterally-facing horns on the top of its frill. Pachyrhinosaurus was the largest animal of Prince Creek, measuring up to 8 metres long and weighing up to 4 tonnes. It is possible that it used its nasal protuberance to shovel through the snow to reach the plants buried under it, similar to today’s bisons.

Reconstruction of a pair of Pachyrhinosaurus perotorum by James Havens.

All the animals of Prince Creek had arduous lives. Almost all the fossils of both Ugrunaaluk and Pachyrhinosaurus, indicate that these species matured quickly and died young. Observing the growth of the different bones that have been found, it is thought that these dinosaurs rarely lived for over 20 years of age, probably due to the harsh conditions of their habitat but also to the presence of predators.

PREDATORS LARGE AND SMALL

The largest predator of the region was Nanuqsaurus (“polar bear lizard”, from Inupiaq language), a tyrannosaurid. This animal had a highly developed sense of smell which allowed it to detect their prey or animal carcasses in low light during the polar winter. Also, although there is no evidence, it was probably covered in feathers which would have protected it from the cold, as many closely-related theropods presented feathers to some extent.

Reconstruction of Nanuqsaurus hoglundi by Tom Parker.

What’s more surprising about Nanuqsaurus is its size, much smaller than that of its relatives. While other tyrannosaurids from the same time measured between 10 or 12 metres long and weighed up to 9 tonnes, Nanuqsaurus was more of a pygmy tyrannosaur, with an estimated length of 6 metres and a weight of 800 kg. This diminutive size was probably caused by the fact that it lived in an environment where food availability varied through the seasons. Apart from the fact that their prey’s population densities probably weren’t very high, during winter months many herbivores would migrate to other areas.

By contrast, there was another theropod that presented the opposite adaptation. Troodon (“wounding tooth”) was a relatively small dinosaur, about 2.9 metres long and 50 kg of weight. This is a pretty abundant dinosaur in many North American deposits. Troodon was a highly active carnivorous animal, with a good binocular vision and it’s also believed to be one of the most intelligent Mesozoic dinosaurs.

Reconstruction of two Troodon inequalis playing in the snow by Midiaou.

While Nanuqsaurus was smaller by the lack of abundant prey, Troodon specimens found at Prince Creek were characterized by their bigger size, compared with the ones from other deposits. This is what is called the Bergmann’s Rule, according to which the populations of a species that live in colder climates tend to be larger than the populations living in warmer climates, as this way they lose less body heat. Also, the larger eyes of Prince Creek’s Troodon, would give them advantage hunting during the long winter nights.

Image from the article A Diminutive New Tyrannosaur from the Top of the World, in which we can see the size of Nanuqsaurus (A) compared with some other tyrannosaurids (B, C, D and E) and two Troodon specimens (F and G) from different latitudes.

As you can see, dinosaurs not only thrived in warm and tropical environments. Even if their populations weren’t very large and their living conditions were harsher, these dinosaurs were able to adapt and survive in the polar forests of Prince Creek, and many of them surely gazed at the spectacular northern lights of 75 million years ago.

Assembly of the different dinosaur species from the Prince Creek formation by James Kuether.

REFERENCES

The following sources have been consulted during the elaboration of this entry:

• Susana Salazar Jaramillo (2014). Paleoclimate and paleoenvironment of the Prince Creek and Cantwell formations, Alaska: terrestrial evidence of middle Maastrichtian greenhouse event. Thesis.
• Live Science. Polar Dinosaurs Endured Cold Dark Winters.
• The Strange Lives of Polar Dinosaurs.
• North Pole Dinosaurs Lived Short, Hard Lives: Discovery News.
• Gangloff, Fiorillo & Norton (2005). The first Pachycephalosaurine (Dinosauria) from the Paleo-Arctic of Alaska and its Paleogeographic implications. Journal of Paleontology. Vol. 79. Pp: 997-1001.
• Mori, Druckenmiller & Erickson (2016). A New Hadrosaurid from the Prince Creek Formation (Lower Maastrichtian) of Northern Alaska. Acta Palaeontologica Polonica. Vol. 61. Pp: 15-32.
• Fiorillo & Tykoski (2014). A Diminutive New Tyrannosaur from the Top of the World. PLoS ONE 9(3).
• Cover Image by Julio Lacerda.

The Arctic: who cares?

The global change is the main threat to the Arctic, due to the increasing temperature is melting their ice coverage. What will be the consequences of this for its fragile ecosystem? Who cares about it?

THE ARCTIC AND ITS IMPORTANCE

The Arctic, one of the few unspoiled areas of the planet, is located in the north pole. Low temperatures in the region (an average of -35°C in winter and 0ºC in summer) are explained by the low insolation due to the inclination of the globe.

Before the industrial age, the permanent ice of the Arctic occupied about 7 million square kilometers (doubling its size in winter), but it is increasingly difficult to maintain that ice in summer. The ice may reach a thickness of 50 meters in winter, dropping to 2 meters in summer.

Before you start, you can enjoy this video with stunning images of the Arctic:

LIFE IN THE ARCTIC

The Arctic offers a wide variety of different environments: ocean, ice sheets, the coastal area, the tundra and some coniferous forests.

The tundra is most notable terrestrial biome in the Arctic (Picture: Biomas).

This allows the livelihood of many plant and animal species. Only in the Arctic Ocean, it has been described more than 5,000 animal species, some of which are endemic to this area. An estimated 400 species live only in the Arctic region.

Among the best known animals, we find the bowhead whale (Balaenoa mysticetus), a large animal that can live more than 100 years, and the narwhal (Monodon monoceros), cetacean in which males have a very long tusk, used during courtship.

Bowhead whale (Balaena mysticetus) is an endemic animal of the Arctic (Picture: Clarín).

On ice and snow, polar bear (Ursus maritimus), walrus (Odobenus rosmarus), the Arctic wolf (Canis lupus arctos) and the reindeer (Rangifer tarandus) are present.

Arctic wolf (Canis lupus arctos) is endangered (Picture: Deanimalia).

The Arctic is also home to over 80 species of birds, including the Brünnich’s guillemoth or the king eider; and more than 400 fish.

But undoubtedly, the group that takes the cake are arthropods, with more than 1,500 documented species, although there are also representatives of almost all existing animal phyla.

This copepod (Euaugaptilus hyperboreus) is part of Arctic zooplankton  (Picture: Poetic Monkey).

THE ARCTIC IS ESSENTIAL TO CLIMATE

The Arctic, along with Antarctica, is like a natural air conditioner on the planet. Therefore, malfunction further enhances the effects of climate change.

The ice cover is responsible for a high percentage of albedo. Albedo is the effect by which a surface reflects part of the solar radiation back into the atmosphere, thus maintaining a lower temperature. Without this effect, the temperatures will be increasingly high.

Ice is the key element of albedo in Earth surface (Picture: US Satellite).

The physical processes taking place in the Arctic affect ocean circulation worldwide: during the formation of sea ice, water crystals exclude salt, so that water is increasingly salty. The increase of salinity, along with the low water temperatures, cause the formation of a very dense water mass that sinks to the ocean floor and is transported southward through the thermohaline circulation, responsible for regulating the global climate. Without ice, the thermohaline circulation may be interrupted or weakened, with the consequences that would follow.

The thermohaline circulation is responsible of worldwide climate (Picture: Blog de recursos de Cpmc).

ARCTIC AND CLIMATE CHANGE

Due to the increase in temperature on a global level, the ice covering the Arctic has been reducing. Several reports indicate that this reduction was  about 30% in just two decades. Also, if this trend continues, in twenty years might disappear all Arctic ice, at least during summer. Without ice, many species will have serious problems to survive, such as the polar bear, seals and other pinnipeds.

(Picture: India Today).

As we have seen, no ice, no albedo; but also if the permanent ice melts, it will cause the release of large amounts of greenhouse gases that are trapped in either the ice or in the frozen Arctic soil (permafrost); providing a positive feedback to climate change.

Some studies suggest that, if the entire Greenland ice melt the average sea level will rise 7 meters.

In addition, increasingly massive algal blooms occur, which sink and cause eutrophication of the ecosystem. The ice thickness reduction allows increasing carbon dioxide in water to penetrate, causing water acidification, which can cause bleaching of coral and shells malformations in animals.

There are many companies that see the melting of the Arctic as a commercial possibility:

• Obtaining energy resources such as natural gas and oil (for only 3 years, according to experts).
• Exploitation of mineral resources such as manganese, gold, lead and diamonds.
• New fishing grounds.
• New trade routes for shipping and tourism.

Thus, the Arctic is a very fragile ecosystem that we must protect together. Acting locally, we are acting globally.

REFERENCES

• Broecker, WS (2005). The role of the ocean in climate: Yesterday, today and tomorrow. Eldigio Press
• El mar a fondo: El agua de mar y las corrientes oceánicas (Guía didáctica).
• McIntyre, A (2010). Life in the World’s Oceans. Blackwell Publishing Ltd.
• Greenpeace (2013). El Ártico y los efectos del cambio climático en España. Salvar el Ártico es salvar mucho más. Greenpeace.
• Hutchinson, S & Hawkins, LE (2004). Océanos. Libros Cúpula. Coleccion Biblioteca visual
• Palacín, B (2010). La creciente importancia el Ártico. Revista Española de Defensa
• Perrin, WF; Würsig, B & Thewissen, JGM (2009). Encyclopedia of Marine Mammals. Academic Press (2 ed)
• Cover picture: Kerstin Langenberger