One of the larger members of the
Arctic Archipelago, it is also a member of the
Sverdrup Islands and
Queen Elizabeth Islands. It is known for its unusual
fossilforests, which date from the
Eocene period.[3] Owing to the lack of mineralization in many of the forest specimens, the traditional characterization of "fossilisation" fails for these forests and "mummification" may be a clearer description. The fossil records provide strong evidence that the Axel Heiberg forest was a high-latitude wetland forest.[4] A
holotype of the
ammoniteOtoceras gracile was found in the
Griesbachian (Early
Triassic) deposits of this island.[5]
History
Axel Heiberg Island has been inhabited in the past by the
Inuit,[6][7] but was uninhabited by the time it was named by
Otto Sverdrup, who explored it in 1900–01. He named it after
Axel Heiberg, financial director of the Norwegian
Ringnes brewery which sponsored the expedition.[8] Other explorers visited the island during the early 20th century, during which time it was claimed by
Norway until 1930. It is now part of Nunavut Territory, Canada. It was not until the late 1940s that the island was aerially photographed by the
United States Army Air Forces' Operation Polaris. In 1955 two
geologists of the
Geological Survey of Canada, N.J. McMillan and Souther traversed the interior as part of Operation Franklin. McMillan's observations of Bunde Glacier, in northwest Axel Heiberg Island, are the earliest glaciological observations on the ground to have found their way into a scientific publication.
In 1959, scientists from
McGill University explored Expedition Fiord (previously Sør Fjord or South Fiord) in central Axel Heiberg Island. This resulted in the establishment of the
McGill Arctic Research Station (79°26′N90°46′W / 79.433°N 90.767°W / 79.433; -90.767 (McGill Arctic Research Station)), constructed 8 km (5.0 mi) inland from Expedition Fjord in 1960. It consists of a small research hut, a cookhouse and two temporary structures that can comfortably accommodate 8–12 persons. The station was initially heavily utilized during the early 1960s, during which a population of 20 was present. The McGill Arctic Research Station is active from March to August with research currently focused on polar geomorphology, geology, glaciology,
permafrost, climate change, and polar microbiology. Over the last 10–15 years, it has served as a significant Mars analogue for astrobiology investigations studying life and habitability of polar cryoenvironments and field-testing planetary exploration instrumentation platforms.
During the summer of 1986, a Canadian expedition headed by Dr. James Basinger set out to investigate a very unusual fossil forest on Axel Heiberg. The findings of these and subsequent expeditions have since been popularly reported in Canada.[9][10][11] Over 40 million years ago during the Eocene epoch, a forest of tall trees flourished on Axel Heiberg Island. The trees reached up to 35 m (115 ft) in height; some may have grown for 500 to 1,000 years. At the time, the polar climate was warm, but the winters were still continuously dark for three months. As the trees fell, the fine sediment in which the forest grew protected the plants. Instead of turning into
petrified "stone" fossils, they were ultimately mummified by the cold, dry Arctic climate, and only recently exposed by erosion.[12] Scientists from the Komarov Botanical Institute of the Russian Academy of Sciences in Saint Petersburg provided a few grams of Metasequoia conifer wood from the site to genetics researchers at the National University of Altai, who compared the DNA sequences of the ancient wood with DNA of modern woody plants and found them to be almost identical.[13] Komarov Institute scientists also discovered double strand DNA molecules in Metasequoia fossil leaves from Axel Heiberg Island.[14]
As late as 1999, the preservation of this unique site was a concern, as the fossil wood was easily damaged and eroded once exposed. There were concerns that wood was being taken by Arctic cruise ship tourists, and that the site was being disturbed by Canadian military helicopters from a nearby base, and even by scientists themselves in their studies.[15] There were calls for more protection for the area. It currently has no official status, in part because land claims had to be settled. But now Nunavut is looking at how best to protect the fossil forest, possibly by setting up a territorial park to be called Napaaqtulik, "where there are trees".[12][16]
Interesting animal fossils have been discovered on the island, including a remarkably preserved specimen of an ancient Aurorachelys turtle and, identified in 2016, the
humerus of a Tingmiatornis bird.[17][18]
Glaciation
White Glacier is a
valley glacier occupying 38.7 km2 (14.9 sq mi) in the Expedition Fiord area of Axel Heiberg Island (79°30′N090°50′W / 79.500°N 90.833°W / 79.500; -90.833 (White Glacier)). It extends in elevation from 56 to 1,782 m (184 to 5,846 ft) above sea level, a range which, as noted by Dyurgerov (2002),[19] is exceeded only by
Devon Ice Cap in the world list of glaciers with measured mass balance. Ice thickness reaches or exceeds 400 m (1,300 ft). Its maximum extension in recent history, marking the advance of the glacier in response to the cooling of the
Little Ice Age, was reached not earlier than the late 18th century, and more probably at the beginning of the 20th century. There is evidence that the retreat of the terminus, previously at about 5 m (16 ft) per year, is decelerating (Cogley et al. 1996a; Cogley and Adams 2000). White Glacier has been the subject of many papers in the glaciological literature since 1960, e.g.[20][21][22] Müller (1962)[20] was the source of a now-classical diagram elaborating and illustrating the concept of "
glacier facies".
The Lost Hammer Spring, located in the central west region of the island (79°07′N090°21′W / 79.117°N 90.350°W / 79.117; -90.350 (Lost Hammer Spring)) is the coldest and saltiest of all
Arctic springs described to date. It is characterized by a perennial hypersaline (24%) discharge at subzero temperatures (~−5 °C (23 °F)) flowing to the surface through a hollow, 2 m (6 ft 7 in) high cone-shaped salt
tufa structure. Continuous gas emissions from the spring indicate an underlying thermogenic
methane source. On the basis of these properties, this spring is considered a significant
astrobiology analogue site for possible habitats currently present on
Mars and the cold moons
Europa and
Enceladus.
Microbes have been found at this site which do not depend on organic material or oxygen, but only on simple inorganic compounds. These inorganic compounds are present on Mars.[23]
Views of the island
Glacier Fiord, Axel Heiberg Island. June 6, 1975.
View from Wolf Mountain over the Expedition Valley towards southern Axel Heiberg Island. June 24, 1975.
Outcrops on Axel Heiberg Island. July 2, 2012.
Axel Heiberg Island, Expedition Valley with White Glacier (left) and Thompson Glacier (right). July 3, 1988.
Front of advancing White Glacier, Axel Heiberg Island, June 23, 1975. The steep glacier front with waterfalls is caused by cold glacier ice, the ice cliff shows shear moraines with debris, part of the well-known Thompson Glacier with its push moraine at right. Foreground: vegetation cover of Saxifraga.
The active push moraine of Thompson glacier in July 1988
^Igor A. Ozerov et al., "Use of DNA-specific stains as indicators of nuclei and extranuclear substances in leaf cells of the Middle Eocene Metasequoia from Arctic Canada" in Review of Palaeobotany and Palynology, Volume 279, August 2020, 104211:
https://doi.org/10.1016/j.revpalbo.2020.104211
^Dyurgerov, M.B. (2002). "Glacier Mass Balance and Regime: Data of Measurements and Analysis". Occasional Paper 55, Institute of Arctic and Alpine Research, University of Colorado.
Jackson, M P A; Harrison, J C (2006). "An Allochthonous Salt Canopy on Axel Heiberg Island, Sverdrup Basin, Arctic Canada". Geology. 34 (12): 1045.
Bibcode:
2006Geo....34.1045J.
doi:
10.1130/g22798a.1.
Vandermark, D.; Tarduno, J. A.; Brinkman, D. B. (2006). "Late Cretaceous Plesiosaur Teeth from Axel Heiberg Island, Nunavut, Canada". Arctic. 59 (1): 79–82.
Chih-Ying Lay, Nadia C. S. Mykytczuk, Étienne Yergeau, Guillaume Lamarche-Gagnon, Charles W. Greer, & Lyle G. Whyte, "Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring," Applied and Environmental Microbiology, Volume 79 Number 12 (June 2013), p. 3637–3648.
http://aem.asm.org/content/79/12/3637