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Baleen whale, largest animal ever known For other uses, see Blue whale (disambiguation).

Blue whale
Temporal range: Early Pleistocene – Recent 1.5–0 Ma PreꞒ O S D C P T J K Pg N
Adult blue whale
(Balaenoptera musculus)
Size compared to an average human
Conservation status

Endangered  (IUCN 3.1)
CITES Appendix I (CITES)
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Artiodactyla
Infraorder: Cetacea
Family: Balaenopteridae
Genus: Balaenoptera
Species: B. musculus
Binomial name
Balaenoptera musculus
(Linnaeus, 1758)
Subspecies
  • B. m. brevicauda Ichihara, 1966
  • ?B. m. indica Blyth, 1859
  • B. m. intermedia Burmeister, 1871
  • B. m. musculus Linnaeus, 1758
Blue whale range (in blue)
Synonyms
  • Balaena musculus Linnaeus, 1758
  • Balaenoptera gibbar Scoresby 1820
  • Pterobalaena gigas Van Beneden 1861
  • Physalus latirostris Flower 1864
  • Sibbaldius borealis Gray 1866
  • Flowerius gigas Lilljeborg 1867
  • Sibbaldius sulfureus Cope 1869
  • Balaenoptera sibbaldii Sars 1875

The blue whale (Balaenoptera musculus) is a marine mammal and a baleen whale. Reaching a maximum confirmed length of 29.9 m (98 ft) and weighing up to 199 t (196 long tons; 219 short tons), it is the largest animal known ever to have existed. The blue whale's long and slender body can be of various shades of greyish-blue on its upper surface and somewhat lighter underneath. Four subspecies are recognized: B. m. musculus in the North Atlantic and North Pacific, B. m. intermedia in the Southern Ocean, B. m. brevicauda (the pygmy blue whale) in the Indian Ocean and South Pacific Ocean, and B. m. indica in the Northern Indian Ocean. There is a population in the waters off Chile that may constitute a fifth subspecies.

In general, blue whale populations migrate between their summer feeding areas near the poles and their winter breeding grounds near the tropics. There is also evidence of year-round residencies, and partial or age/sex-based migration. Blue whales are filter feeders; their diet consists almost exclusively of krill. They are generally solitary or gather in small groups, and have no well-defined social structure other than mother–calf bonds. Blue whales vocalize, with a fundamental frequency ranging from 8 to 25 Hz; their vocalizations may vary by region, season, behavior, and time of day. Orcas are their only natural predators.

The blue whale was abundant in nearly all the Earth's oceans until the end of the 19th century. It was hunted almost to the point of extinction by whalers until the International Whaling Commission banned all blue whale hunting in 1966. The International Union for Conservation of Nature has listed blue whales as Endangered as of 2018. It continues to face numerous man-made threats such as ship strikes, pollution, ocean noise, and climate change. Scientists found evidence of this through morphological or epidemiological analysis. These analyses are accompanied by chemical profiles that use fecal and tissue which continue to prove the impact of man-made threats.

Taxonomy

See also: Evolution of cetaceans

Nomenclature

The genus name, Balaenoptera, means winged whale, while the species name, musculus, could mean "muscle" or a diminutive form of "mouse", possibly a pun by Carl Linnaeus when he named the species in Systema Naturae. One of the first published descriptions of a blue whale comes from Robert Sibbald's Phalainologia Nova, after Sibbald found a stranded whale in the estuary of the Firth of Forth, Scotland, in 1692. The name "blue whale" was derived from the Norwegian blåhval, coined by Svend Foyn shortly after he had perfected the harpoon gun. The Norwegian scientist G. O. Sars adopted it as the common name in 1874.

Blue whales were referred to as "Sibbald's rorqual", after Robert Sibbald, who first described the species. Whalers sometimes referred to them as "sulphur bottom" whales, as the bellies of some individuals are tinged with yellow. This tinge is due to a coating of huge numbers of diatoms. (Herman Melville briefly refers to "sulphur bottom" whales in his novel Moby-Dick.)

Evolution

Balaenopteridae

Minke whale

B. musculus (blue whale)

B. borealis (sei whale)

Eschrichtius robustus (gray whale)

B. physalus (fin whale)

Megaptera novaeangliae (humpback whale)

A phylogenetic tree of six baleen whale species

Blue whales are rorquals in the family Balaenopteridae. A 2018 analysis estimates that the Balaenopteridae family diverged from other families in between 10.48 and 4.98 million years ago during the late Miocene. The earliest discovered anatomically modern blue whale is a partial skull fossil from southern Italy identified as B. cf. musculus, dating to the Early Pleistocene, roughly 1.5–1.25 million years ago. The Australian pygmy blue whale diverged during the Last Glacial Maximum. Their more recent divergence has resulted in the subspecies having a relatively low genetic diversity, and New Zealand blue whales have an even lower genetic diversity.

Whole genome sequencing suggests that blue whales are most closely related to sei whales with gray whales as a sister group. This study also found significant gene flow between minke whales and the ancestors of the blue and sei whale. Blue whales also displayed high genetic diversity.

Hybridization

Blue whales are known to interbreed with fin whales. The earliest description of a possible hybrid between a blue whale and a fin whale was a 20 m (66 ft) anomalous female whale with the features of both the blue and the fin whales taken in the North Pacific. A whale captured off northwestern Spain in 1984, was found to have been the product of a blue whale mother and a fin whale father.

Two live blue-fin whale hybrids have since been documented in the Gulf of St. Lawrence (Canada), and in the Azores (Portugal). DNA tests done in Iceland on a blue whale killed in July 2018 by the Icelandic whaling company Hvalur hf, found that the whale was the offspring of a male fin whale and female blue whale; however, the results are pending independent testing and verification of the samples. Because the International Whaling Commission classified blue whales as a "Protection Stock", trading their meat is illegal, and the kill is an infraction that must be reported. Blue-fin hybrids have been detected from genetic analysis of whale meat samples taken from Japanese markets. Blue-fin whale hybrids are capable of being fertile. Molecular tests on a 21 m (70 ft) pregnant female whale caught off Iceland in 1986 found that it had a blue whale mother and a fin whale father, while its fetus was sired by a blue whale.

In 2024, a genome analysis of North Atlantic blue whales found evidence that approximately 3.5% of the blue whales' genome was derived from hybridization with fin whales. Gene flow was found to be unidirectional from fin whales to blue whales. Comparison with Antarctic blue whales showed that this hybridization began after the separation of the northern and southern populations. Despite their smaller size, fin whales have similar cruising and sprinting speeds to blue whales, which would allow fin males to complete courtship chases with blue females.

There is a reference to a humpback–blue whale hybrid in the South Pacific, attributed to marine biologist Michael Poole.

Subspecies and stocks

At least four subspecies of blue whale are traditionally recognized, some of which are divided into population stocks or "management units". They have a worldwide distribution, but are mostly absent from the Arctic Ocean and the Mediterranean, Okhotsk, and Bering Sea.

Aerial photograph of an adult blue whale showing its length
Aerial view of adult blue whale
  • Northern subspecies (B. m. musculus)
    • North Atlantic population – This population is mainly documented from New England along eastern Canada to Greenland, particularly in the Gulf of St. Lawrence, during summer though some individuals may remain there all year. They also aggregate near Iceland and have increased their presence in the Norwegian Sea. They are reported to migrate south to the West Indies, the Azores and northwest Africa.
    • Eastern North Pacific population – Whales in this region mostly feed off California's coast from summer to fall and then Oregon, Washington State, the Alaska Gyre and Aleutian Islands later in the fall. During winter and spring, blue whales migrate south to the waters of Mexico, mostly the Gulf of California, and the Costa Rica Dome, where they both feed and breed.
    • Central/Western Pacific population – This stock is documented around the Kamchatka Peninsula during the summer; some individuals may remain there year-round. They have been recorded wintering in Hawaiian waters, though some can be found in the Gulf of Alaska during fall and early winter.
  • Northern Indian Ocean subspecies (B. m. indica) – This subspecies can be found year-round in the northwestern Indian Ocean, though some individuals have recorded travelling to the Crozet Islands during between summer and fall.
  • Pygmy blue whale (B. m. brevicauda)
  • Antarctic subspecies (B. m. intermedia) – This subspecies includes all populations found around the Antarctic. They have been recorded to travel as far north as eastern tropical Pacific, the central Indian Ocean, and the waters of southwestern Australia and northern New Zealand.

Blue whales off the Chilean coast might be a separate subspecies based on their geographic separation, genetics, and unique song types. Chilean blue whales might overlap in the Eastern Tropical Pacific with Antarctica blue whales and Eastern North Pacific blue whales. Chilean blue whales are genetically differentiated from Antarctica blue whales such that interbreeding is unlikely. However, the genetic distinction is less between them and the Eastern North Pacific blue whale, hence there might be gene flow between the Southern and Northern Hemispheres. A 2019 study by Luis Pastene, Jorge Acevedo and Trevor Branch provided new morphometric data from a survey of 60 Chilean blue whales, hoping to address the debate about the possible distinction of this population from others in the Southern Hemisphere. Data from this study, based on whales collected in the 1965/1966 whaling season, shows that both the maximum and mean body length of Chilean blue whales lies between these values in pygmy and Antarctic blue whales. Data also indicates a potential difference in snout-eye measurements between the three, and a significant difference in fluke-anus length between the Chilean population and pygmy blue whales. This further confirms Chilean blue whales as a separate population, and implies that they do not fall under the same subspecies as the pygmy blue whale (B. m. brevicauda).

A 2024 genomic study of the global blue whale population found support for the subspecific status of Antarctic and Indo-western Pacific blue whales but not eastern Pacific blue whales. The study found "...divergence between the eastern North and eastern South Pacific, and among the eastern Indian Ocean, the western South Pacific and the northern Indian Ocean." and "no divergence within the Antarctic".

Description

A blue whale with its bow wave, showing the blowhole

The blue whale is a slender-bodied cetacean with a broad U-shaped head; thin, elongated flippers; a small 33 centimeters (13 in) sickle-shaped dorsal fin located close to the tail, and a large tail stock at the root of the wide and thin flukes. The upper jaw is lined with 70–395 black baleen plates. The throat region has 60–88 grooves which allows the skin to expand during feeding. It has two blowholes that can squirt 9.1–12.2 meters (30–40 ft) up in the air. The skin has a mottled grayish-blue coloration, appearing blue underwater. The mottling patterns near the dorsal fin vary between individuals. The underbelly has lighter pigmentation and can appear yellowish due to diatoms in the water, which historically earned them the nickname "sulphur bottom". The male blue whale has the largest penis in the animal kingdom, at around 3 m (9.8 ft) long and 12 in (30 cm) wide.

Size

Photograph of a blue whale skull
A blue whale skull measuring 5.8 meters (19 ft)

The blue whale is the largest animal known ever to have existed. Some studies have estimated that certain shastasaurid ichthyosaurs and the ancient whale Perucetus could have rivalled the blue whale in size, with Perucetus also being heavier than the blue whale with a mean weight of 180 t (180 long tons; 200 short tons). These estimates are based on fragmentary remains, and the proposed size for the latter has been disputed in 2024. Other studies estimate that on land, large sauropods like Bruhathkayosaurus (mean weight: 110–170 tons) and Maraapunisaurus (mean weight: 80–120 tons) would have easily rivalled the blue whale, with the former even exceeding the blue whale based on its most liberal estimations (240 tons), although these estimates are based on even more fragmentary specimens that had disintegrated by the time those estimates were made.

The International Whaling Commission (IWC) whaling database reports 88 individuals longer than 30 meters (98 ft), including one of 33 meters (108 ft), but problems with how the measurements were taken suggest that any longer than 30.5 meters (100 ft) are suspect. The Discovery Committee reported lengths up to 31 meters (102 ft). The longest scientifically measured individual blue whale was 30 meters (98 ft) from rostrum tip to tail notch. Female blue whales are larger than males. Hydrodynamic models suggest a blue whale could not exceed 33 metres (108 ft) because of metabolic and energy constraints.

The average length of sexually mature female blue whales is 22.0 meters (72.1 ft) for Eastern North Pacific blue whales, 24 meters (79 ft) for central and western North Pacific blue whales, 21–24 meters (68–78 ft) for North Atlantic blue whales, 25.4–26.3 meters (83.4–86.3 ft) for Antarctic blue whales, 23.5 meters (77.1 ft) for Chilean blue whales, and 21.3 meters (69.9 ft) for pygmy blue whales.

In the Northern Hemisphere, males weigh an average 100 metric tons (220,000 lb) and females 112 metric tons (247,000 lb). Eastern North Pacific blue whale males average 88.5 tonnes (195,000 lb) and females 100 tonnes (220,000 lb). Antarctic males average 112 tonnes (247,000 lb) and females 130 tonnes (290,000 lb). Pygmy blue whale males average 83.5 tonnes (184,000 lb) to 99 tonnes (218,000 lb). The weight of the heart of a stranded North Atlantic blue whale was 180 kg (400 lb), the largest known in any animal. The record-holder blue whale was recorded at 173 tonnes (190 short tons), with estimates of up to 199 tonnes (220 short tons).

In 2024, Motani and Pyenson calculated the body mass of blue whales at different lengths, compiling records of their sizes from previous academic literatures and using regression analyses and volumetric analyses. A 25 metres (82 ft) long individual was estimated to weigh approximately 101–119 tonnes (111–131 short tons), while a 30 metres (98 ft) long individual was estimated to weigh approximately 184–205 tonnes (203–226 short tons). Considering that the largest blue whale was indeed 33 metres (108 ft) long, they estimated that a blue whale of such length would have weighed approximately 252–273 tonnes (278–301 short tons).

During the harvest of a female blue whale, Messrs. Irvin and Johnson collected a fetus that is now 70% preserved and used for educational purposes. The fetus was collected in 1922, so some shrinkage may have occurred, making visualization of some features fairly difficult. However, due to this collection researchers now know that the external anatomy of a blue whale fetus is approximately 133 mm. Along with during the developmental phases, the fetus is located where the embryonic and fetal phases converge. This fetus is the youngest gestational age of the specimen recorded.

Life span

Blue whales live around 80–90 years or more. Scientists look at a blue whale's earwax or ear plug to estimate its age. Each year, a light and dark layer of wax is laid corresponding with fasting during migration and feeding time. Each set is thus an indicator of age. The oldest blue whale found was determined, using this method, to be 110 years old. The maximum age of a pygmy blue whale determined this way is 73 years. In addition, female blue whales develop scars or corpora albicantia on their ovaries every time they ovulate. In a female pygmy blue whale, one corpus albicans is formed on average every 2.6 years.

Behaviour and ecology

Photograph of a whale blowing
The blow of a blue whale

The blue whale is usually solitary, but can be found in pairs. When productivity is high enough, blue whales can be seen in gatherings of more than 50 individuals. Populations may go on long migrations, traveling to their summer feeding grounds towards the poles and then heading to their winter breeding grounds in more equatorial waters. The animals appear to use memory to locate the best feeding areas. There is evidence of alternative strategies, such as year-round residency, and partial (where only some individuals migrate) or age/sex-based migration. Some whales have been recorded feeding in breeding grounds. The traveling speed for blue whales ranges 5–30 kilometers per hour (3.1–18.6 mph). Their massive size limits their ability to breach.

The greatest dive depth reported from tagged blue whales was 315 meters (1,033 ft). Their theoretical aerobic dive limit was estimated at 31.2 minutes, however, the longest dive measured was 15.2 minutes. The deepest confirmed dive from a pygmy blue whale was 506 meters (1,660 ft). A blue whale's heart rate can drop to 2 beats per minute (bpm) at deep depths, but upon surfacing, can rise to 37 bpm, which is close to its peak heart rate.

Diet and feeding

Photograph of the blue whale's small dorsal fin
The small dorsal fin of this blue whale is just visible on the far left.

The blue whale's diet consists almost exclusively of krill. Blue whales capture krill through lunge feeding; they swim towards them at high speeds as they open their mouths up to 80°. They may engulf 220 metric tons (220 long tons; 240 short tons) of water at one time. They squeeze the water out through their baleen plates with pressure from the throat pouch and tongue, and swallow the remaining krill. Blue whales have been recorded making 180° rolls during lunge-feeding, possibly allowing them to search the prey field and find the densest patches.

While pursuing krill patches, blue whales maximize their calorie intake by increasing the number of lunges while selecting the thickest patches. This provides them enough energy for everyday activities while storing additional energy necessary for migration and reproduction. Due to their size, blue whales have larger energetic demands than most animals resulting in their need for this specific feeding habit. Blue whales have to engulf densities greater than 100 krill/m to maintain the cost of lunge feeding. They can consume 34,776–1,912,680 kilojoules (8,312–457,141 kcal) from one mouthful of krill, which can provide up to 240 times more energy than used in a single lunge. It is estimated that an average-sized blue whale must consume 1,120 ± 359 kilograms (2,469 ± 791 lb) of krill a day.

In the southern ocean, blue whales feed on Antarctic krill (Euphausia superba). In the South Australia, pygmy blue whales (B. m. brevicauda) feeds on Nyctiphanes australis. In California, they feed mostly on Thysanoessa spinifera, but also less commonly on North pacific krill (Euphausia pacifica). Research of the Eastern North Pacific population shows that when diving to feed on krill, the whales reach an average depth of 201 meters, with dives lasting 9.8 minutes on average.

While most blue whales feed almost exclusively on krill, the Northern Indian Ocean subspecies (B. m. indica) instead feeds predominantly on sergestid shrimp. To do so, they dive deeper and for longer periods of time than blue whales in other regions of the world, with dives of 10.7 minutes on average, and a hypothesized dive depth of about 300 meters. Fecal analysis also found the presence of fish, krill, amphipods, cephalopods, and scyphozoan jellyfish in their diet.

Blue whales appear to avoid directly competing with other baleen whales. Different whale species select different feeding spaces and times as well as different prey species. In the Southern Ocean, baleen whales appear to feed on Antarctic krill of different sizes, which may lessen competition between them.

Blue whale feeding habits may differ due to situational disturbances, like environmental shifts or human interference. This can cause a change in diet due to stress response. Due to these changing situations, there was a study performed on Blue whales measuring Cortisol levels and comparing them with the levels of stressed individuals, it gave a closer look to the reasoning behind their diet and behavioral changes.

Reproduction and birth

Photograph of a blue whale calf and its mother
A blue whale calf with its mother

Blue whales generally reach sexual maturity at 8–10 years. In the Northern Hemisphere, the length at which they reach maturity is 21–23 meters (69–75 ft) for females and 20–21 meters (66–69 ft) for males. In the Southern Hemisphere, the length of maturity is 23–24 meters (75–79 ft) and 22 meters (72 ft) for females and males respectively. Male pygmy blue whales average 18.7 meters (61.4 ft) at sexual maturity. Female pygmy blue whales are 21.0–21.7 meters (68.9–71.2 ft) in length and roughly 10 years old at the age of sexual maturity. Little is known about mating behavior, or breeding and birthing areas. Blue whales appear to be polygynous, with males competing for females. A male blue whale typically trails a female and will fight off potential rivals. The species mates from fall to winter.

Pregnant females eat roughly four percent of their body weight daily, amounting to 60% of their overall body weight throughout summer foraging periods. Gestation may last 10–12 months with calves being 6–7 meters (20–23 ft) long and weighing 2–3 metric tons (2.0–3.0 long tons; 2.2–3.3 short tons) at birth. Estimates suggest that because calves require 2–4 kilograms (4.4–8.8 lb) milk per kg of mass gain, blue whales likely produce 220 kilograms (490 lb) of milk per day (ranging from 110 to 320 kilograms (240 to 710 lb) of milk per day). The first video of a calf thought to be nursing was filmed in New Zealand in 2016. Calves may be weaned when they reach 6–8 months old at a length of 16 meters (53 ft). They gain roughly 37,500 pounds (17,000 kg) during the weaning period. Interbirth periods last two to three years; they average 2.6 years in pygmy blue whales.

Vocalizations

A blue whale song Recorded in the Atlantic (1)
A blue whale song Recorded in the Atlantic (2)
A blue whale song Recorded in North Eastern Pacific
A blue whale song Recorded in the South Pacific
A blue whale song Recorded in the West Pacific
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Blue whales produce some of the loudest and lowest frequency vocalizations in the animal kingdom, and their inner ears appear well adapted for detecting low-frequency sounds. The fundamental frequency for blue whale vocalizations ranges from 8 to 25 Hz. Blue whale songs vary between populations.

Vocalizations produced by the Eastern North Pacific population have been well studied. This population produces pulsed calls ("A") and tonal calls ("B"), upswept tones that precede type B calls ("C") and separate downswept tones ("D"). A and B calls are often produced in repeated co-occurring sequences and sung only by males, suggesting a reproductive function. D calls may have multiple functions. They are produced by both sexes during social interactions while feeding. and by males when competing for mates.

Blue whale calls recorded off Sri Lanka have a three-unit phrase. The first unit is a 19.8 to 43.5 Hz pulsive call, and is normally 17.9 ± 5.2 seconds long. The second unit is a 55.9 to 72.4 Hz FM upsweep that is 13.8 ± 1.1 seconds long. The final unit is 28.5 ± 1.6 seconds long with a tone of 108 to 104.7 Hz. A blue whale call recorded off Madagascar, a two-unit phrase, consists of 5–7 pulses with a center frequency of 35.1 ± 0.7 Hz lasting 4.4 ± 0.5 seconds proceeding a 35 ± 0 Hz tone that is 10.9 ± 1.1 seconds long. In the Southern Ocean, blue whales produce 18-second vocals which start with a 9-second-long, 27 Hz tone, and then a 1-second downsweep to 19 Hz, followed by a downsweep further to 18 Hz. Other vocalizations include 1–4 second long, frequency-modulated calls with a frequency of 80 and 38 Hz.

There is evidence that some blue whale songs have temporally declined in tonal frequency. The vocalization of blue whales in the Eastern North Pacific decreased in tonal frequency by 31% from the early 1960s to the early 21st century. The frequency of pygmy blue whales in the Antarctic has decreased by a few tenths of a hertz every year starting in 2002. It is possible that as blue whale populations recover from whaling, there is increasing sexual selection pressure (i.e., a lower frequency indicates a larger body size).

Predators and parasites

The only known natural predator to blue whales is the orca, although the rate of fatal attacks by orcas is unknown. Photograph-identification studies of blue whales have estimated that a high proportion of the individuals in the Gulf of California have rake-like scars, indicative of encounters with orcas. Off southeastern Australia, 3.7% of blue whales photographed had rake marks and 42.1% of photographed pygmy blue whales off Western Australia had rake marks. Documented predation by orcas has been rare. A blue whale mother and calf were first observed being chased at high speeds by orcas off southeastern Australia. The first documented attack occurred in 1977 off southwestern Baja California, Mexico, but the injured whale escaped after five hours. Four more blue whales were documented as being chased by a group of orcas between 1982 and 2003. The first documented predation event by orcas occurred in September 2003, when a group of orcas in the Eastern Tropical Pacific was encountered feeding on a recently killed blue whale calf. In March 2014, a commercial whale watch boat operator recorded an incident involving a group of orcas harassing a blue whale in Monterey Bay. The blue whale defended itself by slapping its tail. A similar incident was recorded by a drone in Monterey Bay in May 2017. The first direct observations of orca predation occurred off the south coast of Western Australia, two in 2019 and one more in 2021. The first victim was estimated to be 18–22 meters (59–72 ft).

In Antarctic waters, blue whales accumulate diatoms of the species Cocconeis ceticola and the genera Navicola, which are normally removed when the whales enter warmer waters. Other external parasites include barnacles such as Coronula diadema, Coronula reginae, and Cryptolepas rhachianecti, which latch on their skin deep enough to leave behind a pit if removed. Whale lice species make their home in cracks of the skin and are relatively harmless. The copepod species Pennella balaenopterae digs in and attaches itself to the blubber to feed on. Intestinal parasites include the trematode genera Ogmogaster and Lecithodesmus; the tapeworm genera Priapocephalus, Phyllobotrium, Tetrabothrius, Diphyllobotrium, and Diplogonoporus; and the thorny-headed worm genus Bolbosoma. In the North Atlantic, blue whales also contain the protozoans Entamoeba, Giardia and Balantidium.

Conservation

The global blue whale population is estimated to be 5,000–15,000 mature individuals and 10,000–25,000 total as of 2018. By comparison, there were at least 140,000 mature whales in 1926. There are an estimated total of 1,000–3,000 whales in the North Atlantic, 3,000–5,000 in the North Pacific, and 5,000–8,000 in the Antarctic. There are possibly 1,000–3,000 whales in the eastern South Pacific while the pygmy blue whale may number 2,000–5,000 individuals. Blue whales have been protected in areas of the Southern Hemisphere since 1939. In 1955, they were given complete protection in the North Atlantic under the International Convention for the Regulation of Whaling; this protection was extended to the Antarctic in 1965 and the North Pacific in 1966. The protected status of North Atlantic blue whales was not recognized by Iceland until 1960. In the United States, the species is protected under the Endangered Species Act.

Blue whales are formally classified as endangered under both the U.S. Endangered Species Act and the IUCN Red List. They are also listed on Appendix I under the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) and the Convention on the Conservation of Migratory Species of Wild Animals. Although, for some populations, there is not enough information on current abundance trends (e.g., pygmy blue whales), others are critically endangered (e.g., Antarctic blue whales).

Threats

Dead blue whale on flensing platform

Blue whales were initially difficult to hunt because of their size and speed. This began to change in the mid-19th century with the development of harpoons that can be shot as projectiles. Blue whale whaling peaked between 1930 and 1931 with 30,000 animals taken. Harvesting of the species was particularly high in the Antarctic, with 350,000–360,000 whales taken in the first half of the 20th century. In addition, 11,000 North Atlantic whales (mostly around Iceland) and 9,500 North Pacific whales were killed during the same period. The International Whaling Commission banned all hunting of blue whales in 1966 and gave them worldwide protection. However, the Soviet Union continued to illegally hunt blue whales and other species up until the 1970s.

Researchers examine a dead blue whale killed by collision with a ship

Ship strikes are a significant mortality factor for blue whales, especially off the U.S. West Coast. A total of 17 blue whales were killed or suspected to have been killed by ships between 1998 and 2019 off the U.S. West Coast. Five deaths in 2007 off California were considered an unusual mortality event, as defined under the Marine Mammal Protection Act. Lethal ship strikes are also a problem in Sri Lankan waters, where their habitat intersects with one of the world's most active shipping routes. Here, strikes caused the deaths of eleven blue whales in 2010 and 2012, and at least two in 2014. Ship-strike mortality claimed the lives of two blue whales off southern Chile in the 2010s. Possible measures for reducing future ship strikes include better predictive models of whale distribution, changes in shipping lanes, vessel speed reductions, and seasonal and dynamic management of shipping lanes. Few cases of blue whale entanglement in commercial fishing gear have been documented. The first report in the U.S. occurred off California in 2015, reportedly some type of deep-water trap/pot fishery. Three more entanglement cases were reported in 2016. In Sri Lanka, a blue whale was documented with a net wrapped through its mouth, along the sides of its body, and wound around its tail.

Increasing man-made underwater noise impacts blue whales. They may be exposed to noise from commercial shipping and seismic surveys as a part of oil and gas exploration. Blue whales in the Southern California Bight decreased calling in the presence of mid-frequency active (MFA) sonar. Exposure to simulated MFA sonar was found to interrupt blue whale deep-dive feeding but no changes in behavior were observed in individuals feeding at shallower depths. The responses also depended on the animal's behavioral state, its (horizontal) distance from the sound source and the availability of prey.

The potential impacts of pollutants on blue whales is unknown. However, because blue whales feed low on the food chain, there is a lesser chance for bioaccumulation of organic chemical contaminants. Analysis of the earwax of a male blue whale killed by a collision with a ship off the coast of California showed contaminants like pesticides, flame retardants, and mercury. Reconstructed persistent organic pollutant (POP) profiles suggested that a substantial maternal transfer occurred during gestation and/or lactation. Male blue whales in the Gulf of St. Lawrence, Canada, were found to have higher concentrations of PCBs, dichlorodiphenyltrichloroethane (DDT), metabolites, and several other organochlorine compounds relative to females, reflecting maternal transfer of these persistent contaminants from females into young.

See also

Note

  1. The extinct whale species Perucetus colossus (described in 2023) has been suggested as a potential contender of the blue whale in size, however, this was later disputed in 2024. Several extinct dinosaurs may also have reached a similar mass to the blue whale.

References

  1. ^ Cooke, J.G. (2019) . "Balaenoptera musculus". IUCN Red List of Threatened Species. 2018: e.T2477A156923585. doi:10.2305/IUCN.UK.2018-2.RLTS.T2477A156923585.en. Retrieved 13 June 2024.
  2. "Appendices | CITES". cites.org. Retrieved 14 January 2022.
  3. ^ Bianucci, G.; Lambert, O.; Urbina, M.; Merella, M.; Collareta, A.; Bennion, R.; Salas-Gismondi, R.; Benites-Palomino, A.; Post, K.; de Muizon, C.; Bosio, G.; Di Celma, C.; Malinverno, E.; Pierantoni, P.P.; Villa, I.M.; Amson, E. (2023). "A heavyweight early whale pushes the boundaries of vertebrate morphology". Nature. 620 (7975): 824–829. Bibcode:2023Natur.620..824B. doi:10.1038/s41586-023-06381-1. PMID 37532931. S2CID 260433513.
  4. ^ Motani, R.; Pyenson, N. D. (2024). "Downsizing a heavyweight: factors and methods that revise weight estimates of the giant fossil whale Perucetus colossus". PeerJ. 12. e16978. doi:10.7717/peerj.16978. PMC 10909350. PMID 38436015.
  5. ^ Paul, Gregory S.; Larramendi, Asier (11 April 2023). "Body mass estimate of Bruhathkayosaurus and other fragmentary sauropod remains suggest the largest land animals were about as big as the greatest whales". Lethaia. 56 (2): 1–11. Bibcode:2023Letha..56..2.5P. doi:10.18261/let.56.2.5. ISSN 0024-1164. S2CID 259782734.
  6. ^ Reeves, R. R.; Stewart, P. J.; Clapham, J.; Powell, J. A. (2002). Whales, dolphins, and porpoises of the eastern North Pacific and adjacent Arctic waters: A guide to their identification. New York: Knopf. pp. 234–237.
  7. ^ Calambokidis, J.; Steiger, G. H. (1997). Blue Whales. McGregor, MN: Voyager Press. p. 72.
  8. Linnaeus, Carl (1758). Systema Naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. Stockholm, Holmia: Laurentius Salvius. p. 824.
  9. ^ Sibbald, Robert (1692). "Phalainologia Nova". Blue Whale ("Balaenoptera Musculus"): 675–678.
  10. Bortolotti, D. (2008). Wild Blue: A Natural History of the World's Largest Animal. New York: St. Martin's Press.
  11. ^ Bennett, A G (1920). "On the occurrence of diatoms on the skin of whales". Proc. R. Soc. Lond. B. 91 (641): 352–357. doi:10.1098/rspb.1920.0021.
  12. ^ Melville, H. (1851). Moby-Dick. New York: Harper & Brothers. p. 398.
  13. ^ Árnason, U.; Lammers, F.; Kumar, V.; Nilsson, M. A.; Janke, A. (2018). "Whole-genome sequencing of the blue whale and other rorquals finds signatures for introgressive gene flow". Science Advances. 4 (4): eaap9873. Bibcode:2018SciA....4.9873A. doi:10.1126/sciadv.aap9873. PMC 5884691. PMID 29632892.
  14. Bianucci, G.; Marx, F. G.; Collareta, A.; Di Stefano, A.; Landini, W.; Morigi, C.; Varola, A. (2019). "Rise of the titans: baleen whales became giants earlier than thought". Biology Letters. 15 (5): 20190175. doi:10.1098/rsbl.2019.0175. PMC 6548731. PMID 31039728.
  15. Attard, C. R. M.; Beheregaray, L. B.; Jenner, K. C. S.; Gill, P. C.; Jenner, M.-N. M.; Morrice, M. G.; Teske, P. R.; Moller, L. M. (2015). "Low genetic diversity in pygmy blue whales is due to climate-induced diversification rather than anthropogenic impacts". Biology Letters. 11 (5): 20141037. doi:10.1098/rsbl.2014.1037. PMC 4455730. PMID 25948571.
  16. Barlow, D. R.; Torres, L. G.; Hodge, K. B.; Steel, D.; Baker, C. S.; Chandler, T. E.; Bott, N.; Constantine, R.; Double, M. C.; Gill, P.; Glasgow, D.; Hamner, R. M.; Lilley, C.; Ogle, M.; Olson, P. A. (2018). "Documentation of a New Zealand blue whale population based on multiple lines of evidence". Endangered Species Research. 36: 27–40. doi:10.3354/esr00891.
  17. Doroshenko, V. N. (1970). "A whale with features of the fin and the blue whale". Izvestia TINRO. 70: 255–257.
  18. Bérubé, M.; Aguilar, A. (1998). "A new hybrid between a blue whale, Balaenoptera Musculus, and a fin whale, "B. Physalus:" frequency and implications of hybridization". Marine Mammal Science. 14 (1): 82–98. Bibcode:1998MMamS..14...82B. doi:10.1111/j.1748-7692.1998.tb00692.x.
  19. Berube, M.; Oosting, T.; Aguilar, A.; Berrow, S.; Hao, W.; Heide-Jørgensen, M. P.; Kovacs, K. M.; Landry, S.; Lydersen, C.; Martin, V.; Øien, N.; Panigada, S.; Prieto, R.; Ramp, C.; Robbins, J. (2017). Are the "Bastards" coming back? Molecular identification of live blue and fin whale hybrids in the North Atlantic ocean. 22nd Biennial Conference on the Biology of Marine Mammals. Halifax, Nova Scotia, Canada.
  20. Kilvert, Nick (20 July 2018). "DNA test shows slaughtered blue whale is a hybrid, Iceland marine institute says". ABC. Retrieved 21 December 2019.
  21. Fishman, Margie (19 July 2018). "Hybrid blue-fin whale is still protected". Animal Welfare Institute. Retrieved 21 December 2019.
  22. Palumbi, S. R.; Cipriano, F. (1998). "Species identification using genetic tools: the value of nuclear and mitochondrial gene sequences in whale conservation". Journal of Heredity. 89 (5): 459–464. doi:10.1093/jhered/89.5.459. PMID 9768497.
  23. Spilliaert, R.; Vikingsson, G.; Arnason, U.; Palsdottir, A.; Sigurjonsson, J.; Arnason, A. (1991). "Species hybridization between a female blue whale (Balaenoptera rnusctllus) and a male fin whale ("B.pbysalus"): Molecular and morphological documentation". Journal of Heredity. 82 (4): 269–274. doi:10.1093/oxfordjournals.jhered.a111085. PMID 1679066.
  24. Jossey, Sushma; Haddrath, O.; Loureiro, L.; Weir, J.; Lim, B.; Miller, J.; Scherer, S.; Goskøyr, A; Lille-Langøy, R; Kovacs, Kit; Lyndersen, C; Routti, H; Engstrom, M (6 January 2024). "Population structure and history of North Atlantic Blue whales (Balaenoptera musculus musculus) inferred from whole genome sequence analysis". Conservation Genetics. Open access (2): 357–371. Bibcode:2024ConG...25..357J. doi:10.1007/s10592-023-01584-5.
  25. Hatch, L. T.; Dopman, E. B.; Harrison, R. G. (2006). "Phylogenetic relationships among the baleen whales based on maternally and paternally inherited characters". Molecular Phylogenetics and Evolution. 41 (1): 12–27. Bibcode:2006MolPE..41...12H. doi:10.1016/j.ympev.2006.05.023. PMID 16843014.
  26. ^ Oliver, Chris W. (November 2020). Recovery Plan for the Blue Whale (Balaenoptera musculus) (Report). National Oceanic and Atmospheric Administration. Retrieved 12 April 2022.
  27. "List of Marine Mammal Species and Subspecies". The Society for Marine Mammalogy. 13 November 2016. Retrieved 30 December 2019.
  28. LeDuc, R. G.; Dizon, A. E.; Goto, M.; Pastene, L. A.; Kato, H.; Nishiwaki, S.; LeDuc, C. A.; Brownell, R. L. (2023). "Patterns of genetic variation in Southern Hemisphere blue whales, and the use of assignment test to detect mixing on the feeding grounds". Journal of Cetacean Research and Management. 9: 73–80. doi:10.47536/jcrm.v9i1.694. S2CID 257136658.
  29. Torres-Florez, J. P.; Olson, P. A.; Bedrinana-Romano, L.; Rosenbaum, H.; Ruiz, J.; Leduc, R.; Huck-Gaete, R. (2015). "First documented migratory destination for eastern South Pacific blue whales". Marine Mammal Science. 31 (4): 1580–1586. Bibcode:2015MMamS..31.1580T. doi:10.1111/mms.12239.
  30. Buchan, S. J.; Rendell, L. E.; Hucke-Gaete, R. (2010). "Preliminary recordings of blue whale (Balaenoptera musculus) vocalizations in the Gulf of Corcovado, northern Patagonia Chile". Marine Mammal Science. 26 (2): 451–459. Bibcode:2010MMamS..26..451B. doi:10.1111/j.1748-7692.2009.00338.x.
  31. LeDuc, R. G.; Archer, E. I.; Lang, A. R.; Martien, K. K.; Hancock-Hanser, B.; Torres-Florez, J. P.; Hucke-Gaete, R.; Rosenbaum, H. R.; Van Waerebeek, K.; Brownell, R. L. Jr.; Taylor, B. L. (2016). "Genetic variation in blue whales in the eastern Pacific: implication for taxonomy and use of common wintering grounds". Molecular Ecology. 26 (3): 740–751. doi:10.1111/mec.13940. PMID 27891694. S2CID 206184206.
  32. Pastene, Luis A.; Acevedo, Jorge; Branch, Trevor A. (2019). "Morphometric analysis of Chilean blue whales and implications for their taxonomy". Marine Mammal Science. 36 (1): 116–135. doi:10.1111/mms.12625. ISSN 0824-0469.
  33. Attard, C. R. M.; Sandoval-Castillo, J; Lang, A. R.; Vernazzani, B. G.; Torres, L. G.; Baldwin, R; Jenner, K. C. S.; Gill, P. C.; Burton, C. L. K.; Barceló, A; Sironi, M; Jenner, M.-N. M.; Morrice, M. G.; Beheregaray, L. B.; Möller, L. M. (2024). "Global conservation genomics of blue whales calls into question subspecies taxonomy and refines knowledge of population structure". Animal Conservation. 27 (5): 626–638. Bibcode:2024AnCon..27..626A. doi:10.1111/acv.12935.
  34. ^ Sears, R.; Perrin, W. F. (2009). "Blue whale (Balaenoptera musculus)". In Perrin, W. F.; Würsig, B.; Thewissen, J. G. M. (eds.). Encyclopedia of marine mammals. San Diego, CA: Academic Press. pp. 120–124.
  35. ^ Leatherwood, S.; Caldwell, D. K.; Winn, H. E. (1976). "Whales, dolphins, and porpoises of the western North Atlantic". NOAA Technical Report NMFS Circular. 396: 176. Archived from the original on 20 July 2020. Retrieved 31 December 2019.
  36. Leatherwood, S.; Reeves, R. R.; Perrin, W. F.; Evans, W. E. (1982). "Whales, dolphins, and porpoises of the eastern North Pacific and adjacent Arctic waters: A guide to their identification". NOAA Technical Report NMFS Circular. 444: 245.
  37. Sears, R.; Williamson, J. M.; Wenzel, F. W.; Bérubé, M.; Gendron, D.; Jones, P. (1990). "Photographic identification of the blue whale (Balaenoptera musculus) in the Gulf of St. Lawrence, Canada". Reports of the International Whaling Commission. 12: 335–342.
  38. Calambokidis, J.; Barlow, J.; Ford, J. K. B.; Chandler, T. E.; Douglas, A. B. (2009). "Insights into the population structure of blue whales in the Eastern North Pacific from recent sightings and photographic identification". Marine Mammal Science. 25 (4): 816–832. Bibcode:2009MMamS..25..816C. doi:10.1111/j.1748-7692.2009.00298.x. S2CID 83527877.
  39. Gendron, D.; De La Cruz, U.; Winn, H. E. (2012). "A new classification method to simplify blue whale photo-identification technique". Journal of Cetacean Research and Management. 13 (1): 79–84.
  40. Scammon, C. M. (1874). The Marine Mammals of the Northwestern Coast of North America. New York: Dover.
  41. "Reproduction". University of Wisconsin. Retrieved 3 October 2012.
  42. Ruud, J. T. (1956). "The blue whale". Scientific American. 195 (6): 46–50. Bibcode:1956SciAm.195f..46R. doi:10.1038/scientificamerican1256-46.
  43. ^ Lockyer, C. (1981). "Growth and energy budgets of large baleen whales from the southern hemisphere". FAO Fisheries Series (5) Mammals in the Seas. 3: 379–487.
  44. ^ Mizroch, S. A.; Rice, D. W.; Breiwick, J. M. (1984). "The blue whale, Balaenoptera musculus". Marine Fisheries Review. 46: 15–19.
  45. De la Salle P, R Lomax D, A Massare J, Gallois R (2018). "A giant Late Triassic ichthyosaur from the UK and a reinterpretation of the Aust Cliff 'dinosaurian' bones". PLOS ONE. 13 (4). doi:10.6084/m9.figshare.5975440.
  46. ^ McClain, C. R.; Balk, M. A.; Benfield, M. C.; Branch, T. A.; Chen, C.; Cosgrove, J.; Dove, A. D. M.; Helm, R. R.; Hochberg, F. G.; Gaskins, L. C.; Lee, F. B.; Marshall, A.; McMurray, S. E.; Schanche, C.; Stone, S. N. (2015). "Sizing ocean giants: patterns of intraspecific size variation in marine megafauna". PeerJ. e715: e715. doi:10.7717/peerj.715. PMC 4304853. PMID 25649000.
  47. Mackintosh, N. A. (1942). "The southern stocks of whalebone whales". Discovery Reports. 22 (3889): 569–570. Bibcode:1944Natur.153..569F. doi:10.1038/153569a0. S2CID 41590649.
  48. Sears, R.; Calambokidis, J. (2002). Update COSEWIC status report on the blue whale (Balaenoptera musculus) in Canada. Ottawa, ON: Committee on the Status of Endangered Wildlife in Canada. p. 32.
  49. Ralls, K. (1976). "Mammals in which females are larger than males". The Quarterly Review of Biology. 51 (2): 245–270. doi:10.1086/409310. PMID 785524. S2CID 25927323.
  50. Potvin, J.; Goldbogen, J.; Chadwick, R. E. (2012). "Metabolic Expenditures of Lunge Feeding Rorquals Across Scale: Implications for the Evolution of Filter Feeding and the Limits to Maximum Body Size". PLOS ONE. 7 (9): e44854. Bibcode:2012PLoSO...744854P. doi:10.1371/journal.pone.0044854. PMC 3443106. PMID 23024769.
  51. ^ Branch, T. A.; Abubaker, E. M. N.; Mkango, S.; Butterworth, D. S. (2007). "Separating southern blue whale subspecies based on length frequencies of sexually mature females". Marine Mammal Science. 23 (4): 803–833. Bibcode:2007MMamS..23..803B. doi:10.1111/j.1748-7692.2007.00137.x.
  52. ^ Gilpatrick, J. W.; Perryman, W. L. (2008). "Geographic variation in external morphology of North Pacific and Southern Hemisphere blue whales (Balaenoptera musculus)". Journal of Cetacean Research and Management. 10 (1): 9–21. doi:10.47536/jcrm.v10i1.654. S2CID 256926335.
  53. Lockyer, C. (1976). "Body weights of some species of large whales". J. Cons. Int. Explor. Mer. 36 (3): 259–273. doi:10.1093/icesjms/36.3.259.
  54. "See the world's biggest heart". Archived from the original on 16 September 2020. Retrieved 21 August 2015.
  55. "Assessment and Update Status Report on the Blue Whale Balaenoptera musculus" (PDF). Committee on the Status of Endangered Wildlife in Canada. 2002. Retrieved 19 April 2007.
  56. McClain, Craig R.; Balk, Meghan A.; Benfield, Mark C.; Branch, Trevor A.; Chen, Catherine; Cosgrove, James; Dove, Alistair D.M.; Gaskins, Leo; Helm, Rebecca R.; Hochberg, Frederick G.; Lee, Frank B.; Marshall, Andrea; McMurray, Steven E.; Schanche, Caroline; Stone, Shane N.; Thaler, Andrew D. (13 January 2015). "Sizing ocean giants: patterns of intraspecific size variation in marine megafauna". PeerJ. 3: e715. doi:10.7717/peerj.715. PMC 4304853. PMID 25649000.
  57. Roston, Rachel A. (2013). "Anatomy and Age Estimation of an Early Blue Whale (Balaenoptera musculus) Fetus". The Anatomical Record. 296 (4): 709–722. doi:10.1002/ar.22678. PMID 23447333. Retrieved 23 November 2024.
  58. ^ "Blue whale". National Geographic. Archived from the original on 7 June 2022. Retrieved 3 March 2023.
  59. Purves, P. E. (1955). "The wax plug in the external auditory meatus of the". Discovery Reports. 27: 259–273.
  60. Gabriele, C. M.; Lockyer, C.; Straley, J. M.; Juasz, C. M.; Kato, H. (2010). "Sighting history of a naturally marked humpback whale (Megaptera novaeangliae) suggests ear plug growth layer groups are deposited annually". Marine Mammal Science. 26 (2): 443–450. Bibcode:2010MMamS..26..443G. doi:10.1111/j.1748-7692.2009.00341.x.
  61. Lockyer, C. (1984). "Age Determination by means of the ear plug in baleen whales". Report of the International Whaling Commission. 34: 692–696.
  62. "Blue whale". Whale and Dolphin Conservation. Archived from the original on 3 March 2023. Retrieved 3 March 2023.
  63. ^ Branch, T. A. (2008). "Biological parameters for pygmy blue whales". International Whaling Commission Document. SC/60/SH6: 13.
  64. Perrin, W. F.; Donovan, G. P. (1984). "Report of the Workshop". In Perrin, W. F.; Donovan, G. P.; DeMaster, D. P. (eds.). Reproduction in whales, dolphin and porpoises. Cambridge, UK: International Whaling Commission.
  65. ^ "Blue Whale". NOAA Fisheries. Retrieved 11 November 2019.
  66. Abrahms, B.; Hazen, E. L.; Aikens, E. O.; Savoca, M. S.; Goldbogen, J. A.; Goldbogen, S. J.; Jacox, M. G.; Irvine, L. M.; Palacios, D. M.; Mate, B. R. (2019). "Memory and resource tracking drive blue whale migrations". Proceedings of the National Academy of Sciences. 116 (12): 5582–5587. Bibcode:2019PNAS..116.5582A. doi:10.1073/pnas.1819031116. PMC 6431148. PMID 30804188.
  67. Geijer, C. K.; Notarbartolo di Sciara, G.; Panigada, S. (2016). "Mysticete migration revisited: Are Mediterranean fin whales an anomaly?". Mammal Review. 46 (4): 284–296. doi:10.1111/mam.12069.
  68. Segre, P. S.; Potvin, J; Cade, D. E.; Calambokidis, J; Di Clemente , J; Fish, F. E.; Friedlaender, A. S.; Gough, W. T.; Kahane-Rapport, S. R.; Oliveira, C; Parks, S. E.; Penry, G. S.; Simon, M; Stimpert, A. K.; Wiley, D. N.; Bierlich, K. C.; Madsen, P. T.; Goldbogen, J. A. (2020). "Energetic and physical limitations on the breaching performance of large whales". Physics of Living Systems. 9. doi:10.7554/eLife.51760. PMC 7065846. PMID 32159511.
  69. ^ Goldbogen, J. A.; Calambokidis, J.; Oleson, E.; Potvin, J.; Pyenson, N. D.; Schorr, G.; Shadwick, R. E. (2011). "Mechanics, hydrodynamics and energetics of blue whale lunge feeding: Efficiency dependence on krill density". Journal of Experimental Biology. 214 (1): 131–46. Bibcode:2011JExpB.214..131G. doi:10.1242/jeb.048157. PMID 21147977.
  70. Croll, D. A.; Aceveo-Gutierrez, A.; Tershy, B. R.; Urban-Ramirez, J. (2010). "The diving behavior of blue and fin whales: Is dive duration shorter than expected based on oxygen stores?". Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology. 129 (4): 797–809. doi:10.1016/S1095-6433(01)00348-8. PMID 11440866.
  71. Owen, K.; Jenner, C. S.; Jenner, M.-N. M.; Andrews, R. D. (2016). "A week in the life of a pygmy blue whale: migratory dive depth overlaps with large vessel drafts". Animal Biotelemetry. 4 (17): 1–11. Bibcode:2016AnBio...4...17O. doi:10.1186/s40317-016-0109-4.
  72. Goldbogen, J. A.; Cade, D. E.; Calambokidis, J.; Czapanskiy, M. F.; Fahlbusch, J.; Friedlaender, A. S.; Gough, W. T.; Kahane-Rapport, S. R.; Savoca, M. S.; Ponganis, K. V.; Ponganis, P. J. (2019). "Extreme bradycardia and tachycardia in the world's largest animal". Proceedings of the National Academy of Sciences. 116 (50): 25329–25332. Bibcode:2019PNAS..11625329G. doi:10.1073/pnas.1914273116. PMC 6911174. PMID 31767746.
  73. ^ Fossette, S.; Abrahms, B.; Hazen, E. L.; Bograd, S. J.; Zilliacus, K. M.; Calambokidis, J.; Burrows, J. A.; Goldbogen, J. A.; Harvey, J. T.; Marinovic, B.; Tershy, B.; Croll, D. A. (2017). "Resource partitioning facilitates coexistence in sympatric cetaceans in the California Current". Ecology and Evolution. 7 (1): 9085–9097. Bibcode:2017EcoEv...7.9085F. doi:10.1002/ece3.3409. PMC 5677487. PMID 29152200.
  74. Goldbogen, J. A.; Calambokidis, J.; Friedlaender, A. S.; Francis, J.; DeRuiter, A. L.; Stimpert, A. K.; Falcone, E.; Southall, B. L. (2012). "Underwater acrobatics by the world's largest predator: 360° rolling manoeuvres by lunge-feeding blue whales". Biology Letters. 9 (1): 20120986. doi:10.1098/rsbl.2012.0986. PMC 3565519. PMID 23193050.
  75. Barlow, Dawn R. (2023). "Shaped by their Environment: Variation in Blue Whale Morphology Across Three Productive Coastal Ecosystems". Integrative Organismal Biology. Retrieved 23 November 2024.
  76. Hazen, E. L.; Friedlaender, A. S.; Goldbogen, J. A. (2015). "Blue whales ("Balaenoptera musculus") optimize foraging efficiency by balancing oxygen use and energy gain as a function of prey density". Science Advances. 1 (9): e1500469. Bibcode:2015SciA....1E0469H. doi:10.1126/sciadv.1500469. PMC 4646804. PMID 26601290.
  77. Brodie, P. F. (1975). "Cetacean energetics, an overview of intraspecific size variation". Ecology. 56 (1): 152–161. Bibcode:1975Ecol...56..152B. doi:10.2307/1935307. JSTOR 1935307.
  78. Croll, D. A.; Kudela, R.; Tershy, B. R. (2006). "Ecosystem impact of the decline of large whales in the North Pacific". In Estes, J. A. (ed.). Whales, Whaling and Ocean Ecosystems. Berkeley, CA: University of California Press. pp. 202–214.
  79. ^ de Vos, Asha; Faux, Cassandra E.; Marthick, James; Dickinson, Joanne; Jarman, Simon N. (6 April 2018). "New Determination of Prey and Parasite Species for Northern Indian Ocean Blue Whales". Frontiers in Marine Science. 5. doi:10.3389/fmars.2018.00104. ISSN 2296-7745.
  80. Fiedler, Paul C.; Reilly, Stephen B.; Hewitt, Roger P.; Demer, David; Philbrick, Valerie A.; Smith, Susan; Armstrong, Wesley; Croll, Donald A.; Tershy, Bernie R.; Mate, Bruce R. (1 August 1998). "Blue whale habitat and prey in the California Channel Islands". Deep Sea Research Part II: Topical Studies in Oceanography. 45 (8): 1781–1801. Bibcode:1998DSRII..45.1781F. doi:10.1016/S0967-0645(98)80017-9. ISSN 0967-0645.
  81. Hardin, G. (1960). "The competitive exclusion principle". Science. 131 (3409): 1292–1297. Bibcode:1960Sci...131.1292H. doi:10.1126/science.131.3409.1292. PMID 14399717. S2CID 18542809.
  82. Hutchinson, G. E. (1961). "The Paradox of the Plankton". The American Naturalist. 95 (882): 137–145. Bibcode:1961ANat...95..137H. doi:10.1086/282171. S2CID 86353285.
  83. Pianka, E. R. (1974). "Niche overlap and diffuse competition". Proceedings of the National Academy of Sciences. 71 (5): 2141–2145. Bibcode:1974PNAS...71.2141P. doi:10.1073/pnas.71.5.2141. PMC 388403. PMID 4525324.
  84. Doniol-Valcroze, T. (2008). Habitat selection and niche characteristics of rorqual whales in the northern Gulf of St. Lawrence (Canada) (PhD). Montreal, Canada: McGill University.
  85. Friedlaender, A. S.; Goldbogen, J. A.; Hazen, E. L.; Calambokidis, J.; Southall, B. L. (2015). "Feeding performance by sympatric blue and fin whales exploiting a common prey resource". Marine Mammal Science. 31 (1): 345–354. Bibcode:2015MMamS..31..345F. doi:10.1111/mms.12134.
  86. Santora, J. A.; Reiss, C. S.; Loeb, V. J.; Veit, R. R. (2010). "Spatial association between hotspots of baleen whales and demographic patterns of Antarctic krill Euphausia superba suggests size-dependent predation". Marine Ecology Progress Series. 405: 255–269. Bibcode:2010MEPS..405..255S. doi:10.3354/meps08513.
  87. Melica, Valentina (2020). "Reproduction and Stress Response Endocrinology in Blue (Balaenoptera musculus) and Gray (Eschrichtius robust) Whales" (PDF). Scholarworks Alaska. Retrieved 23 November 2024.
  88. ^ Sears, R.; Perrin, W. F. (2018). "Blue Whale: "Balaenoptera musculus"". In Würsig, B.; Thewissen, J. G. M.; Kovacs, K. M. (eds.). Encyclopedia of marine mammals. London, UK: Academic Press. pp. 110–114.
  89. Ichihara T. (1964). "The pygmy blue whale, Balaenoptera musculus brevicauda, a new subspecies from Antarctic". Norsk. Hvalf. Tid. 6.
  90. Sazhinov E. G. (1970). "The onset of sexual and physical maturity for pygmy blue whales (Balaenoptera musculus brevicauda. Ichinara. 1966)". Whales of the Southern Hemisphere (29): 34–40.
  91. Branch, T. A.; Mikhalev, Y. A. (2008). "Regional differences in length at sexual maturity for female blue whales based on recovered Soviet whaling data". Marine Mammal Science. 24 (3): 690–703. Bibcode:2008MMamS..24..690B. doi:10.1111/j.1748-7692.2008.00214.x.
  92. Sears, R.; Ramp, C.; Douglas, A. B.; Calambokidis, J. (2013). "Reproductive parameters of eastern North Pacific blue whales Balaenoptera musculus". Endangered Species Research. 22 (1): 23–31. doi:10.3354/esr00532.
  93. ^ Schall, E.; Di Lorio, L.; Berchok, C.; Filún, D.; Bedriñana-Romano, L.; Buchan, S. J.; Van Opzeeland, I.; Sears, R.; Hucke-Gaete, R. (2019). "Visual and passive acoustic observations of blue whale trios from two distinct populations". Marine Mammal Science. 36 (1): 365–374. doi:10.1111/mms.12643. hdl:1912/24953.
  94. Sergeant, D. E. (1969). "Feeding rates of Cetacea". Fiskeridir. SKR. Havundersok. 15: 246–258.
  95. Lockyer, C. (1984). "Review of baleen whale (Mysticeti) reproduction and implications for management". Report of the International Whaling Commission. 6: 27–50.
  96. Oftedal, O. T. (1997). "Lactation in whales and dolphins: Evidence of divergence between baleen- and toothed-species". Journal of Mammary Gland Biology and Neoplasia. 2 (3): 205–230. doi:10.1023/A:1026328203526. PMID 10882306. S2CID 19588882.
  97. "Exclusive Video May Show Blue Whale Calf Nursing". National Geographic. 2 March 2016. Archived from the original on 31 December 2019. Retrieved 20 December 2019.
  98. Yamato, M.; Ketten, D. R.; Arruda, J.; Cramer, S. (2008). "Biomechanical and structural modeling of hearing in baleen whales". Bioacoustics. 17 (1–3): 100–102. Bibcode:2008Bioac..17..100Y. doi:10.1080/09524622.2008.9753781. S2CID 85314872.
  99. Stafford, K. M.; Fox, G. C.; Clark, D. S. (1998). "Long-range acoustic detection and localization of blue whale calls in the northeast Pacific Ocean". Journal of the Acoustical Society of America. 50 (4): 1193–1198. Bibcode:1998ASAJ..104.3616S. doi:10.1121/1.423944. PMID 9857519.
  100. McDonald, M. A.; Mesnick, S. L.; Hildebrand, J. A. (2023). "Biogeographic characterization of blue whale song worldwide: Using song to identify populations". Journal of Cetacean Research and Management. 8: 55–66. doi:10.47536/jcrm.v8i1.702. S2CID 18769917.
  101. Aroyan, J. L.; McDonald, M. A.; Webb, S. C.; Hildebrand, J. A.; Clark, D. S.; Laitman, J. T.; Reidenberg, J. S. (2000). "Acoustic models of sound production and propagation". In Au, W. W. A.; Popper, A.; Fay, R. N. (eds.). Hearing by whales and dolphins. New York: Springer-Verlag. p. 442.
  102. ^ McDonald, M. A.; Calambokidis, J.; Teranishi, A. M.; Hildebrand, J. A. (2001). "The acoustic calls of blue whales off California with gender data". Journal of the Acoustical Society of America. 109 (4): 1728–1735. Bibcode:2001ASAJ..109.1728M. doi:10.1121/1.1353593. PMID 11325141.
  103. ^ Oleson, E. M.; Calambokidis, J.; Burgess, W. C.; McDonald, M. A.; LeDuc, C. A.; Hildebrand, J. A. (2007). "Behavioral context of call production by eastern North Pacific blue whales". Marine Ecology Progress Series. 330: 269–284. Bibcode:2007MEPS..330..269O. doi:10.3354/meps330269.
  104. Lewis, L. A.; Calambokidis, J.; Stimpert, A. K.; Fahlbusch, J.; Friedlaender, A. S.; McKenna, M. F.; Mesnick, S.; Oleson, E. M.; Southall, B. L.; Szesciorka, A. S.; Sirovic, A. (2018). "Context-dependent variability in blue whale acoustic behaviour". Royal Society Open Science. 5 (8): 1080241. doi:10.1098/rsos.180241. PMC 6124089. PMID 30225013.
  105. ^ Stafford, K. M.; Chapp, E.; Bohnenstiel, D.; Tolstoy, M. (2010). "Seasonal detection of three types of "pygmy" blue whale calls in the Indian Ocean". Marine Mammal Science. 27 (4): 828–840. doi:10.1111/j.1748-7692.2010.00437.x.
  106. Ljungblad, D. K.; Clark, C. W.; Shimada, H. (1998). A comparison of sounds attributed to pygmy blue whales (Balaenoptera musculus brevicauda) recorded south of the Madagascar Plateau and those attributed to 'true' blue whales (Balaenoptera musculus) recorded off Antarctica (Report). Vol. 48. International Whaling Commission. pp. 439–442.
  107. Sirovic, A.; Hildebrand, J. A.; Wiggins, S. M.; McDonald, M. A.; Moore, S. E.; Thiele, D. (2004). "Seasonality of blue and fin whale calls and the influence of sea ice in the Western Antarctic Peninsula". Deep Sea Research Part II: Topical Studies in Oceanography. 51 (17–19): 2327–2344. Bibcode:2004DSRII..51.2327S. doi:10.1016/j.dsr2.2004.08.005.
  108. ^ Rankin, S.; Ljungblad, D.; Clark, C.; Kato, H. (2023). "Vocalisations of Antarctic blue whales, Balaenoptera musculus intermedia, recorded during the 2001/2002 and 2002/2003 IWC/SOWER circumpolar cruises, Area V, Antarctica". Journal of Cetacean Research and Management. 7: 13–20. doi:10.47536/jcrm.v7i1.752. S2CID 43993242.
  109. Sirovic, A.; Hildebrand, J. A.; Thiele, D. (2006). "Baleen whales in the Scotia Sea in January and February 2003". Journal of Cetacean Research and Management. 8: 161–171. doi:10.47536/jcrm.v8i2.712. S2CID 251277044.
  110. ^ Nieukirk, S. L.; Mellinger, D. K.; Hildebrand, J. A.; McDonald, M. A.; Dziak, R. P. (2005). Downward shift in the frequency of blue whale vocalizations. 16th Biennial Conference on the Biology of Marine Mammals. San Diego, CA. p. 205.
  111. ^ McDonald, M. A.; Hildebrand, J. A.; Mesnick, S. (2009). "Worldwide decline in tonal frequencies of blue whale songs". Endangered Species Research. 9: 13–21. doi:10.3354/esr00217.
  112. ^ Leroy, E. C.; Royer, J.-Y.; Bonnel, J.; Samaran, F. (2018). "Long-term and seasonal changes of large whale call frequency in the southern Indian Ocean". Journal of Geophysical Research: Oceans. 123 (11): 8568–8580. Bibcode:2018JGRC..123.8568L. doi:10.1029/2018JC014352. hdl:1912/10837. S2CID 135201588.
  113. Sears, R. (1990). "The Cortez blues". Whalewatcher. 24: 12–15.
  114. Mehta, A. V.; Allen, J. M.; Constantine, R.; Garrigue, C.; Jann, B.; Jenner, C.; Marx, M. K.; Matkin, C. O.; Mattila, D. K.; Minton, G.; Mizroch, S. A.; Olavarría, C.; Robbins, J.; Russell, K. G.; Seton, R. E. (2007). "Baleen whales are not important as prey for orcas (Orcinus orca) in high latitudes". Marine Ecology Progress Series. 348: 297–307. doi:10.3354/meps07015. hdl:1912/4520.
  115. Cotton, B. C. (1944). "Killer whales in South Australia". Australian Zoologist. 10: 293–294.
  116. Tarpy, C. (1979). "Killer whale attack!". National Geographic Magazine. 155: 542–545.
  117. Ford, J. K. B.; Reeves, R. (2008). "Fight or flight: antipredator strategies of baleen whales". Mammal Review. 38 (1): 50–86. doi:10.1111/j.1365-2907.2008.00118.x.
  118. Pitman, R.; Fearnbach, H.; LeDuc, R.; Gilpatrick, J. W.; Ford, J. K. B.; Balance, L. T. (2023). "Killer whales preying on a blue whale calf on the Costa Rica Dome: Genetics, morphometrics, vocalizations and composition of the group". Journal of Cetacean Research and Management. 9 (2): 151–158. doi:10.47536/jcrm.v9i2.683. S2CID 257138804.
  119. "Killer Whales Bully Lone Blue Whale in Rare Video". Live Science. 5 March 2014. Retrieved 23 December 2019.
  120. "Killer Whales Attacked a Blue Whale—Here's the Surprising Reason Why". National Geographic. 25 May 2017. Archived from the original on 31 December 2019. Retrieved 23 December 2019.
  121. Totterdell, J. A.; Wellard, R.; Reeves, I. M.; Elsdon, B.; Markovic, P.; Yoshida, M.; Fairchild, A.; Sharp, G.; Pitman, R. (2022). "The first three records of killer whales (Orcinus orca) killing and eating blue whales (Balaenoptera musculus)". Marine Mammal Science. 38 (3): 1286–1301. Bibcode:2022MMamS..38.1286T. doi:10.1111/mms.12906. S2CID 246167673.
  122. Hermosilla, C; Silva, L. M. R.; Prieto, R; Kleinertz, S; Taubert, A; Silva, M. A. (2015). "Endo- and ectoparasites of large whales (Cetartiodactyla: Balaenopteridae, Physeteridae): Overcoming difficulties in obtaining appropriate samples by non- and minimally-invasive methods". International Journal for Parasitology: Parasites and Wildlife. 4 (3): 414–420. Bibcode:2015IJPPW...4..414H. doi:10.1016/j.ijppaw.2015.11.002. PMC 4699982. PMID 26835249.
  123. Gambell, R. (1979). "The blue whale". Biologist. 26: 209–215.
  124. Best, P. B. (1993). "Increase rates in severely depleted stocks of baleen whales". ICES J. Mar. Sci. 50 (2): 169–186. Bibcode:1993ICJMS..50..169B. doi:10.1006/jmsc.1993.1018.
  125. Sigurjónsson, J. (1988). "Operational factors of the Icelandic large whale fishery". Reports of the International Whaling Commission. 38: 327–333.
  126. "Part 17 – Conservation of Endangered Species and Other Fish or Wildlife (First List of Endangered Foreign Fish and Wildlife as Appendix A)" (PDF). U.S. Fish & Wildlife Service. 2 June 1970. Archived (PDF) from the original on 9 October 2022. Retrieved 24 December 2019.
  127. "Appendices". Convention on International Trade in Endangered Species of Wild Fauna and Flora. 26 November 2019. Retrieved 24 December 2019.
  128. "Convention on the Conservation of Migratory Species of Wild Animals" (PDF). United Nations Environment Programme. 23 June 1979. Archived from the original (PDF) on 2 May 2020. Retrieved 24 December 2019.
  129. Samaran, F.; Stafford, K. M.; Branch, T. A.; Gedamke, J.; Royer, Y.-J.; Dziak, R. P.; Guinet, C. (2013). "Seasonal and geographic variation of southern blue whale subspecies in the Indian Ocean". PLOS ONE. 8 (8): e71561. Bibcode:2013PLoSO...871561S. doi:10.1371/journal.pone.0071561. PMC 3742792. PMID 23967221.
  130. "Blue Whale". International Union for Conservation. 6 December 2018. Retrieved 24 December 2019.
  131. Darby, Andrew (2009). Harpoon Into the Heart of Whaling. Hachette Books. pp. 38–39. ISBN 9780786732005.
  132. "Blue whale – Balaenoptera musculus". International Whaling Commission. Retrieved 25 February 2022.
  133. Ivashchenko, Y.; Clapham, P. J.; Brownell, R. (2011). "Soviet Illegal Whaling: The Devil and the Details" (PDF). Marine Fisheries Review. 73 (1): 1–19. Archived from the original (PDF) on 22 March 2022. Retrieved 26 January 2023.
  134. ^ Berman-Kowalewski, M.; Gulland, F.; Wilkin, S.; Calambokidis, J.; Mate, B.; Cordaro, J.; Rotstein, D.; St. Leger, J.; Collins, P.; Fahy, K.; Dover, S. (2010). "Association between blue whale mortality and ship strikes along the California coast". Aquatic Mammals. 36 (1): 59–66. doi:10.1578/AM.36.1.2010.59. S2CID 86304413.
  135. Abramson, L.; Polefka, S.; Hastings, S.; Bor, K. (2009). Reducing the Threat of Ship Strikes on Large Cetaceans in the Santa Barbara Channel Region and Channel Islands National Marine Sanctuary: Recommendations and Case Studies (Report). Channel Islands National Marine Sanctuary Advisory Council. pp. 1–73.
  136. de Vos, A.; Brownell, R. L. Jr.; Tershy, B. R.; Croll, D. A. (2016). "Anthropogenic threats and conservation needs of blue whales, "Balaenoptera musculus indica", around Sri Lanka". J. Mar. Biol. 2016 (8420846): 1–12. doi:10.1155/2016/8420846.
  137. Priyadarshana, T.; Randage, R.; Alling, A.; Calderan, S.; Gordon, J.; Leaper, R.; Porter, L. (2015). An update on work related to ship strike risk to Blue whales off southern Sri Lanka (Report). Vol. SC66A. The International Whaling Commission.
  138. Randage, S. M.; Alling, A.; Currier, K.; Heywood, E. (2023). "Review of the Sri Lanka blue whale (Balaenoptera musculus) with observations on its distribution in the shipping lane". Journal of Cetacean Research and Management. 14: 43–49. doi:10.47536/jcrm.v14i1.522. S2CID 46399716.
  139. Brownell, R. L. Jr.; Cabrera, E.; Galletti-Vernazzani, B. (2014). Dead blue whale in Puerto Montt, Chile: Another case of ship collision mortality (Report). Vol. SC/65b/HIM08. International Whaling Commission.
  140. International whaling Commission (2017). Report of the Scientific Committee (Report). International Whaling Commission. p. 136.
  141. Redfern, J. V.; McKenna, M. F.; Moore, T. J.; Calambokidis, J.; Deangelis, M. L.; Becker, E. A.; Barlow, J.; Forney, K. A.; Fiedler, P. C.; Chivers, S. J. (2013). "Assessing the risk of ships striking large whales in marine spatial planning". Conservation Biology. 22 (2): 292–302. Bibcode:2013ConBi..27..292R. doi:10.1111/cobi.12029. PMID 23521668. S2CID 17833403.
  142. Dransfield, A.; Hines, E.; McGowan, J.; Holzman, B.; Nur, N.; Elliott, M.; Howar, J.; Jacncke, J. (2014). "Where the whales are: using habitat modeling to support changes in shipping regulations within National Marine Sanctuaries in Central California". Endanger Species Res. 26 (1): 39–57. doi:10.3354/esr00627.
  143. Carretta, J. V.; Muto, M. M.; Greenman, J.; Wilkinson, K.; Viezbicke, J.; Jannot, J. (2017). Sources of human-related injury and mortality for U.S. Pacific west coast marine mammal stock assessments, 2011– 2015 (Report). Vol. PSRG-2017-07. NOAA.
  144. NMFS (2017). National Report on Large Whale Entanglements (Report). NOAA.
  145. de Vos, A. (2015). "Marine life on the line". In Braun, D. (ed.). Deepwater Horizon oil spill: Final Programmatic Damage Assessment and Restoration Plan and Final Programmatic Environmental Impact Statement. National Geographic. p. 685.
  146. Southall, B. L.; Hatch, L.; Scholik-Schlomer, A.; Bergmann, T.; Jasny, M.; Metcalf, K.; Weilgart, L.; Wright, A. J.; Perera, M. E. (2018). "Reducing noise from large commercial ships: progress and partnerships". Proc. Mar. Saf. Sec. Council. 1: 58–65.
  147. Wiggins, S. M.; Oleson, E. M.; Hildebrand, J. A. (2001). "Blue whale call intensity varies with ambient noise level". Journal of the Acoustical Society of America. 110 (5): 2771. Bibcode:2001ASAJ..110.2771W. doi:10.1121/1.4777708.
  148. McKenna, M. F.; Ross, D.; Wiggins, S. M.; Hildebrand, J. A. (2012). "Underwater radiated noise from modern commercial ships". The Journal of the Acoustical Society of America. 131 (1): 92–103. Bibcode:2012ASAJ..131...92M. doi:10.1121/1.3664100. PMID 22280574. S2CID 9474116.
  149. Szesciorka, A. R.; Allen, A. N.; Calambokidis, J.; Fahlbusch, J.; McKenna, M. F.; Southall, B. L. (2019). "A case study of a near vessel strike of a blue whale: perceptual cues and fine-scale aspects of behavioral avoidance". Front. Mar. Sci. 6 (761): 1–10. doi:10.3389/fmars.2019.00761.
  150. Di Iorio, L.; Clark, C. W. (2009). "Exposure to seismic survey alters blue whale acoustic communication". Biology Letters. 6 (1): 1–4.
  151. McDonald, M. A.; Hildebrand, J. A.; Webb, S. C. (1995). "Blue and fin whales observed on a seafloor array in the Northeast Pacific". Journal of the Acoustical Society of America. 98 (2): 712–721. Bibcode:1995ASAJ...98..712M. doi:10.1121/1.413565. PMID 7642810. S2CID 3829165.
  152. Melcón, M. L.; Cummins, A. J.; Kerosky, S. M.; Roche, L. K.; Wiggins, S. M.; Hildebrand, J. A. (2012). "Blue Whales Respond to Anthropogenic Noise". PLOS ONE. 7 (2): e32681. Bibcode:2012PLoSO...732681M. doi:10.1371/journal.pone.0032681. PMC 3290562. PMID 22393434.
  153. Southall, B. L.; DeRuiter, S. L.; Friedlaender, A.; Stimpert, A. K.; Goldbogen, J. A.; Hazen, E.; Casey, C.; Fregosi, S.; Cade, D. E.; Allen, A. N.; Harris, C. M.; Schorr, G.; Moretti, D. (2019). "Behavioral responses of individual blue whales (Balaenoptera musculus) to mid-frequency military sonar". The Journal of Experimental Biology. 222 (jeb190637): jeb190637. Bibcode:2019JExpB.222B0637S. doi:10.1242/jeb.190637. hdl:10023/19592. PMID 30833464.
  154. O'Shea, T. J.; Brownell, R. L. (1994). "Organochlorine and metal contaminants in baleen whales:a review and evaluation of conservation implications". Science of the Total Environment. 154 (2–3): 179–200. Bibcode:1994ScTEn.154..179O. doi:10.1016/0048-9697(94)90087-6. PMID 7973606.
  155. Trumble, S. J.; Robinson, E. M.; Berman-Kowalewski, M.; Potter, C. W.; Usenko, S. (2013). "Blue whale earplug reveals lifetime contaminant exposure and hormone profiles". Proceedings of the National Academy of Sciences. 110 (42): 16922–16926. Bibcode:2013PNAS..11016922T. doi:10.1073/pnas.1311418110. PMC 3801066. PMID 24043814.
  156. Metcalfe, C. D.; Koenig, B. G.; Metcalfe, T. L.; Paterson, G.; Sears, R. (2004). "Intra- and inter-species differences in persistent organic contaminants in the blubber of blue whales and humpback whales from the Gulf of St. Lawrence, Canada". Marine Environmental Research. 57 (4): 245–260. Bibcode:2004MarER..57..245M. doi:10.1016/j.marenvres.2003.08.003. PMID 14749058.

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Extant Cetacea species
Parvorder Mysticeti (Baleen whales)
Balaenidae
Balaena
Eubalaena
(Right whales)
Balaenopteridae
(Rorquals)
Balaenoptera
Eschrichtius
Megaptera
Cetotheriidae
Caperea
Parvorder Odontoceti (Toothed whales)
Delphinidae
(Oceanic dolphins)
Cephalorhynchus
Delphinus
Feresa
Globicephala
(Pilot whales)
Grampus
Lagenodelphis
Lagenorhynchus
Lissodelphis
(Right whale dolphins)
Orcaella
Orcinus
Peponocephala
Pseudorca
Sotalia
Sousa
(Humpback dolphins)
Stenella
Steno
Tursiops
(Bottlenose dolphins)
Monodontidae
Delphinapterus
Monodon
Phocoenidae
(Porpoises)
Neophocoena
(Finless porpoises)
Phocoena
Phocoenoides
Physeteridae
Physeter
Kogiidae
Kogia
Iniidae
Inia
Lipotidae
Lipotes
Platanistidae
Platanista
Pontoporiidae
Pontoporia
Ziphiidae
(Beaked whales)
Berardius
Hyperoodon
(Bottlenose whales)
Indopacetus
Mesoplodon
(Mesoplodont whales)
Tasmacetus
Ziphius
Taxon identifiers
Balaenoptera musculus
Balaena musculus
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