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Wikipedia

Pinniped

January 31, 2023

Pinnipeds (pronounced /ˈpɪnɪˌpɛdz/), commonly known as seals,[a] are a widely distributed and diverse clade of carnivorous, fin-footed, semiaquatic, mostly marine mammals. They comprise the extant families Odobenidae (whose only living member is the walrus), Otariidae (the eared seals: sea lions and fur seals), and Phocidae (the earless seals, or true seals). There are 34 extant species of pinnipeds, and more than 50 extinct species have been described from fossils. While seals were historically thought to have descended from two ancestral lines, molecular evidence supports them as a monophyletic lineage (descended from one ancestral line). Pinnipeds belong to the order Carnivora; their closest living relatives are musteloids (weasels, raccoons, skunks, and red pandas), having diverged about 50 million years ago.

Pinnipeds
Temporal range: Latest OligoceneHolocene, 24–0 Ma
Clockwise from top left: New Zealand fur seal (Arctocephalus forsteri), southern elephant seal (Mirounga leonina), Steller sea lion (Eumetopias jubatus), walrus (Odobenus rosmarus) and grey seal (Halichoerus grypus)
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Carnivora
Clade: Pinnipedimorpha
Clade: Pinnipediformes
Clade: Pinnipedia
Illiger, 1811[1]
Subclades
Range map

Seals range in size from the 1 m (3 ft 3 in) and 45 kg (99 lb) Baikal seal to the 5 m (16 ft) and 3,200 kg (7,100 lb) southern elephant seal male, which is also the largest member of the order Carnivora. Several species exhibit sexual dimorphism. They have streamlined bodies and four limbs that are modified into flippers. Though not as fast in the water as dolphins, seals are more flexible and agile. Otariids use their front limbs primarily to propel themselves through the water, while phocids and walruses use their hind limbs. Otariids and walruses have hind limbs that can be pulled under the body and used as legs on land. By comparison, terrestrial locomotion by phocids is more cumbersome. Otariids have visible external ears, while phocids and walruses lack these. Pinnipeds have well-developed senses—their eyesight and hearing are adapted for both air and water, and they have an advanced tactile system in their whiskers or vibrissae. Some species are well adapted for diving to great depths. They have a layer of fat, or blubber, under the skin to keep warm in the cold water, and, other than the walrus, all species are covered in fur.

Although pinnipeds are widespread, most species prefer the colder waters of the Northern and Southern Hemispheres. They spend most of their lives in the water, but come ashore to mate, give birth, molt or escape from predators, such as sharks and orcas. Seals mainly live in marine environments but can also be found in freshwater. They feed largely on fish and marine invertebrates; a few, such as the leopard seal, feed on large vertebrates, such as penguins and other seals. Walruses are specialized for feeding on bottom-dwelling mollusks. Male pinnipeds typically mate with more than one female (polygyny), although the degree of polygyny varies with the species. The males of land-breeding species tend to mate with a greater number of females than those of ice breeding species. Male pinniped strategies for reproductive success vary between defending females, defending territories that attract females and performing ritual displays or lek mating. Pups are typically born in the spring and summer months and females bear almost all the responsibility for raising them. Mothers of some species fast and nurse their young for a relatively short period of time while others take foraging trips at sea between nursing bouts. Walruses are known to nurse their young while at sea. Seals produce a number of vocalizations, notably the barks of California sea lions, the gong-like calls of walruses and the complex songs of Weddell seals.

The meat, blubber and fur coats of pinnipeds have traditionally been used by indigenous peoples of the Arctic. Seals have been depicted in various cultures worldwide. They are commonly kept in captivity and are even sometimes trained to perform tricks and tasks. Once relentlessly hunted by commercial industries for their products, seals and walruses are now protected by international law. The Japanese sea lion and the Caribbean monk seal have become extinct in the past century, while the Mediterranean monk seal and Hawaiian monk seal are ranked endangered by the International Union for Conservation of Nature. Besides hunting, pinnipeds also face threats from accidental trapping, marine pollution, and conflicts with local people.

Etymology

The name "pinniped" derives from the Latin words pinna "fin" and pes, pedis "foot".[2] The common name "seal" originates from the Old English word seolh, which is in turn derived from the Proto-Germanic *selkhaz.[3]

Taxonomy and evolution

Taxonomy

Further information: List of pinnipeds
Cladogram showing relationships among the living pinnipeds, found in Berta, Churchill and Boessenecker (2018). The Southern Hemisphere eared seal clade is not fully resolved.[4]

The German naturalist Johann Karl Wilhelm Illiger was the first to recognize the pinnipeds as a distinct taxonomic unit; in 1811 he gave the name Pinnipedia to both a family and an order.[5] American zoologist Joel Asaph Allen reviewed the world's pinnipeds in an 1880 monograph, History of North American pinnipeds, a monograph of the walruses, sea-lions, sea-bears and seals of North America. In this publication, he traced the history of names, gave keys to families and genera, described North American species and provided synopses of species in other parts of the world.[6] In 1989, Annalisa Berta and colleagues proposed the unranked clade Pinnipedimorpha to contain the fossil genus Enaliarctos and modern seals as a sister group.[7] Pinnipeds belong to the order Carnivora and the suborder Caniformia (known as dog-like carnivorans).[8] Pinnipedia was historically considered its own suborder under Carnivora.[9] Of the three extant families, the Otariidae and Odobenidae are grouped in the superfamily Otarioidea,[10] while the Phocidae belong to the superfamily Phocoidea.[11] There are 34 extant species of pinnipeds,[4] and more than 50 fossil species.[12]

Otariids are also known as eared seals due to the presence of pinnae. These animals rely on their well-developed fore-flippers to propel themselves through the water. They can also turn their hind-flippers forward and "walk" on land.[13] The anterior end of an otariid's frontal bones extends between the nasal bones, and the supraorbital foramen is large and flat horizontally. The supraspinatous fossas are divided by a "secondary spine" and the bronchi are divided anteriorly.[14] Otariids consist of two types: sea lions and fur seals. Sea lions are distinguished by their rounder snouts and shorter, rougher pelage, while fur seals have more pointed snouts, longer fore-flippers and thicker fur coats that include an undercoat and guard hairs. The former also tend to be larger than the latter.[15] Five genera and seven species (one now extinct) of sea lion are known to exist, while two genera and nine species of fur seal exist. While sea lions and fur seals have historically been considered separate subfamilies (Otariinae and Arctocephalinae respectively), a 2001 genetic study found that the northern fur seal is more closely related to several sea lion species.[16] This is supported by a 2006 molecular study that also found that the Australian sea lion and New Zealand sea lion are more closely related to Arctocephalus than to other sea lions.[17]

Odobenidae consists of only one living member: the modern walrus. This animal is easily distinguished from other extant pinnipeds by its larger size (exceeded only by the elephant seals), nearly hairless skin and long upper canines, known as tusks. Like otariids, walruses are capable of turning their hind-flippers forward and can walk on land. When moving in water, the walrus relies on its hind-flippers for locomotion, while its fore-flippers are used for steering. In addition, the walrus lacks external ear flaps.[18] Walruses have pterygoid bones that are broad and thick, frontal bones that are V-shaped at the anterior end and calcaneuses with pronounced tuberosity in the middle.[14]

Phocids are known as true or "earless" seals. These animals lack external ear flaps and are incapable of turning their hind-flippers forward, which makes them more cumbersome on land. In water, true seals swim by moving their hind-flippers and lower body from side to side.[13] Phocids have thickened mastoids, enlarged entotympanic bones, everted pelvic bones and massive ankle bones. They also lack supraorbital processes on the frontal and have underdeveloped calcaneal tubers.[14] A 2006 molecular study supports the division of phocids into two monophyletic subfamilies: Monachinae, which consists of Mirounga, Monachini and Lobodontini; and Phocinae, which includes Pusa, Phoca, Halichoerus, Histriophoca, Pagophilus, Erignathus and Cystophora.[17]

Evolutionary history

Further information: List of fossil pinnipedimorphs
 
Restoration of Puijila

One popular hypothesis suggested that pinnipeds are diphyletic (descended from two ancestral lines), with walruses and otariids sharing a recent common ancestor with bears and phocids sharing one with Musteloidea. However, morphological and molecular evidence support a monophyletic origin.[14] A 2021 genetic study found that pinnipeds are more closely related to musteloids.[19] Pinnipeds split from other caniforms 50 million years ago (mya) during the Eocene.[20] Their evolutionary link to terrestrial mammals was unknown until the 2007 discovery of Puijila in early Miocene deposits in Nunavut, Canada. Like a modern otter, Puijila had a long tail, short limbs and webbed feet instead of flippers. However, its limbs and shoulders were more robust and Puijila likely had been a quadrupedal swimmer—retaining a form of aquatic locomotion that gave rise to the major swimming types employed by modern pinnipeds. The researchers who found Puijila placed it in a clade with Potamotherium (traditionally considered a mustelid) and Enaliarctos. Of the three, Puijila was the least specialized for aquatic life. The discovery of Puijila in a lake deposit suggests that pinniped evolution went through a freshwater transitional phase.[21]

 
Fossil of Enaliarctos

Enaliarctos, a fossil species of late Oligocene/early Miocene (24–22 mya) California, closely resembled modern pinnipeds; it was adapted to an aquatic life with a flexible spine, and limbs modified into flippers. Its teeth were adapted for shearing (like terrestrial carnivorans), and it may have stayed near shore more often than its extant relatives. Enaliarctos was capable of swimming with both the fore-flippers and hind-flippers, but it may have been more specialized as a fore-flipper swimmer.[14] One species, Enaliarctos emlongi, exhibited notable sexual dimorphism, suggesting that this physical characteristic may have been an important driver of pinniped evolution.[22] A closer relative of extant pinnipeds was Pteronarctos, which lived in Oregon 19–15 mya. As in modern seals, Pteroarctos had an orbital wall that was not limited by certain facial bones (like the jugal or lacrimal bone), but was mostly shaped by the maxilla. The extinct family Desmatophocidae lived 23–10 mya in the North Atlantic and had elongated skulls, fairly large eyes, cheekbones connected by a mortised structure and rounded cheek teeth. They also were sexually dimorphic and may have been capable of propelling themselves with both the foreflippers and hindflippers.[14] Their phylogeny and evolutionary relationship to other pinnipeds is poorly understood[23] although it has been proposed that they may be closer to the otariids than the phocids.[24]

 
Fossil skull cast of Piscophoca sp. from Phocidae

The ancestors of the Otarioidea and Phocoidea diverged 33 mya.[20] Phocids are known to have existed for at least 15 million years,[14] and molecular evidence supports a divergence of the Monachinae and Phocinae lineages 22 mya.[17] The fossil monachine Monotherium and phocine Leptophoca were found in southeastern North America. The deep split between the lineages of Erignathus and Cystophora 17 mya suggests that the phocines migrated eastward and northward from the North Atlantic. The genera Phoca and Pusa could have arisen when a phocine lineage traveled from the Paratethys Sea to the Arctic Basin and subsequently went eastward. The ancestor of the Baikal seal migrated into Lake Baikal from the Arctic (via the Siberian ice sheet) and became isolated there. The Caspian seal's ancestor became isolated as the Paratethys shrank, leaving the animal in a small remnant sea, the Caspian Sea.[14] The monochines diversified southward. Monachus emerged in the Mediterranean and migrated to the Caribbean and then the central North Pacific.[25] The two extant elephant seal species diverged close to 4 mya after the Panamanian isthmus was formed.[17] The lobodontine lineage emerged around 9 mya and colonized the southern ocean in response to glaciation.[25]

 
Reconstruction of Archaeodobenus akamatsui family Odobenidae

The lineages of Otariidae and Odobenidae split almost 28 mya.[17] Otariids originated in the North Pacific. The earliest fossil Pithanotaria, found in California, is dated to 11 mya. The Callorhinus lineage split earlier at 16 mya. Zalophus, Eumetopias and Otaria diverged next, with the latter colonizing the coast of South America. Most of the other otariids diversified in the Southern Hemisphere. The earliest fossils of Odobenidae—Prototaria of Japan and Proneotherium of Oregon—date to 18–16 mya. These primitive walruses had much shorter canines and lived on a fish diet rather than a specialized mollusk diet like the modern walrus. Odobenids further diversified in the middle and late Miocene. Several species had enlarged upper and lower canines. The genera Valenictus and Odobenus developed elongated tusks. The lineage of the modern walrus may have spread from the North Pacific to the Caribbean (via the Central American Seaway) 8–5 mya and subsequently made it to the North Atlantic and returned to the North Pacific via the Arctic 1 mya. Alternatively, this lineage may have spread from the North Pacific to the Arctic and subsequently the North Atlantic during the Pleistocene.[14]

Anatomy and physiology

 
 
Skeleton of California sea lion (top) and southern elephant seal

Pinnipeds have streamlined, spindle-shaped bodies with reduced or non-existent external ear flaps, rounded heads, flexible necks, limbs modified into flippers, and small tails.[26][27] Pinniped skulls have large eye orbits, short snouts and a constricted interorbital region.[28] They are unique among carnivorans in that their orbital walls are mostly shaped by the maxilla which are not contained by certain facial bones.[14] Compared to other carnivorans, their teeth tend to be fewer in number (especially incisors and back molars), are pointed and cone-shaped, and lack carnassials.[29] The walrus has unique upper canines that are elongated into tusks.[30] The mammary glands and genitals of pinnipeds can retract into the body.[26]

Pinnipeds range in size from the 1 m (3 ft 3 in) and 45 kg (99 lb) Baikal seal to the 5 m (16 ft) and 3,200 kg (7,100 lb) southern elephant seal. Overall, they tend to be larger than other carnivorans; the southern elephant seal is the largest carnivoran.[26] Several species have male-biased sexual dimorphism that correlates with the degree of polygyny in a species: highly polygynous species like elephant seals are extremely sexually dimorphic, while less polygynous species have males and females that are closer in size. In lobodontine seals, females are slightly larger than males. Males of sexually dimorphic species also tend to have secondary sex characteristics, such as the prominent proboscis of elephant seals, the inflatable red nasal membrane of hooded seals and the thick necks and manes of otariids.[31][32] Despite a correlation between size dimorphism and the degree of polygyny, some evidence suggests that size differences between the sexes originated due to ecological differences and prior to the development of polygyny.[33][34]

 
Male and female South American sea lions, showing sexual dimorphism

Almost all pinnipeds have fur coats, the exception being the walrus, which is only sparsely covered. Even some fully furred species (particularly sea lions) are less haired than most land mammals.[35] In species that live on ice, young pups have thicker coats than adults. The individual hairs on the coat, known collectively as lanugo, can trap heat from sunlight and keep the pup warm.[36] Pinnipeds are typically countershaded, and are darker colored dorsally and lighter colored ventrally, which serves to eliminate shadows caused by light shining over the ocean water. The pure white fur of harp seal pups conceals them in their Arctic environment.[37] Some species, such as ribbon seals, ringed seals and leopard seals, have patterns of contrasting light and dark coloration. All fully furred species molt; phocids molt once a year, while otariids gradually molt all year.[38] Seals have a layer of subcutaneous fat known as blubber that is particularly thick in phocids and walruses.[26] Blubber serves both to keep the animals warm and to provide energy and nourishment when they are fasting. It can constitute as much as 50% of a pinniped's body weight. Pups are born with only a thin layer of blubber, but some species compensate for this with thick lanugos.[36]

Pinnipeds have a simple stomach that is similar in structure to terrestrial carnivores. Most species have neither a cecum nor a clear demarcation between the small and large intestines; the large intestine is comparatively short and only slightly wider than the small intestine. Small intestine lengths range from 8 times (California sea lion) to 25 times (elephant seal) the body length. The length of the intestine may be an adaptation to frequent deep diving, as the increased volume of the digestive tract serves as an extended storage compartment for partially digested food during submersion. Pinnipeds do not have an appendix.[39] As in most marine mammals, the kidneys are divided into small lobes and can effectively absorb water and filter out excess salt.[40]

Locomotion

 
 
Harbor seal (top) and California sea lion swimming. The former swims with its hind-flippers, the latter with its fore-flippers.

Pinnipeds have two pairs of flippers on the front and back, the fore-flippers and hind-flippers. The elbows and ankles are enclosed within the body.[41] Pinnipeds tend to be slower swimmers than cetaceans, typically cruising at 5–15 kn (9–28 km/h; 6–17 mph) compared to around 20 kn (37 km/h; 23 mph) for several species of dolphin. Seals are more agile and flexible,[35] and some otariids, such as the California sea lion, are capable of bending their necks backwards far enough to reach their hind-flippers, allowing them to make dorsal turns.[42] Pinnipeds have several adaptions for reducing drag. In addition to their streamlined bodies, they have smooth networks of muscle bundles in their skin that may increase laminar flow and make it easier for them to slip through water. They also lack arrector pili, so their fur can be streamlined as they swim.[35]

When swimming, otariids rely on their fore-flippers for locomotion in a wing-like manner similar to penguins and sea turtles.[43] Fore-flipper movement is not continuous, and the animal glides between each stroke.[42] Compared to terrestrial carnivorans, the fore-limbs of otariids are reduced in length, which gives the locomotor muscles at the shoulder and elbow joints greater mechanical advantage;[41] the hind-flippers serve as stabilizers.[35] Phocids and walruses swim by moving their hind-flippers and lower body from side to side,[43] while their fore-flippers are mainly used for steering.[41] Some species leap out of the water, which may allow them to travel faster. In addition, sea lions are known to "ride" waves, which probably helps them decrease their energy usage.[35]

Pinnipeds can move around on land, though not as well as terrestrial animals. Otariids and walruses are capable of turning their hind-flippers forward and under the body so they can "walk" on all fours.[44] The fore-flippers move in a transverse, rather than a sagittal fashion. Otariids rely on their head. neck and back spine more than their hind-flippers during terrestrial locomotion.[45] By swinging their heads and necks, otariids create momentum while they are moving. Sea lions have been recorded climbing up flights of stairs. Phocids are less agile on land. They cannot pull their hind-flippers forward, and move on land by lunging, bouncing and wiggling while their fore-flippers keep them balanced. Some species use their fore-flippers to pull themselves forward. Terrestrial locomotion is easier for phocids on ice, as they can sled along.[44]

Senses

 
Light reflection on an elephant seal eye

The eyes of pinnipeds are relatively large for their size and are positioned near the front of the head. One exception is the walrus, whose smaller eyes are located on the sides of its head.[46][47] This is because it feeds on immobile bottom dwelling mollusks and hence does not need acute vision.[46] A seal's eye is adapted for seeing both underwater and in air. The lens is mostly spherical, and much of the retina is equidistant from the lens center. The cornea has a flattened center where refraction is nearly equal in both water and air. Pinnipeds also have very muscular and vascularized irises. The well-developed dilator muscle gives the animals a great range in pupil dilation. When contracted, the pupil is typically pear-shaped, although the bearded seal's is more diagonal. In species that live in shallow water, such as harbor seals and California sea lions, dilation varies little, while the deep-diving elephant seals have much greater variation.[48]

 
Frontal view of brown fur seal head

On land, pinnipeds are near-sighted in dim light. This is reduced in bright light, as the retracted pupil reduces the lens and cornea's ability to bend light. They also have a well-developed tapetum lucidum, a reflecting layer that increases sensitivity by reflecting light back through the rods. This helps them see in low-light conditions.[46] Ice-living seals like the harp seal have corneas that can tolerate high levels of ultraviolet radiation typical of bright, snowy environments. As such, they do not suffer snow blindness.[49] Pinnipeds appear to have limited color vision, as they lack S-cones.[50] Flexible eye movement has been documented in seals.[51] The extraocular muscles of the walrus are well developed. This and its lack of orbital roof allow it to protrude its eyes and see in both frontal and dorsal directions.[52] Seals release large amounts of mucus to protect their eyes.[35] The corneal epithelium is keratinized and the sclera is thick enough to withstand the pressures of diving. As in many mammals and birds, pinnipeds possess nictitating membranes.[53]

The pinniped ear is adapted for hearing underwater, where it can hear sound frequencies at up to 70,000 Hz. In air, hearing is somewhat reduced in pinnipeds compared to many terrestrial mammals. While they are capable of hearing a wide range of frequencies (e.g. 500 to 32,000 Hz in the northern fur seal, compared to 20 to 20,000 Hz in humans), their airborne hearing sensitivity is weaker overall.[54] One study of three species—the harbor seal, California sea lion and northern elephant seal—found that the sea lion was best adapted for airborne hearing, the harbor seal was equally capable of hearing in air and water, and the elephant seal was better adapted for underwater hearing.[55] Although pinnipeds have a fairly good sense of smell on land,[56] it is useless underwater as their nostrils are closed.[57]

 
Vibrissae of walrus

Pinnipeds have well-developed tactile senses. Their mystacial vibrissae have ten times the innervation of terrestrial mammals, allowing them to effectively detect vibrations in the water.[58] These vibrations are generated, for example, when a fish swims through water. Detecting vibrations is useful when the animals are foraging and may add to or even replace vision, particularly in darkness.[59] Harbor seals have been observed following varying paths of another seal that swam ahead several minutes before, similar to a dog following a scent trail,[60][61] and even to discriminate the species and the size of the fish responsible for the trail.[62] Blind ringed seals have even been observed successfully hunting on their own in Lake Saimaa, likely relying on their vibrissae to gain sensory information and catch prey.[63]

Unlike terrestrial mammals, such as rodents, pinnipeds do not move their vibrissae over an object when examining it but instead extend their moveable whiskers and keep them in the same position.[59] By holding their vibrissae steady, pinnipeds are able to maximize their detection ability.[64] The vibrissae of phocids are undulated and wavy while otariid and walrus vibrissae are smooth.[65] Research is ongoing to determine the function, if any, of these shapes on detection ability. The vibrissa's angle relative to the flow, not the shape, however, seems to be the most important factor.[64] The vibrissae of some otariids grow quite long—those of the Antarctic fur seal can reach 41 cm (16 in).[66] Walruses have the most vibrissae, at 600–700 individual hairs. These are important for detecting their prey on the muddy sea floor. In addition to foraging, vibrissae may also play a role in navigation; spotted seals appear to use them to detect breathing holes in the ice.[67]

Diving adaptations

See also: Physiology of underwater diving § Pinnipeds
 
Weddell seal underwater

Before diving, pinnipeds typically exhale to empty their lungs of half the air[68] and then close their nostrils and throat cartilages to protect the trachea.[69] Their unique lungs have airways that are highly reinforced with cartilaginous rings and smooth muscle, and alveoli that completely deflate during deeper dives.[70][71] While terrestrial mammals are generally unable to empty their lungs,[72] pinnipeds can reinflate their lungs even after complete respiratory collapse.[73] The middle ear contains sinuses that probably fill with blood during dives, preventing middle ear squeeze.[74] The heart of a seal is moderately flattened to allow the lungs to deflate. The trachea is flexible enough to collapse under pressure.[68] During deep dives, any remaining air in their bodies is stored in the bronchioles and trachea, which prevents them from experiencing decompression sickness, oxygen toxicity and nitrogen narcosis. In addition, seals can tolerate large amounts of lactic acid, which reduces skeletal muscle fatigue during intense physical activity.[74]

The main adaptations of the pinniped circulatory system for diving are the enlargement and increased complexity of veins to increase their capacity. Retia mirabilia form blocks of tissue on the inner wall of the thoracic cavity and the body periphery. These tissue masses, which contain extensive contorted spirals of arteries and thin-walled veins, act as blood reservoirs that increase oxygen stores for use during diving.[75] As with other diving mammals, pinnipeds have high amounts of hemoglobin and myoglobin stored in their blood and muscles. This allows them to stay submerged for long periods of time while still having enough oxygen. Deep-diving species such as elephant seals have blood volumes that represent up to 20% of their body weight. When diving, they reduce their heart rate and maintain blood flow only to the heart, brain and lungs. To keep their blood pressure stable, phocids have an elastic aorta that dissipates some of the energy of each heartbeat.[74]

Thermoregulation

 
Northern elephant seal resting in water

Pinnipeds conserve heat with their large and compact body size, insulating blubber and fur, and high metabolism.[76] In addition, the blood vessels in their flippers are adapted for countercurrent exchange. Veins containing cool blood from the body extremities surround arteries, which contain warm blood received from the core of the body. Heat from the arterial blood is transferred to the blood vessels, which then recirculate blood back to the core.[77] The same adaptations that conserve heat while in water tend to inhibit heat loss when out of water. To counteract overheating, many species cool off by flipping sand onto their backs, adding a layer of cool, damp sand that enhances heat loss. The northern fur seal pants to help stay cool, while monk seals often dig holes in the sand to expose cooler layers to rest in.[78]

Sleep

Pinnipeds spend many months at a time at sea, so they must sleep in the water. Scientists have recorded them sleeping for minutes at a time while slowly drifting downward in a belly-up orientation. Like other marine mammals, seals sleep in water with half of their brain awake so that they can detect and escape from predators.[79] When they are asleep on land, both sides of their brain go into sleep mode.[80]

Distribution and habitat

 
Walrus on ice off Alaska. This species has a discontinuous distribution around the Arctic Circle.

Living pinnipeds mainly inhabit polar and subpolar regions, particularly the North Atlantic, the North Pacific and the Southern Ocean. They are entirely absent from Indomalayan waters.[81] Monk seals and some otariids live in tropical and subtropical waters. Seals usually require cool, nutrient-rich waters with temperatures lower than 20 °C (68 °F). Even those that live in warm or tropical climates live in areas that become cold and nutrient rich due to current patterns.[81][82] Only monk seals live in waters that are not typically cool or rich in nutrients.[81] The Caspian seal and Baikal seal are found in large landlocked bodies of water (the Caspian Sea and Lake Baikal respectively).

As a whole, pinnipeds can be found in a variety of aquatic habitats, including coastal water, open ocean, brackish water and even freshwater lakes and rivers. The Baikal seal is the only exclusively freshwater species. Most seals inhabit coastal areas, though some travel offshore and feed in deep waters off oceanic islands.[83] Pinnipeds also use a number of terrestrial habitats and substrates, both continental and island. In temperate and tropical areas, they haul out on to sandy and pebble beaches, rocky shores, shoals, mud flats, tide pools and in sea caves. Some species also rest on man-made structures, like piers, jetties, buoys and oil platforms. Pinnipeds may move further inland and rest in sand dunes or vegetation, and may even climb cliffs.[84] New Zealand sea lions are the only pinnipeds that can be found up to 2 kilometres (1.2 mi) inland in forests.[85][86][87] Polar-living species haul out on to both fast ice and drift ice.[88] They use the ice platforms for breeding and raising young seal pups.[89] Ringed seals build dens underneath fast ice.[90]

Behavior and life history

 
Harbor seal hauled out on rock

Pinnipeds have an amphibious lifestyle; they spend most of their lives in the water, but haul out to mate, raise young, molt, rest, thermoregulate or escape from aquatic predators. Several species are known to migrate vast distances, particularly in response to extreme environmental changes, like El Niño or changes in ice cover. Elephant seals stay at sea 8–10 months a year and migrate between breeding and molting sites. The northern elephant seal has one of the longest recorded migration distances for a mammal, at 18,000–21,000 km (11,000–13,000 mi). Phocids tend to migrate more than otariids.[91] Traveling seals may use various features of their environment to reach their destination including geomagnetic fields, water and wind currents, the position of the sun and moon and the taste and temperature of the water.[92]

Pinnipeds may dive during foraging or to avoid predators. When foraging, for example, the Weddell seal typically dives for less than 15 minutes to depths of around 400 m (1,300 ft) but can dive for as long as 73 minutes and to depths of up to 600 m (2,000 ft). Northern elephant seals commonly dive 350–650 m (1,150–2,130 ft) for as long as 20 minutes. They can also dive 1,500 m (4,900 ft) and for as long as 77 minutes.[93] The dives of otariids tend to be shorter and less deep. They typically last 5–7 minutes with average depths to 30–45 m (98–148 ft). However, the New Zealand sea lion has been recorded diving to a maximum of 460 m (1,510 ft) and a duration of 12 minutes.[94] Walruses do not often dive very deep, as they feed in shallow water.[95]

Pinnipeds have lifespans averaging 25–30 years. Females usually live longer, as males tend to fight and often die before reaching maturity.[96] The longest recorded lifespans include 43 years for a wild female ringed seal and 46 years for a wild female grey seal.[97] The age at which a pinniped sexually matures can vary from 2–12 years depending on the species. Females typically mature earlier than males.[98]

Foraging and predation

 
Steller sea lion with white sturgeon

All pinnipeds are carnivorous and predatory. As a whole, they mostly feed on fish and cephalopods, followed by crustaceans and bivalves, and then zooplankton and endothermic ("warm-blooded") prey like sea birds.[99] While most species are generalist and opportunistic feeders, a few are specialists. Examples include the crabeater seal, which primarily eats krill, the ringed seal, which eats mainly crustaceans, the Ross seal and southern elephant seal, which specialize on squid, and the bearded seal and walrus, which feed on clams and other bottom-dwelling invertebrates.[81]

Pinnipeds may hunt solitarily or cooperatively. The former behavior is typical when hunting non-schooling fish, slow-moving or immobile invertebrates or endothermic prey. Solitary foraging species usually exploit coastal waters, bays and rivers. An exception to this is the northern elephant seal, which feeds on fish at great depths in the open ocean. In addition, walruses feed solitarily but are often near other walruses in small or large groups that may surface and dive in unison. When large schools of fish or squid are available, pinnipeds such as certain otariids hunt cooperatively in large groups, locating and herding their prey. Some species, such as California and South American sea lions, may forage with cetaceans and sea birds.[100]

Seals typically consume their prey underwater where it is swallowed whole. Prey that is too large or awkward is taken to the surface to be torn apart.[101] The leopard seal, a prolific predator of penguins, is known to violently swing its prey back and forth until it is dead.[102] The elaborately cusped teeth of filter-feeding species, such as crabeater seals, allow them to remove water before they swallow their planktonic food.[81] The walrus is unique in that it consumes its prey by suction feeding, using its tongue to suck the meat of a bivalve out of the shell.[47] While pinnipeds mostly hunt in the water, South American sea lions are known to chase down penguins on land.[103] Some species may swallow stones or pebbles for reasons not understood.[104] Though they can drink seawater, pinnipeds get most of their fluid intake from the food they eat.[40]

Pinnipeds themselves are subject to predation. Most species are preyed on by the orca. To subdue and kill seals, orcas continuously ram them with their heads, slap them with their tails and fling them in the air. They are typically hunted by groups of 10 or fewer whales, but they are occasionally hunted by larger groups or by lone individuals. Pups are more commonly taken by orcas, but adults can be targeted as well. Large sharks are another major predator of pinnipeds—usually the great white shark but also the tiger shark and mako shark. Sharks usually attack by ambushing them from below. The prey usually escapes, and seals are often seen with shark-inflicted wounds. Otariids typically have injuries in the hindquarters, while phocids usually have injuries on the forequarters.[105] Pinnipeds are also targeted by terrestrial and pagophilic predators. The polar bear is well adapted for hunting Arctic seals and walruses, particularly pups. Bears are known to use sit-and-wait tactics as well as active stalking and pursuit of prey on ice or water. Other terrestrial predators include cougars, brown hyenas and various species of canids, which mostly target the young.[105]

 
Orca hunting a Weddell seal

Pinnipeds lessen the chance of predation by gathering in groups.[106] Some species are capable of inflicting damaging wounds on their attackers with their sharp canines—an adult walrus is capable of killing polar bears.[105] When out at sea, northern elephant seals dive out of the reach of surface-hunting orcas and white sharks.[79] In the Antarctic, which lacks terrestrial predators, pinniped species spend more time on the ice than their Arctic counterparts.[107] Arctic seals use more breathing holes per individual, appear more restless when hauled out, and rarely defecate on the ice. Ringed seals rely on their dens for protection.[90]

Interspecific predation among pinnipeds does occur. The leopard seal is known to prey on numerous other species, especially the crabeater seal. Leopard seals typically target crabeater pups, which form an important part of their diet from November to January. Older crabeater seals commonly bear scars from failed leopard seal attacks; a 1977 study found that 75% of a sample of 85 individual crabeaters had these scars.[108] Walruses, despite being specialized for feeding on bottom-dwelling invertebrates, occasionally prey on Arctic seals. They kill their prey with their long tusks and eat their blubber and skin. Steller sea lions have been recorded eating the pups of harbor seals, northern fur seals and California sea lions. New Zealand sea lions feed on pups of some fur seal species, and the South American sea lion may prey on South American fur seals.[105]

Reproductive behavior

 
Walrus herd on ice floe

The mating system of pinnipeds varies from extreme polygyny to serial monogamy.[109] Of the 33 species, 20 breed on land, and the remaining 13 breed on ice.[110] Species that breed on land are usually polygynous, as females gather in large aggregations and males are able to mate with them as well as defend them from rivals. Polygynous species include elephant seals, grey seals and most otariids.[31] Land-breeding pinnipeds tend to mate on islands where there are fewer terrestrial predators. Few islands are favorable for breeding, and those that are tend to be crowded. Since the land they breed on is fixed, females return to the same sites for many years. The males arrive earlier in the season and wait for them. The males stay on land and try to mate with as many females as they can; some of them will even fast. If a male leaves the beach to feed, he will likely lose mating opportunities and his dominance.[111]

Polygynous species also tend to be extremely sexual dimorphic in favor of males. This dimorphism manifests itself in larger chests and necks, longer canines and denser fur—all traits that help males in fights for females. Increased body weight in males increases the length of time they can fast due to the ample energy reserves stored in the blubber.[31] Larger males also likely enjoy access to feeding grounds that smaller ones are unable to access due to their lower thermoregulatory ability and decreased energy stores.[33] In some instances, only the largest males are able to reach the furthest deepest foraging grounds where they enjoy maximum energetic yields that are unavailable to smaller males and females.[112]

Other seals, like the walrus and most phocids, breed on ice with copulation usually taking place in the water (a few land-breeding species also mate in water).[31][113][114] Females of these species tend to aggregate less. In addition, since ice is less stable than solid land, breeding sites change location each year, and males are unable to predict where females will stay during the breeding season. Hence polygyny tends to be weaker in ice-breeding species. An exception to this is the walrus, where females form dense aggregations perhaps due to their patchy food sources. Pinnipeds that breed on fast ice tend to cluster together more than those that breed on drift ice.[113] Some of these species are serially monogamous, including the harp seal, crabeater seal and hooded seal.[115] Seals that breed on ice tend to have little or no sexual dimorphism. In lobodontine seals, females are slightly longer than males. Walruses and hooded seals are unique among ice-breeding species in that they have pronounced sexual dimorphism in favor of males.[31][113]

 
Northern fur seal breeding colony

Adult male pinnipeds have several strategies to ensure reproductive success. Otariids establish territories containing resources that attract females, such as shade, tide pools or access to water. Territorial boundaries are usually marked by natural breaks in the substrate,[116] and some may be fully or partially underwater.[117][118] Males defend their territorial boundaries with threatening vocalizations and postures, but physical fights are usually avoided.[119] Individuals also return to the same territorial site each breeding season. In certain species, like the Steller sea lion and northern fur seal, a dominant male can maintain a territory for as long as 2–3 months. Females can usually move freely between territories and males are unable to coerce them, but in some species such as the northern fur seal, South American sea lion and Australian sea lion, males can successfully contain females in their territories and prevent them from leaving. In some phocid species, like the harbor seal, Weddell seal and bearded seal, the males have underwater territories called "maritories" near female haul-out areas.[116] These are also maintained by vocalizations.[120] The maritories of Weddell seal males can overlap with female breathing holes in the ice.[113]

 
Male northern elephant seals fighting for dominance and females

Lek systems are known to exist among some populations of walruses.[116] These males cluster around females and try to attract them with elaborate courtship displays and vocalizations.[116][121] Lekking may also exist among California sea lions, South American fur seals, New Zealand sea lions and harbor seals.[116][122] In some species, including elephant seals and grey seals, males will try to lay claim to the desired females and defend them from rivals.[116] Elephant seal males establish dominance hierarchies with the highest ranking males—the alpha males—maintaining harems of as many as 30–100 females. These males commonly disrupt the copulations of their subordinates while they themselves can mount without inference. They will, however, break off mating to chase off a rival.[123] Grey seal males usually claim a location among a cluster of females whose members may change over time,[124] while males of some walrus populations try to monopolize access to female herds.[116] Male harp seals, crabeater seals and hooded seals follow and defend lactating females in their vicinity—usually one or two at a time,[125] and wait for them to reach estrus.[115][116]

Younger or subdominant male pinnipeds may attempt to achieve reproductive success in other ways. Subadult elephant seals will sneak into female clusters and try to blend in by pulling in their noses. They also harass and attempt to mate with females that head out to the water. In otariid species like the South American and Australian sea lions, non-territorial subadults form "gangs" and cause chaos within the breeding rookeries to increase their chances of mating with females.[126] Alternative mating strategies also exist in young male grey seals, which do have some success.[124]

Female pinnipeds do appear to have some choice in mates, particularly in lek-breeding species like the walrus, but also in elephant seals where the males try to dominate all the females that they want to mate with.[121] When a female elephant seal or grey seal is mounted by an unwanted male, she tries to squirm and get away, while croaking and slapping him with her tail. This commotion attracts other males to the scene, and the most dominant will end the copulation and attempt to mate with the female himself.[127][128] Dominant female elephant seals stay in the center of the colony where they are more likely to mate with a dominant male, while peripheral females are more likely to mate with subordinates.[129] Female Steller sea lions are known to solicit mating with their territorial males.[121]

Birth and parenting

With the exception of the walrus, which has five- to six-year-long inter-birth intervals, female pinnipeds enter estrous shortly after they give birth.[130] All species go through delayed implantation, wherein the embryo remains in suspended development for weeks or months before it is implanted in the uterus. Delayed implantation postpones the birth of young until the female hauls-out on land or until conditions for birthing are favorable.[130][131] Gestation in seals (including delayed implantation) typically lasts a year.[130] For most species, birthing takes place in the spring and summer months.[132] Typically, single pups are born;[130] twins are uncommon and have high mortality rates.[131] Pups of most species are born precocial.[130]

 
Harp seal mother nursing pup

Unlike terrestrial mammals, pinniped milk has little to no lactose.[133] Mother pinnipeds have different strategies for maternal care and lactation. Phocids such as elephant seals, grey seals and hooded seals remain on land or ice and fast during their relatively short lactation period–four days for the hooded seal and five weeks for elephant seals. The milk of these species consist of up to 60% fat, allowing the young to grow fairly quickly. In particular, northern elephant seal pups gain 4 kg (9 lb) each day before they are weaned. Some pups may try to steal extra milk from other nursing mothers and gain weight more quickly than others. Alloparenting occurs in these fasting species;[130] while most northern elephant seal mothers nurse their own pups and reject nursings from alien pups, some do accept alien pups with their own.[134]

 
Adult Antarctic fur seal with pups

For otariids and some phocids like the harbor seal, mothers fast and nurse their pups for a few days at a time. In between nursing bouts, the females leave their young onshore to forage at sea. These foraging trips may last anywhere between a day and two weeks, depending on the abundance of food and the distance of foraging sites. While their mothers are away, the pups will fast.[130] Lactation in otariids may last 6–11 months; in the Galápagos fur seal it can last as long as 3 years. Pups of these species are weaned at lower weights than their phocid counterparts.[135] Walruses are unique in that mothers nurse their young at sea.[130] The female rests at the surface with its head held up, and the young suckle upside down.[136] Young pinnipeds typically learn to swim on their own and some species can even swim at birth. Other species may wait days or weeks before entering the water. Elephant seals do not swim until weeks after they are weaned.[137]

Male pinnipeds generally play little role in raising the young.[138] Male walruses may help inexperienced young as they learn to swim, and have even been recorded caring for orphans.[139] Male California sea lions have been observed to help shield swimming pups from predators.[140] Males can also pose threats to the safety of pups. In terrestrially breeding species, pups may get crushed by fighting males.[138] Subadult male South America sea lions sometimes abduct pups from their mothers and treat them like adult males treat females. This helps them gain experience in controlling females. Pups can get severely injured or killed during abductions.[141] Female New Zealand sea lions move inland with their pups to protect them.[85][86]

Communication

 
Walrus males are known to use vocalizations to attract mates.

Pinnipeds can produce a number of vocalizations such as barks, grunts, rasps, rattles, growls, creaks, warbles, trills, chirps, chugs, clicks and whistles. While most vocals are audible to the human ear, a captive leopard seal was recorded making ultrasonic calls underwater. In addition, the vocals of northern elephant seals may produce infrasonic vibrations. Vocals are produced both in air and underwater. Otariids are more vocal on land, while phocids are more vocal in water. Antarctic seals are more vocal on land or ice than Arctic seals due to a lack of terrestrial and pagophilic predators like the polar bear.[120] Male vocals are usually of lower frequencies than those of the females.[142]

Vocalizations are particularly important during the breeding seasons. Dominant male elephant seals advertise their status and threaten rivals with "clap-threats" and loud drum-like calls[143] that may be modified by the proboscis.[144] Male otariids have strong barks, growls, roars and "whickers". Male walruses are known to produce distinctive gong-like calls when attempting to attract females. They can also create somewhat musical sounds with their inflated throats.[143]

The Weddell seal has perhaps the most elaborate vocal repertoire with separate sounds for airborne and underwater contexts.[145] Underwater vocals include trills, chirps, chugs and knocks. The calls appear to contain prefixes and suffixes that serve to emphasize a message.[120] The underwater vocals of Weddell seals can last 70 seconds, which is long for a marine mammal call. Some calls have around seven rhythm patterns and are comparable to birdsongs and whalesongs.[146] Similar calls have been recorded in other lobodontine seals[147] and in bearded seals.[148]

In some pinniped species, there appear to be geographic differences in vocalizations, known as dialects,[149] while certain species may even have individual variations in expression.[150] These differences are likely important for mothers and pups who need to remain in contact on crowded beaches.[142] Otariid females and their young use mother-pup attraction calls to help them reunite when the mother returns from foraging at sea.[142] The calls are described are "loud" and "bawling".[151] Female elephant seals make an unpulsed attraction call when responding to their young. When threatened by other adults or when pups try to suckle, females make a harsh, pulsed call.[152] Pups may also vocalize when playing, in distress or when prodding their mothers to allow them to suckle.[151][152]

 
Sea lion balancing a ball

Non-vocal communication is not as common in pinnipeds as in cetaceans. Nevertheless, when disturbed by intruders harbor seals and Baikal seals may slap their fore-flippers against their bodies as warnings. Teeth chattering, hisses and exhalations are also made as aggressive warnings. Visual displays also occur: Weddell seals will make an S-shaped posture when patrolling under the ice, and Ross seals will display the stripes on their chests and teeth when approached.[120] Male hooded seals use their inflatable nasal membranes to display to and attract females.[32]

Intelligence

In a match-to-sample task study, a single California sea lion was able to demonstrate an understanding of symmetry, transitivity and equivalence; a second seal was unable to complete the tasks.[153] They demonstrate the ability to understand simple syntax and commands when taught an artificial sign language, though they only rarely used the signs semantically or logically.[154] In 2011, a captive California sea lion named Ronan was recorded bobbing its head in synchrony to musical rhythms. This "rhythmic entrainment" was previously seen only in humans, parrots and other birds possessing vocal mimicry.[155] Adult male elephant seals appear to memorize both the rhythm and timbre of their rivals' calls.[156] In 1971, a captive harbor seal named Hoover was trained to imitate human words, phrases and laughter.[157]

For sea lions used in entertainment, trainers toss a ball at the animal so it may accidentally balance it or hold the ball on its nose, thereby gaining an understanding of the behavior desired. It may require a year to train a sea lion to perform a trick for the public. Its long-term memory allows it to perform a trick after at least three months of non-performance.[140]

Human relations

Cultural depictions

Further information: List of fictional pinnipeds
 
Inuit seal sculptures at the Linden Museum

Various human cultures have for millennia depicted pinnipeds. The anthropologist, A. Asbjørn Jøn, has analysed beliefs of the Celts of Orkney and Hebrides who believed in selkies—seals that could change into humans and walk on land.[158] Seals are also of great importance in the culture of the Inuit.[159] In Inuit mythology, the goddess Sedna rules over the sea and marine animals. She is depicted as a mermaid, occasionally with a seal's lower body. In one legend, seals, whales and other marine mammals were formed from her severed fingers.[160] One of the earliest Ancient Greek coins depicts the head of a seal, and the animals were mentioned by Homer and Aristotle. The Greeks associated them with both the sea and sun and were considered to be under the protection of the gods Poseidon and Apollo.[161] The Moche people of ancient Peru worshipped the sea and its animals, and often depicted sea lions in their art.[162] In modern culture, pinnipeds are thought of as cute, playful and comical figures.[163]

In captivity

Pinnipeds can be found in facilities around the world, as their large size and playfulness make them popular attractions.[164] Seals have been kept in captivity since at least Ancient Rome and their trainability was noticed by Pliny the Elder. Zoologist Georges Cuvier noted during the 19th century that wild seals show considerable fondness for humans and stated that they are second only to some monkeys among wild animals in their easy tamability. Francis Galton noted in his landmark paper on domestication that seals were a spectacular example of an animal that would most likely never be domesticated despite their friendliness and desire for comfort due to the fact that they serve no practical use for humans.[165]

 
Captive sea lion at Kobe Oji Zoo Kobe, Japan

Some modern exhibits have rocky backgrounds with artificial haul-out sites and a pool, while others have pens with small rocky, elevated shelters where the animals can dive into their pools. More elaborate exhibits contain deep pools that can be viewed underwater with rock-mimicking cement as haul-out areas. The most common pinniped species kept in captivity is the California sea lion, as it is both easy to train and adaptable. Other popularly kept species include the grey seal and harbor seal. Larger animals like walruses and Steller sea lions are much less common.[164] Some organizations, such as the Humane Society of the United States and World Animal Protection, object to keeping pinnipeds and other marine mammals in captivity. They state that the exhibits could not be large enough to house animals that have evolved to be migratory, and a pool could never replace the size and biodiversity of the ocean. They also state that the tricks performed for audiences are "exaggerated variations of their natural behaviors" and distract the people from the animal's unnatural environment.[166]

California sea lions are used in military applications by the U.S. Navy Marine Mammal Program, including detecting naval mines and enemy divers. In the Persian Gulf, the animals have been trained to swim behind divers approaching a U.S. naval ship and attach a clamp with a rope to the diver's leg. Navy officials say that the sea lions can do this in seconds, before the enemy realizes what happened.[167] Organizations like PETA believe that such operations put the animals in danger.[168] The Navy insists that the sea lions are removed once their mission is complete.[169]

Hunting

Main article: Seal hunting
 
Men killing northern fur seals on Saint Paul Island, Alaska, in the mid-1890s

Humans have hunted seals since the Stone Age. Originally, seals were hit with clubs during haul-out. Eventually, seal hunters used harpoons to spear the animals from boats out at sea, and hooks for killing pups on ice or land. They were also trapped in nets. The use of firearms in seal hunting during the modern era drastically increased the number of killings. Pinnipeds are typically hunted for their meat and blubber. The skins of fur seals and phocids are made into coats, and the tusks of walruses continue to be used for carvings or as ornaments.[170] There is a distinction between the subsistence hunting of seals by indigenous peoples of the Arctic and commercial hunting: subsistence hunters typically use seal products for themselves and depend on them for survival.[171] National and international authorities have given special treatment to aboriginal hunters since their methods of killing are seen as less destructive and wasteful. This distinction is being questioned as indigenous people are using more modern weaponry and mechanized transport to hunt with, and are selling seal products in the marketplace. Some anthropologists argue that the term "subsistence" should also apply to these cash-based exchanges as long as they take place within local production and consumption. More than 100,000 phocids (especially ringed seals) as well as around 10,000 walruses are harvested annually by native hunters.[170]

 
Protests of Canada's seal hunts

Commercial sealing was historically just as important an industry as whaling. Exploited species included harp seals, hooded seals, Caspian seals, elephant seals, walruses and all species of fur seal.[171] The scale of seal harvesting decreased substantially after the 1960s,[170] after the Canadian government reduced the length of the hunting season and implemented measures to protect adult females.[172] Several species that were commercially exploited have rebounded in numbers; for example, Antarctic fur seals may be as numerous as they were prior to harvesting. The northern elephant seal was hunted to near extinction in the late 19th century, with only a small population remaining on Guadalupe Island. It has since recolonized much of its historic range, but has a population bottleneck.[171] Conversely, the Mediterranean monk seal was extirpated from much of its former range, which stretched from the Mediterranean to the Black Sea and northwest Africa, and only remains in the northeastern Mediterranean and some parts of northwest Africa.[173]

Several species of pinniped continue to be harvested. The Convention for the Conservation of Antarctic Seals allows limited hunting of crabeater seals, leopard seals and Weddell seals. However, Weddell seal hunting is prohibited between September and February if the animal is over one year of age, to ensure breeding stocks are healthy. Other species protected are southern elephant seals, Ross seals and Antarctic fur seals.[171] The Government of Canada permits the hunting of harp seals. This has been met with controversy and debate. Proponents of seal hunts insist that the animals are killed humanely and the white-coated pups are not taken, while opponents argue that it is irresponsible to kill harp seals as they are already threatened by declining habitat.[174][175]

The Caribbean monk seal has been killed and exploited by Europeans settlers and their descendants since 1494, starting with Christopher Columbus himself. The seals were easy targets for organized sealers, fishermen, turtle hunters and buccaneers because they evolved with little pressure from terrestrial predators and were thus "genetically tame". In the Bahamas, as many as 100 seals were slaughtered in one night. In the mid-nineteenth century, the species was thought to have gone extinct until a small colony was found near the Yucatán Peninsula in 1886. Seal killings continued, and the last reliable report of the animal alive was in 1952. The IUCN declared it extinct in 1996.[176] The Japanese sea lion was common around the Japanese islands, but overexploitation and competition from fisheries drastically decreased the population in the 1930s. The last recorded individual was a juvenile in 1974.[177]

Conservation issues

As of 2021, the International Union for Conservation of Nature (IUCN) recognizes 36 pinniped species. With the Japanese sea lion and the Caribbean monk seal recently extinct, ten more are considered at risk, as they are ranked "Endangered" (Hawaiian monk seal, Mediterranean monk seal, Galápagos fur seal, Australian sea lion, New Zealand sea lion, Caspian seal, and Galápagos sea lion) or "Vulnerable" (northern fur seal, hooded seal, and walrus).[178] There has been some debate over the cause of the decline of Steller sea lions in Alaska since the 1970s.[179]

Pinnipeds face various threats. They are unintentionally caught in fishing nets by commercial fisheries and accidentally swallow fishing hooks. Gillnetting and Seine netting is a significant cause of mortality in seals and other marine mammals. Species commonly entangled include California sea lions, Hawaiian monk seals, northern fur seals and brown fur seals.[171] Pinnipeds are also affected by marine pollution. High levels of organic chemicals accumulate in these animals since they are near the top of food chains and have large reserves of blubber. Lactating mothers can pass the toxins on to their young. These pollutants can cause gastrointestinal cancers, decreased reproductivity and greater vulnerability to infectious diseases.[180] Other man-made threats include habitat destruction by oil and gas exploitation, encroachment by boats,[171] and underwater noise.[181]

 
Grey seal on beach occupied by humans near Niechorze, Poland. Pinnipeds and humans may compete for space and resources.

Species that live in polar habitats are vulnerable to the effects of climate change on oceans, particularly declines in sea ice.[182] In 2010 and 2011, sea ice in the Northwest Atlantic was at or near an all-time low and harp seals as well as ringed seals that bred on thin ice saw increased death rates.[89][183] Antarctic fur seals in South Georgia in the South Atlantic Ocean saw extreme reductions over a 20-year study, during which scientists measured increased sea surface temperature anomalies.[184]

Some species have become so numerous that they conflict with local people. In the United States, pinnipeds are protected under the Marine Mammal Protection Act of 1972 (MMPA). Since that year, California sea lion populations have risen to 250,000. These animals began exploiting more man-made environments, like docks, for haul-out sites. Many docks are not designed to withstand the weight of several resting sea lions. Wildlife managers have used various methods to control the animals, and some city officials have redesigned docks so they can better withstand use by sea lions.[185][186] The return of sea lions in New Zealand has caused unique human conflicts for pinnipeds, as breeding females move up to 2 kilometres (1.2 mi) inland to protect their pups.[85][87] As consequence, they have been hit by cars on roads, deliberately killed, and disturbed by domestic dogs. Human infrastructures such as residential areas, roads, fences, and private lands have also affected their dispersal and breeding success.[187] Conservation efforts are being made by predicting potential areas of human-wildlife conflict to direct proactive measures that facilitate coexistence between humans and this endangered species, such as making road signs and engaging with local communities.[188][189][187]

Seals also conflict with fisherman.[190] In 2007, MMPA was amended to permit the lethal removal of sea lions from salmon runs at Bonneville Dam.[191] In the 1980s and 1990s, South African politicians and fisherman demanded that brown fur seals be culled, believing that the animals competed with commercial fisheries. Scientific studies found that culling fur seals would actually have a negative effect on the fishing industry, and the culling option was dropped in 1993.[192]

Notes

  1. ^ This term typically excludes the walrus in everyday English. In science, it is also sometimes restricted to the "true" seals of the family Phocidae. This article uses it for all pinnipeds.

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Bibliography

  • Berta, Annalisa (2012). Return to the Sea: The life and evolutionary times of marine mammals. University of California Press. ISBN 978-0-520-27057-2.
  • Berta, Annalisa; Sumich, James L.; Kovacs, Kit M. (2006). Marine Mammals. Evolutionary Biology (2nd ed.). Academic Press. ISBN 978-0-12-088552-7.
  • MacDonald, David, ed. (2001). The Encyclopedia of Mammals (2nd ed.). Oxford University Press. ISBN 978-0-7607-1969-5.
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  • Riedman, Marianne (1990). The Pinnipeds: Seals, sea lions, and walruses. University of California Press. ISBN 978-0-520-06497-3.
  • Scheffer, Victor B. (1958). Seals, Sea Lions, and Walruses: A Review of the Pinnipedia. Stanford University Press. ISBN 978-0-8047-0544-8.

External links

 
Look up pinniped in Wiktionary, the free dictionary.
 
Wikimedia Commons has media related to Pinnipedia.
 
Wikiquote has quotations related to Pinniped.
 
Wikisource has the text of the 1911 Encyclopædia Britannica article "Seal".
  • "Seal Conservation home page". Seal Conservation Society.
  • . Department of Fisheries. National Oceanographic and Atmospheric Administration. Archived from the original on 19 July 2014.
  • . Pinniped Ecology Applied Research Laboratory. Oregon State University. Archived from the original on 5 July 2019. Retrieved 11 August 2013.
  • "Pinniped Laboratory home page". Pinniped Cognition & Sensory Systems Laboratory. University of California, Santa Cruz.

January 31, 2023
pinniped, pronounced, commonly, known, seals, widely, distributed, diverse, clade, carnivorous, footed, semiaquatic, mostly, marine, mammals, they, comprise, extant, families, odobenidae, whose, only, living, member, walrus, otariidae, eared, seals, lions, sea. Pinnipeds pronounced ˈ p ɪ n ɪ ˌ p ɛ d z commonly known as seals a are a widely distributed and diverse clade of carnivorous fin footed semiaquatic mostly marine mammals They comprise the extant families Odobenidae whose only living member is the walrus Otariidae the eared seals sea lions and fur seals and Phocidae the earless seals or true seals There are 34 extant species of pinnipeds and more than 50 extinct species have been described from fossils While seals were historically thought to have descended from two ancestral lines molecular evidence supports them as a monophyletic lineage descended from one ancestral line Pinnipeds belong to the order Carnivora their closest living relatives are musteloids weasels raccoons skunks and red pandas having diverged about 50 million years ago PinnipedsTemporal range Latest Oligocene Holocene 24 0 Ma PreꞒ Ꞓ O S D C P T J K Pg NClockwise from top left New Zealand fur seal Arctocephalus forsteri southern elephant seal Mirounga leonina Steller sea lion Eumetopias jubatus walrus Odobenus rosmarus and grey seal Halichoerus grypus Scientific classificationKingdom AnimaliaPhylum ChordataClass MammaliaOrder CarnivoraClade PinnipedimorphaClade PinnipediformesClade PinnipediaIlliger 1811 1 SubcladesFamily Enaliarctidae Superfamily Otarioidea Family Odobenidae walruses Family Otariidae fur seals and sea lions Superfamily Phocoidea Family Phocidae true or earless seals Range mapSeals range in size from the 1 m 3 ft 3 in and 45 kg 99 lb Baikal seal to the 5 m 16 ft and 3 200 kg 7 100 lb southern elephant seal male which is also the largest member of the order Carnivora Several species exhibit sexual dimorphism They have streamlined bodies and four limbs that are modified into flippers Though not as fast in the water as dolphins seals are more flexible and agile Otariids use their front limbs primarily to propel themselves through the water while phocids and walruses use their hind limbs Otariids and walruses have hind limbs that can be pulled under the body and used as legs on land By comparison terrestrial locomotion by phocids is more cumbersome Otariids have visible external ears while phocids and walruses lack these Pinnipeds have well developed senses their eyesight and hearing are adapted for both air and water and they have an advanced tactile system in their whiskers or vibrissae Some species are well adapted for diving to great depths They have a layer of fat or blubber under the skin to keep warm in the cold water and other than the walrus all species are covered in fur Although pinnipeds are widespread most species prefer the colder waters of the Northern and Southern Hemispheres They spend most of their lives in the water but come ashore to mate give birth molt or escape from predators such as sharks and orcas Seals mainly live in marine environments but can also be found in freshwater They feed largely on fish and marine invertebrates a few such as the leopard seal feed on large vertebrates such as penguins and other seals Walruses are specialized for feeding on bottom dwelling mollusks Male pinnipeds typically mate with more than one female polygyny although the degree of polygyny varies with the species The males of land breeding species tend to mate with a greater number of females than those of ice breeding species Male pinniped strategies for reproductive success vary between defending females defending territories that attract females and performing ritual displays or lek mating Pups are typically born in the spring and summer months and females bear almost all the responsibility for raising them Mothers of some species fast and nurse their young for a relatively short period of time while others take foraging trips at sea between nursing bouts Walruses are known to nurse their young while at sea Seals produce a number of vocalizations notably the barks of California sea lions the gong like calls of walruses and the complex songs of Weddell seals The meat blubber and fur coats of pinnipeds have traditionally been used by indigenous peoples of the Arctic Seals have been depicted in various cultures worldwide They are commonly kept in captivity and are even sometimes trained to perform tricks and tasks Once relentlessly hunted by commercial industries for their products seals and walruses are now protected by international law The Japanese sea lion and the Caribbean monk seal have become extinct in the past century while the Mediterranean monk seal and Hawaiian monk seal are ranked endangered by the International Union for Conservation of Nature Besides hunting pinnipeds also face threats from accidental trapping marine pollution and conflicts with local people Contents 1 Etymology 2 Taxonomy and evolution 2 1 Taxonomy 2 2 Evolutionary history 3 Anatomy and physiology 3 1 Locomotion 3 2 Senses 3 3 Diving adaptations 3 4 Thermoregulation 3 5 Sleep 4 Distribution and habitat 5 Behavior and life history 5 1 Foraging and predation 5 2 Reproductive behavior 5 3 Birth and parenting 5 4 Communication 5 5 Intelligence 6 Human relations 6 1 Cultural depictions 6 2 In captivity 6 3 Hunting 7 Conservation issues 8 Notes 9 References 9 1 Bibliography 10 External linksEtymology EditThe name pinniped derives from the Latin words pinna fin and pes pedis foot 2 The common name seal originates from the Old English word seolh which is in turn derived from the Proto Germanic selkhaz 3 Taxonomy and evolution EditTaxonomy Edit Further information List of pinnipeds Pinnipedia Phocidae Phocinae Bearded sealHooded sealPhocini Ringed sealBaikal sealCaspian sealSpotted sealHarbor sealGrey sealRibbon sealHarp sealMonachinae Lobodontini Weddell sealLeopard sealCrabeater sealRoss sealMiroungini Southern elephant sealNorthern elephant seal elephant seals Monachini Mediterranean monk sealHawaiian monk sealCaribbean monk seal earless seals Otariidae Northern fur sealSteller sea lionCalifornia sea lionGalapagos sea lionSouth American sea lionAustralian sea lionNew Zealand sea lionBrown fur sealSubantarctic fur sealAntarctic fur sealGuadalupe fur sealJuan Fernandez fur sealAntipodean fur sealGalapagos fur sealSouth American fur seal eared seals Odobenidae WalrusCladogram showing relationships among the living pinnipeds found in Berta Churchill and Boessenecker 2018 The Southern Hemisphere eared seal clade is not fully resolved 4 The German naturalist Johann Karl Wilhelm Illiger was the first to recognize the pinnipeds as a distinct taxonomic unit in 1811 he gave the name Pinnipedia to both a family and an order 5 American zoologist Joel Asaph Allen reviewed the world s pinnipeds in an 1880 monograph History of North American pinnipeds a monograph of the walruses sea lions sea bears and seals of North America In this publication he traced the history of names gave keys to families and genera described North American species and provided synopses of species in other parts of the world 6 In 1989 Annalisa Berta and colleagues proposed the unranked clade Pinnipedimorpha to contain the fossil genus Enaliarctos and modern seals as a sister group 7 Pinnipeds belong to the order Carnivora and the suborder Caniformia known as dog like carnivorans 8 Pinnipedia was historically considered its own suborder under Carnivora 9 Of the three extant families the Otariidae and Odobenidae are grouped in the superfamily Otarioidea 10 while the Phocidae belong to the superfamily Phocoidea 11 There are 34 extant species of pinnipeds 4 and more than 50 fossil species 12 Otariids are also known as eared seals due to the presence of pinnae These animals rely on their well developed fore flippers to propel themselves through the water They can also turn their hind flippers forward and walk on land 13 The anterior end of an otariid s frontal bones extends between the nasal bones and the supraorbital foramen is large and flat horizontally The supraspinatous fossas are divided by a secondary spine and the bronchi are divided anteriorly 14 Otariids consist of two types sea lions and fur seals Sea lions are distinguished by their rounder snouts and shorter rougher pelage while fur seals have more pointed snouts longer fore flippers and thicker fur coats that include an undercoat and guard hairs The former also tend to be larger than the latter 15 Five genera and seven species one now extinct of sea lion are known to exist while two genera and nine species of fur seal exist While sea lions and fur seals have historically been considered separate subfamilies Otariinae and Arctocephalinae respectively a 2001 genetic study found that the northern fur seal is more closely related to several sea lion species 16 This is supported by a 2006 molecular study that also found that the Australian sea lion and New Zealand sea lion are more closely related to Arctocephalus than to other sea lions 17 Odobenidae consists of only one living member the modern walrus This animal is easily distinguished from other extant pinnipeds by its larger size exceeded only by the elephant seals nearly hairless skin and long upper canines known as tusks Like otariids walruses are capable of turning their hind flippers forward and can walk on land When moving in water the walrus relies on its hind flippers for locomotion while its fore flippers are used for steering In addition the walrus lacks external ear flaps 18 Walruses have pterygoid bones that are broad and thick frontal bones that are V shaped at the anterior end and calcaneuses with pronounced tuberosity in the middle 14 Phocids are known as true or earless seals These animals lack external ear flaps and are incapable of turning their hind flippers forward which makes them more cumbersome on land In water true seals swim by moving their hind flippers and lower body from side to side 13 Phocids have thickened mastoids enlarged entotympanic bones everted pelvic bones and massive ankle bones They also lack supraorbital processes on the frontal and have underdeveloped calcaneal tubers 14 A 2006 molecular study supports the division of phocids into two monophyletic subfamilies Monachinae which consists of Mirounga Monachini and Lobodontini and Phocinae which includes Pusa Phoca Halichoerus Histriophoca Pagophilus Erignathus and Cystophora 17 Evolutionary history Edit Further information List of fossil pinnipedimorphs Restoration of Puijila One popular hypothesis suggested that pinnipeds are diphyletic descended from two ancestral lines with walruses and otariids sharing a recent common ancestor with bears and phocids sharing one with Musteloidea However morphological and molecular evidence support a monophyletic origin 14 A 2021 genetic study found that pinnipeds are more closely related to musteloids 19 Pinnipeds split from other caniforms 50 million years ago mya during the Eocene 20 Their evolutionary link to terrestrial mammals was unknown until the 2007 discovery of Puijila in early Miocene deposits in Nunavut Canada Like a modern otter Puijila had a long tail short limbs and webbed feet instead of flippers However its limbs and shoulders were more robust and Puijila likely had been a quadrupedal swimmer retaining a form of aquatic locomotion that gave rise to the major swimming types employed by modern pinnipeds The researchers who found Puijila placed it in a clade with Potamotherium traditionally considered a mustelid and Enaliarctos Of the three Puijila was the least specialized for aquatic life The discovery of Puijila in a lake deposit suggests that pinniped evolution went through a freshwater transitional phase 21 Fossil of Enaliarctos Enaliarctos a fossil species of late Oligocene early Miocene 24 22 mya California closely resembled modern pinnipeds it was adapted to an aquatic life with a flexible spine and limbs modified into flippers Its teeth were adapted for shearing like terrestrial carnivorans and it may have stayed near shore more often than its extant relatives Enaliarctos was capable of swimming with both the fore flippers and hind flippers but it may have been more specialized as a fore flipper swimmer 14 One species Enaliarctos emlongi exhibited notable sexual dimorphism suggesting that this physical characteristic may have been an important driver of pinniped evolution 22 A closer relative of extant pinnipeds was Pteronarctos which lived in Oregon 19 15 mya As in modern seals Pteroarctos had an orbital wall that was not limited by certain facial bones like the jugal or lacrimal bone but was mostly shaped by the maxilla The extinct family Desmatophocidae lived 23 10 mya in the North Atlantic and had elongated skulls fairly large eyes cheekbones connected by a mortised structure and rounded cheek teeth They also were sexually dimorphic and may have been capable of propelling themselves with both the foreflippers and hindflippers 14 Their phylogeny and evolutionary relationship to other pinnipeds is poorly understood 23 although it has been proposed that they may be closer to the otariids than the phocids 24 Fossil skull cast of Piscophoca sp from Phocidae The ancestors of the Otarioidea and Phocoidea diverged 33 mya 20 Phocids are known to have existed for at least 15 million years 14 and molecular evidence supports a divergence of the Monachinae and Phocinae lineages 22 mya 17 The fossil monachine Monotherium and phocine Leptophoca were found in southeastern North America The deep split between the lineages of Erignathus and Cystophora 17 mya suggests that the phocines migrated eastward and northward from the North Atlantic The genera Phoca and Pusa could have arisen when a phocine lineage traveled from the Paratethys Sea to the Arctic Basin and subsequently went eastward The ancestor of the Baikal seal migrated into Lake Baikal from the Arctic via the Siberian ice sheet and became isolated there The Caspian seal s ancestor became isolated as the Paratethys shrank leaving the animal in a small remnant sea the Caspian Sea 14 The monochines diversified southward Monachus emerged in the Mediterranean and migrated to the Caribbean and then the central North Pacific 25 The two extant elephant seal species diverged close to 4 mya after the Panamanian isthmus was formed 17 The lobodontine lineage emerged around 9 mya and colonized the southern ocean in response to glaciation 25 Reconstruction of Archaeodobenus akamatsui family Odobenidae The lineages of Otariidae and Odobenidae split almost 28 mya 17 Otariids originated in the North Pacific The earliest fossil Pithanotaria found in California is dated to 11 mya The Callorhinus lineage split earlier at 16 mya Zalophus Eumetopias and Otaria diverged next with the latter colonizing the coast of South America Most of the other otariids diversified in the Southern Hemisphere The earliest fossils of Odobenidae Prototaria of Japan and Proneotherium of Oregon date to 18 16 mya These primitive walruses had much shorter canines and lived on a fish diet rather than a specialized mollusk diet like the modern walrus Odobenids further diversified in the middle and late Miocene Several species had enlarged upper and lower canines The genera Valenictus and Odobenus developed elongated tusks The lineage of the modern walrus may have spread from the North Pacific to the Caribbean via the Central American Seaway 8 5 mya and subsequently made it to the North Atlantic and returned to the North Pacific via the Arctic 1 mya Alternatively this lineage may have spread from the North Pacific to the Arctic and subsequently the North Atlantic during the Pleistocene 14 Anatomy and physiology Edit Skeleton of California sea lion top and southern elephant seal Pinnipeds have streamlined spindle shaped bodies with reduced or non existent external ear flaps rounded heads flexible necks limbs modified into flippers and small tails 26 27 Pinniped skulls have large eye orbits short snouts and a constricted interorbital region 28 They are unique among carnivorans in that their orbital walls are mostly shaped by the maxilla which are not contained by certain facial bones 14 Compared to other carnivorans their teeth tend to be fewer in number especially incisors and back molars are pointed and cone shaped and lack carnassials 29 The walrus has unique upper canines that are elongated into tusks 30 The mammary glands and genitals of pinnipeds can retract into the body 26 Pinnipeds range in size from the 1 m 3 ft 3 in and 45 kg 99 lb Baikal seal to the 5 m 16 ft and 3 200 kg 7 100 lb southern elephant seal Overall they tend to be larger than other carnivorans the southern elephant seal is the largest carnivoran 26 Several species have male biased sexual dimorphism that correlates with the degree of polygyny in a species highly polygynous species like elephant seals are extremely sexually dimorphic while less polygynous species have males and females that are closer in size In lobodontine seals females are slightly larger than males Males of sexually dimorphic species also tend to have secondary sex characteristics such as the prominent proboscis of elephant seals the inflatable red nasal membrane of hooded seals and the thick necks and manes of otariids 31 32 Despite a correlation between size dimorphism and the degree of polygyny some evidence suggests that size differences between the sexes originated due to ecological differences and prior to the development of polygyny 33 34 Male and female South American sea lions showing sexual dimorphism Almost all pinnipeds have fur coats the exception being the walrus which is only sparsely covered Even some fully furred species particularly sea lions are less haired than most land mammals 35 In species that live on ice young pups have thicker coats than adults The individual hairs on the coat known collectively as lanugo can trap heat from sunlight and keep the pup warm 36 Pinnipeds are typically countershaded and are darker colored dorsally and lighter colored ventrally which serves to eliminate shadows caused by light shining over the ocean water The pure white fur of harp seal pups conceals them in their Arctic environment 37 Some species such as ribbon seals ringed seals and leopard seals have patterns of contrasting light and dark coloration All fully furred species molt phocids molt once a year while otariids gradually molt all year 38 Seals have a layer of subcutaneous fat known as blubber that is particularly thick in phocids and walruses 26 Blubber serves both to keep the animals warm and to provide energy and nourishment when they are fasting It can constitute as much as 50 of a pinniped s body weight Pups are born with only a thin layer of blubber but some species compensate for this with thick lanugos 36 Pinnipeds have a simple stomach that is similar in structure to terrestrial carnivores Most species have neither a cecum nor a clear demarcation between the small and large intestines the large intestine is comparatively short and only slightly wider than the small intestine Small intestine lengths range from 8 times California sea lion to 25 times elephant seal the body length The length of the intestine may be an adaptation to frequent deep diving as the increased volume of the digestive tract serves as an extended storage compartment for partially digested food during submersion Pinnipeds do not have an appendix 39 As in most marine mammals the kidneys are divided into small lobes and can effectively absorb water and filter out excess salt 40 Locomotion Edit Harbor seal top and California sea lion swimming The former swims with its hind flippers the latter with its fore flippers Pinnipeds have two pairs of flippers on the front and back the fore flippers and hind flippers The elbows and ankles are enclosed within the body 41 Pinnipeds tend to be slower swimmers than cetaceans typically cruising at 5 15 kn 9 28 km h 6 17 mph compared to around 20 kn 37 km h 23 mph for several species of dolphin Seals are more agile and flexible 35 and some otariids such as the California sea lion are capable of bending their necks backwards far enough to reach their hind flippers allowing them to make dorsal turns 42 Pinnipeds have several adaptions for reducing drag In addition to their streamlined bodies they have smooth networks of muscle bundles in their skin that may increase laminar flow and make it easier for them to slip through water They also lack arrector pili so their fur can be streamlined as they swim 35 When swimming otariids rely on their fore flippers for locomotion in a wing like manner similar to penguins and sea turtles 43 Fore flipper movement is not continuous and the animal glides between each stroke 42 Compared to terrestrial carnivorans the fore limbs of otariids are reduced in length which gives the locomotor muscles at the shoulder and elbow joints greater mechanical advantage 41 the hind flippers serve as stabilizers 35 Phocids and walruses swim by moving their hind flippers and lower body from side to side 43 while their fore flippers are mainly used for steering 41 Some species leap out of the water which may allow them to travel faster In addition sea lions are known to ride waves which probably helps them decrease their energy usage 35 Pinnipeds can move around on land though not as well as terrestrial animals Otariids and walruses are capable of turning their hind flippers forward and under the body so they can walk on all fours 44 The fore flippers move in a transverse rather than a sagittal fashion Otariids rely on their head neck and back spine more than their hind flippers during terrestrial locomotion 45 By swinging their heads and necks otariids create momentum while they are moving Sea lions have been recorded climbing up flights of stairs Phocids are less agile on land They cannot pull their hind flippers forward and move on land by lunging bouncing and wiggling while their fore flippers keep them balanced Some species use their fore flippers to pull themselves forward Terrestrial locomotion is easier for phocids on ice as they can sled along 44 Senses Edit Light reflection on an elephant seal eye The eyes of pinnipeds are relatively large for their size and are positioned near the front of the head One exception is the walrus whose smaller eyes are located on the sides of its head 46 47 This is because it feeds on immobile bottom dwelling mollusks and hence does not need acute vision 46 A seal s eye is adapted for seeing both underwater and in air The lens is mostly spherical and much of the retina is equidistant from the lens center The cornea has a flattened center where refraction is nearly equal in both water and air Pinnipeds also have very muscular and vascularized irises The well developed dilator muscle gives the animals a great range in pupil dilation When contracted the pupil is typically pear shaped although the bearded seal s is more diagonal In species that live in shallow water such as harbor seals and California sea lions dilation varies little while the deep diving elephant seals have much greater variation 48 Frontal view of brown fur seal head On land pinnipeds are near sighted in dim light This is reduced in bright light as the retracted pupil reduces the lens and cornea s ability to bend light They also have a well developed tapetum lucidum a reflecting layer that increases sensitivity by reflecting light back through the rods This helps them see in low light conditions 46 Ice living seals like the harp seal have corneas that can tolerate high levels of ultraviolet radiation typical of bright snowy environments As such they do not suffer snow blindness 49 Pinnipeds appear to have limited color vision as they lack S cones 50 Flexible eye movement has been documented in seals 51 The extraocular muscles of the walrus are well developed This and its lack of orbital roof allow it to protrude its eyes and see in both frontal and dorsal directions 52 Seals release large amounts of mucus to protect their eyes 35 The corneal epithelium is keratinized and the sclera is thick enough to withstand the pressures of diving As in many mammals and birds pinnipeds possess nictitating membranes 53 The pinniped ear is adapted for hearing underwater where it can hear sound frequencies at up to 70 000 Hz In air hearing is somewhat reduced in pinnipeds compared to many terrestrial mammals While they are capable of hearing a wide range of frequencies e g 500 to 32 000 Hz in the northern fur seal compared to 20 to 20 000 Hz in humans their airborne hearing sensitivity is weaker overall 54 One study of three species the harbor seal California sea lion and northern elephant seal found that the sea lion was best adapted for airborne hearing the harbor seal was equally capable of hearing in air and water and the elephant seal was better adapted for underwater hearing 55 Although pinnipeds have a fairly good sense of smell on land 56 it is useless underwater as their nostrils are closed 57 Vibrissae of walrus Pinnipeds have well developed tactile senses Their mystacial vibrissae have ten times the innervation of terrestrial mammals allowing them to effectively detect vibrations in the water 58 These vibrations are generated for example when a fish swims through water Detecting vibrations is useful when the animals are foraging and may add to or even replace vision particularly in darkness 59 Harbor seals have been observed following varying paths of another seal that swam ahead several minutes before similar to a dog following a scent trail 60 61 and even to discriminate the species and the size of the fish responsible for the trail 62 Blind ringed seals have even been observed successfully hunting on their own in Lake Saimaa likely relying on their vibrissae to gain sensory information and catch prey 63 Unlike terrestrial mammals such as rodents pinnipeds do not move their vibrissae over an object when examining it but instead extend their moveable whiskers and keep them in the same position 59 By holding their vibrissae steady pinnipeds are able to maximize their detection ability 64 The vibrissae of phocids are undulated and wavy while otariid and walrus vibrissae are smooth 65 Research is ongoing to determine the function if any of these shapes on detection ability The vibrissa s angle relative to the flow not the shape however seems to be the most important factor 64 The vibrissae of some otariids grow quite long those of the Antarctic fur seal can reach 41 cm 16 in 66 Walruses have the most vibrissae at 600 700 individual hairs These are important for detecting their prey on the muddy sea floor In addition to foraging vibrissae may also play a role in navigation spotted seals appear to use them to detect breathing holes in the ice 67 Diving adaptations Edit See also Physiology of underwater diving Pinnipeds Weddell seal underwater Before diving pinnipeds typically exhale to empty their lungs of half the air 68 and then close their nostrils and throat cartilages to protect the trachea 69 Their unique lungs have airways that are highly reinforced with cartilaginous rings and smooth muscle and alveoli that completely deflate during deeper dives 70 71 While terrestrial mammals are generally unable to empty their lungs 72 pinnipeds can reinflate their lungs even after complete respiratory collapse 73 The middle ear contains sinuses that probably fill with blood during dives preventing middle ear squeeze 74 The heart of a seal is moderately flattened to allow the lungs to deflate The trachea is flexible enough to collapse under pressure 68 During deep dives any remaining air in their bodies is stored in the bronchioles and trachea which prevents them from experiencing decompression sickness oxygen toxicity and nitrogen narcosis In addition seals can tolerate large amounts of lactic acid which reduces skeletal muscle fatigue during intense physical activity 74 The main adaptations of the pinniped circulatory system for diving are the enlargement and increased complexity of veins to increase their capacity Retia mirabilia form blocks of tissue on the inner wall of the thoracic cavity and the body periphery These tissue masses which contain extensive contorted spirals of arteries and thin walled veins act as blood reservoirs that increase oxygen stores for use during diving 75 As with other diving mammals pinnipeds have high amounts of hemoglobin and myoglobin stored in their blood and muscles This allows them to stay submerged for long periods of time while still having enough oxygen Deep diving species such as elephant seals have blood volumes that represent up to 20 of their body weight When diving they reduce their heart rate and maintain blood flow only to the heart brain and lungs To keep their blood pressure stable phocids have an elastic aorta that dissipates some of the energy of each heartbeat 74 Thermoregulation Edit Northern elephant seal resting in water Pinnipeds conserve heat with their large and compact body size insulating blubber and fur and high metabolism 76 In addition the blood vessels in their flippers are adapted for countercurrent exchange Veins containing cool blood from the body extremities surround arteries which contain warm blood received from the core of the body Heat from the arterial blood is transferred to the blood vessels which then recirculate blood back to the core 77 The same adaptations that conserve heat while in water tend to inhibit heat loss when out of water To counteract overheating many species cool off by flipping sand onto their backs adding a layer of cool damp sand that enhances heat loss The northern fur seal pants to help stay cool while monk seals often dig holes in the sand to expose cooler layers to rest in 78 Sleep Edit Pinnipeds spend many months at a time at sea so they must sleep in the water Scientists have recorded them sleeping for minutes at a time while slowly drifting downward in a belly up orientation Like other marine mammals seals sleep in water with half of their brain awake so that they can detect and escape from predators 79 When they are asleep on land both sides of their brain go into sleep mode 80 Distribution and habitat Edit Walrus on ice off Alaska This species has a discontinuous distribution around the Arctic Circle Living pinnipeds mainly inhabit polar and subpolar regions particularly the North Atlantic the North Pacific and the Southern Ocean They are entirely absent from Indomalayan waters 81 Monk seals and some otariids live in tropical and subtropical waters Seals usually require cool nutrient rich waters with temperatures lower than 20 C 68 F Even those that live in warm or tropical climates live in areas that become cold and nutrient rich due to current patterns 81 82 Only monk seals live in waters that are not typically cool or rich in nutrients 81 The Caspian seal and Baikal seal are found in large landlocked bodies of water the Caspian Sea and Lake Baikal respectively As a whole pinnipeds can be found in a variety of aquatic habitats including coastal water open ocean brackish water and even freshwater lakes and rivers The Baikal seal is the only exclusively freshwater species Most seals inhabit coastal areas though some travel offshore and feed in deep waters off oceanic islands 83 Pinnipeds also use a number of terrestrial habitats and substrates both continental and island In temperate and tropical areas they haul out on to sandy and pebble beaches rocky shores shoals mud flats tide pools and in sea caves Some species also rest on man made structures like piers jetties buoys and oil platforms Pinnipeds may move further inland and rest in sand dunes or vegetation and may even climb cliffs 84 New Zealand sea lions are the only pinnipeds that can be found up to 2 kilometres 1 2 mi inland in forests 85 86 87 Polar living species haul out on to both fast ice and drift ice 88 They use the ice platforms for breeding and raising young seal pups 89 Ringed seals build dens underneath fast ice 90 Behavior and life history Edit Harbor seal hauled out on rock Pinnipeds have an amphibious lifestyle they spend most of their lives in the water but haul out to mate raise young molt rest thermoregulate or escape from aquatic predators Several species are known to migrate vast distances particularly in response to extreme environmental changes like El Nino or changes in ice cover Elephant seals stay at sea 8 10 months a year and migrate between breeding and molting sites The northern elephant seal has one of the longest recorded migration distances for a mammal at 18 000 21 000 km 11 000 13 000 mi Phocids tend to migrate more than otariids 91 Traveling seals may use various features of their environment to reach their destination including geomagnetic fields water and wind currents the position of the sun and moon and the taste and temperature of the water 92 Pinnipeds may dive during foraging or to avoid predators When foraging for example the Weddell seal typically dives for less than 15 minutes to depths of around 400 m 1 300 ft but can dive for as long as 73 minutes and to depths of up to 600 m 2 000 ft Northern elephant seals commonly dive 350 650 m 1 150 2 130 ft for as long as 20 minutes They can also dive 1 500 m 4 900 ft and for as long as 77 minutes 93 The dives of otariids tend to be shorter and less deep They typically last 5 7 minutes with average depths to 30 45 m 98 148 ft However the New Zealand sea lion has been recorded diving to a maximum of 460 m 1 510 ft and a duration of 12 minutes 94 Walruses do not often dive very deep as they feed in shallow water 95 Pinnipeds have lifespans averaging 25 30 years Females usually live longer as males tend to fight and often die before reaching maturity 96 The longest recorded lifespans include 43 years for a wild female ringed seal and 46 years for a wild female grey seal 97 The age at which a pinniped sexually matures can vary from 2 12 years depending on the species Females typically mature earlier than males 98 Foraging and predation Edit Steller sea lion with white sturgeon All pinnipeds are carnivorous and predatory As a whole they mostly feed on fish and cephalopods followed by crustaceans and bivalves and then zooplankton and endothermic warm blooded prey like sea birds 99 While most species are generalist and opportunistic feeders a few are specialists Examples include the crabeater seal which primarily eats krill the ringed seal which eats mainly crustaceans the Ross seal and southern elephant seal which specialize on squid and the bearded seal and walrus which feed on clams and other bottom dwelling invertebrates 81 Pinnipeds may hunt solitarily or cooperatively The former behavior is typical when hunting non schooling fish slow moving or immobile invertebrates or endothermic prey Solitary foraging species usually exploit coastal waters bays and rivers An exception to this is the northern elephant seal which feeds on fish at great depths in the open ocean In addition walruses feed solitarily but are often near other walruses in small or large groups that may surface and dive in unison When large schools of fish or squid are available pinnipeds such as certain otariids hunt cooperatively in large groups locating and herding their prey Some species such as California and South American sea lions may forage with cetaceans and sea birds 100 Seals typically consume their prey underwater where it is swallowed whole Prey that is too large or awkward is taken to the surface to be torn apart 101 The leopard seal a prolific predator of penguins is known to violently swing its prey back and forth until it is dead 102 The elaborately cusped teeth of filter feeding species such as crabeater seals allow them to remove water before they swallow their planktonic food 81 The walrus is unique in that it consumes its prey by suction feeding using its tongue to suck the meat of a bivalve out of the shell 47 While pinnipeds mostly hunt in the water South American sea lions are known to chase down penguins on land 103 Some species may swallow stones or pebbles for reasons not understood 104 Though they can drink seawater pinnipeds get most of their fluid intake from the food they eat 40 Leopard seal capturing emperor penguin Pinnipeds themselves are subject to predation Most species are preyed on by the orca To subdue and kill seals orcas continuously ram them with their heads slap them with their tails and fling them in the air They are typically hunted by groups of 10 or fewer whales but they are occasionally hunted by larger groups or by lone individuals Pups are more commonly taken by orcas but adults can be targeted as well Large sharks are another major predator of pinnipeds usually the great white shark but also the tiger shark and mako shark Sharks usually attack by ambushing them from below The prey usually escapes and seals are often seen with shark inflicted wounds Otariids typically have injuries in the hindquarters while phocids usually have injuries on the forequarters 105 Pinnipeds are also targeted by terrestrial and pagophilic predators The polar bear is well adapted for hunting Arctic seals and walruses particularly pups Bears are known to use sit and wait tactics as well as active stalking and pursuit of prey on ice or water Other terrestrial predators include cougars brown hyenas and various species of canids which mostly target the young 105 Orca hunting a Weddell seal Pinnipeds lessen the chance of predation by gathering in groups 106 Some species are capable of inflicting damaging wounds on their attackers with their sharp canines an adult walrus is capable of killing polar bears 105 When out at sea northern elephant seals dive out of the reach of surface hunting orcas and white sharks 79 In the Antarctic which lacks terrestrial predators pinniped species spend more time on the ice than their Arctic counterparts 107 Arctic seals use more breathing holes per individual appear more restless when hauled out and rarely defecate on the ice Ringed seals rely on their dens for protection 90 Interspecific predation among pinnipeds does occur The leopard seal is known to prey on numerous other species especially the crabeater seal Leopard seals typically target crabeater pups which form an important part of their diet from November to January Older crabeater seals commonly bear scars from failed leopard seal attacks a 1977 study found that 75 of a sample of 85 individual crabeaters had these scars 108 Walruses despite being specialized for feeding on bottom dwelling invertebrates occasionally prey on Arctic seals They kill their prey with their long tusks and eat their blubber and skin Steller sea lions have been recorded eating the pups of harbor seals northern fur seals and California sea lions New Zealand sea lions feed on pups of some fur seal species and the South American sea lion may prey on South American fur seals 105 Reproductive behavior Edit Walrus herd on ice floe The mating system of pinnipeds varies from extreme polygyny to serial monogamy 109 Of the 33 species 20 breed on land and the remaining 13 breed on ice 110 Species that breed on land are usually polygynous as females gather in large aggregations and males are able to mate with them as well as defend them from rivals Polygynous species include elephant seals grey seals and most otariids 31 Land breeding pinnipeds tend to mate on islands where there are fewer terrestrial predators Few islands are favorable for breeding and those that are tend to be crowded Since the land they breed on is fixed females return to the same sites for many years The males arrive earlier in the season and wait for them The males stay on land and try to mate with as many females as they can some of them will even fast If a male leaves the beach to feed he will likely lose mating opportunities and his dominance 111 Polygynous species also tend to be extremely sexual dimorphic in favor of males This dimorphism manifests itself in larger chests and necks longer canines and denser fur all traits that help males in fights for females Increased body weight in males increases the length of time they can fast due to the ample energy reserves stored in the blubber 31 Larger males also likely enjoy access to feeding grounds that smaller ones are unable to access due to their lower thermoregulatory ability and decreased energy stores 33 In some instances only the largest males are able to reach the furthest deepest foraging grounds where they enjoy maximum energetic yields that are unavailable to smaller males and females 112 Other seals like the walrus and most phocids breed on ice with copulation usually taking place in the water a few land breeding species also mate in water 31 113 114 Females of these species tend to aggregate less In addition since ice is less stable than solid land breeding sites change location each year and males are unable to predict where females will stay during the breeding season Hence polygyny tends to be weaker in ice breeding species An exception to this is the walrus where females form dense aggregations perhaps due to their patchy food sources Pinnipeds that breed on fast ice tend to cluster together more than those that breed on drift ice 113 Some of these species are serially monogamous including the harp seal crabeater seal and hooded seal 115 Seals that breed on ice tend to have little or no sexual dimorphism In lobodontine seals females are slightly longer than males Walruses and hooded seals are unique among ice breeding species in that they have pronounced sexual dimorphism in favor of males 31 113 Northern fur seal breeding colony Adult male pinnipeds have several strategies to ensure reproductive success Otariids establish territories containing resources that attract females such as shade tide pools or access to water Territorial boundaries are usually marked by natural breaks in the substrate 116 and some may be fully or partially underwater 117 118 Males defend their territorial boundaries with threatening vocalizations and postures but physical fights are usually avoided 119 Individuals also return to the same territorial site each breeding season In certain species like the Steller sea lion and northern fur seal a dominant male can maintain a territory for as long as 2 3 months Females can usually move freely between territories and males are unable to coerce them but in some species such as the northern fur seal South American sea lion and Australian sea lion males can successfully contain females in their territories and prevent them from leaving In some phocid species like the harbor seal Weddell seal and bearded seal the males have underwater territories called maritories near female haul out areas 116 These are also maintained by vocalizations 120 The maritories of Weddell seal males can overlap with female breathing holes in the ice 113 Male northern elephant seals fighting for dominance and females Lek systems are known to exist among some populations of walruses 116 These males cluster around females and try to attract them with elaborate courtship displays and vocalizations 116 121 Lekking may also exist among California sea lions South American fur seals New Zealand sea lions and harbor seals 116 122 In some species including elephant seals and grey seals males will try to lay claim to the desired females and defend them from rivals 116 Elephant seal males establish dominance hierarchies with the highest ranking males the alpha males maintaining harems of as many as 30 100 females These males commonly disrupt the copulations of their subordinates while they themselves can mount without inference They will however break off mating to chase off a rival 123 Grey seal males usually claim a location among a cluster of females whose members may change over time 124 while males of some walrus populations try to monopolize access to female herds 116 Male harp seals crabeater seals and hooded seals follow and defend lactating females in their vicinity usually one or two at a time 125 and wait for them to reach estrus 115 116 Younger or subdominant male pinnipeds may attempt to achieve reproductive success in other ways Subadult elephant seals will sneak into female clusters and try to blend in by pulling in their noses They also harass and attempt to mate with females that head out to the water In otariid species like the South American and Australian sea lions non territorial subadults form gangs and cause chaos within the breeding rookeries to increase their chances of mating with females 126 Alternative mating strategies also exist in young male grey seals which do have some success 124 Female pinnipeds do appear to have some choice in mates particularly in lek breeding species like the walrus but also in elephant seals where the males try to dominate all the females that they want to mate with 121 When a female elephant seal or grey seal is mounted by an unwanted male she tries to squirm and get away while croaking and slapping him with her tail This commotion attracts other males to the scene and the most dominant will end the copulation and attempt to mate with the female himself 127 128 Dominant female elephant seals stay in the center of the colony where they are more likely to mate with a dominant male while peripheral females are more likely to mate with subordinates 129 Female Steller sea lions are known to solicit mating with their territorial males 121 Birth and parenting Edit With the exception of the walrus which has five to six year long inter birth intervals female pinnipeds enter estrous shortly after they give birth 130 All species go through delayed implantation wherein the embryo remains in suspended development for weeks or months before it is implanted in the uterus Delayed implantation postpones the birth of young until the female hauls out on land or until conditions for birthing are favorable 130 131 Gestation in seals including delayed implantation typically lasts a year 130 For most species birthing takes place in the spring and summer months 132 Typically single pups are born 130 twins are uncommon and have high mortality rates 131 Pups of most species are born precocial 130 Harp seal mother nursing pup Unlike terrestrial mammals pinniped milk has little to no lactose 133 Mother pinnipeds have different strategies for maternal care and lactation Phocids such as elephant seals grey seals and hooded seals remain on land or ice and fast during their relatively short lactation period four days for the hooded seal and five weeks for elephant seals The milk of these species consist of up to 60 fat allowing the young to grow fairly quickly In particular northern elephant seal pups gain 4 kg 9 lb each day before they are weaned Some pups may try to steal extra milk from other nursing mothers and gain weight more quickly than others Alloparenting occurs in these fasting species 130 while most northern elephant seal mothers nurse their own pups and reject nursings from alien pups some do accept alien pups with their own 134 Adult Antarctic fur seal with pups For otariids and some phocids like the harbor seal mothers fast and nurse their pups for a few days at a time In between nursing bouts the females leave their young onshore to forage at sea These foraging trips may last anywhere between a day and two weeks depending on the abundance of food and the distance of foraging sites While their mothers are away the pups will fast 130 Lactation in otariids may last 6 11 months in the Galapagos fur seal it can last as long as 3 years Pups of these species are weaned at lower weights than their phocid counterparts 135 Walruses are unique in that mothers nurse their young at sea 130 The female rests at the surface with its head held up and the young suckle upside down 136 Young pinnipeds typically learn to swim on their own and some species can even swim at birth Other species may wait days or weeks before entering the water Elephant seals do not swim until weeks after they are weaned 137 Male pinnipeds generally play little role in raising the young 138 Male walruses may help inexperienced young as they learn to swim and have even been recorded caring for orphans 139 Male California sea lions have been observed to help shield swimming pups from predators 140 Males can also pose threats to the safety of pups In terrestrially breeding species pups may get crushed by fighting males 138 Subadult male South America sea lions sometimes abduct pups from their mothers and treat them like adult males treat females This helps them gain experience in controlling females Pups can get severely injured or killed during abductions 141 Female New Zealand sea lions move inland with their pups to protect them 85 86 Communication Edit Walrus males are known to use vocalizations to attract mates Pinnipeds can produce a number of vocalizations such as barks grunts rasps rattles growls creaks warbles trills chirps chugs clicks and whistles While most vocals are audible to the human ear a captive leopard seal was recorded making ultrasonic calls underwater In addition the vocals of northern elephant seals may produce infrasonic vibrations Vocals are produced both in air and underwater Otariids are more vocal on land while phocids are more vocal in water Antarctic seals are more vocal on land or ice than Arctic seals due to a lack of terrestrial and pagophilic predators like the polar bear 120 Male vocals are usually of lower frequencies than those of the females 142 Vocalizations are particularly important during the breeding seasons Dominant male elephant seals advertise their status and threaten rivals with clap threats and loud drum like calls 143 that may be modified by the proboscis 144 Male otariids have strong barks growls roars and whickers Male walruses are known to produce distinctive gong like calls when attempting to attract females They can also create somewhat musical sounds with their inflated throats 143 The Weddell seal has perhaps the most elaborate vocal repertoire with separate sounds for airborne and underwater contexts 145 Underwater vocals include trills chirps chugs and knocks The calls appear to contain prefixes and suffixes that serve to emphasize a message 120 The underwater vocals of Weddell seals can last 70 seconds which is long for a marine mammal call Some calls have around seven rhythm patterns and are comparable to birdsongs and whalesongs 146 Similar calls have been recorded in other lobodontine seals 147 and in bearded seals 148 In some pinniped species there appear to be geographic differences in vocalizations known as dialects 149 while certain species may even have individual variations in expression 150 These differences are likely important for mothers and pups who need to remain in contact on crowded beaches 142 Otariid females and their young use mother pup attraction calls to help them reunite when the mother returns from foraging at sea 142 The calls are described are loud and bawling 151 Female elephant seals make an unpulsed attraction call when responding to their young When threatened by other adults or when pups try to suckle females make a harsh pulsed call 152 Pups may also vocalize when playing in distress or when prodding their mothers to allow them to suckle 151 152 Sea lion balancing a ball Non vocal communication is not as common in pinnipeds as in cetaceans Nevertheless when disturbed by intruders harbor seals and Baikal seals may slap their fore flippers against their bodies as warnings Teeth chattering hisses and exhalations are also made as aggressive warnings Visual displays also occur Weddell seals will make an S shaped posture when patrolling under the ice and Ross seals will display the stripes on their chests and teeth when approached 120 Male hooded seals use their inflatable nasal membranes to display to and attract females 32 Intelligence Edit In a match to sample task study a single California sea lion was able to demonstrate an understanding of symmetry transitivity and equivalence a second seal was unable to complete the tasks 153 They demonstrate the ability to understand simple syntax and commands when taught an artificial sign language though they only rarely used the signs semantically or logically 154 In 2011 a captive California sea lion named Ronan was recorded bobbing its head in synchrony to musical rhythms This rhythmic entrainment was previously seen only in humans parrots and other birds possessing vocal mimicry 155 Adult male elephant seals appear to memorize both the rhythm and timbre of their rivals calls 156 In 1971 a captive harbor seal named Hoover was trained to imitate human words phrases and laughter 157 For sea lions used in entertainment trainers toss a ball at the animal so it may accidentally balance it or hold the ball on its nose thereby gaining an understanding of the behavior desired It may require a year to train a sea lion to perform a trick for the public Its long term memory allows it to perform a trick after at least three months of non performance 140 Human relations EditCultural depictions Edit Further information List of fictional pinnipeds Inuit seal sculptures at the Linden Museum Various human cultures have for millennia depicted pinnipeds The anthropologist A Asbjorn Jon has analysed beliefs of the Celts of Orkney and Hebrides who believed in selkies seals that could change into humans and walk on land 158 Seals are also of great importance in the culture of the Inuit 159 In Inuit mythology the goddess Sedna rules over the sea and marine animals She is depicted as a mermaid occasionally with a seal s lower body In one legend seals whales and other marine mammals were formed from her severed fingers 160 One of the earliest Ancient Greek coins depicts the head of a seal and the animals were mentioned by Homer and Aristotle The Greeks associated them with both the sea and sun and were considered to be under the protection of the gods Poseidon and Apollo 161 The Moche people of ancient Peru worshipped the sea and its animals and often depicted sea lions in their art 162 In modern culture pinnipeds are thought of as cute playful and comical figures 163 In captivity Edit Pinnipeds can be found in facilities around the world as their large size and playfulness make them popular attractions 164 Seals have been kept in captivity since at least Ancient Rome and their trainability was noticed by Pliny the Elder Zoologist Georges Cuvier noted during the 19th century that wild seals show considerable fondness for humans and stated that they are second only to some monkeys among wild animals in their easy tamability Francis Galton noted in his landmark paper on domestication that seals were a spectacular example of an animal that would most likely never be domesticated despite their friendliness and desire for comfort due to the fact that they serve no practical use for humans 165 Captive sea lion at Kobe Oji Zoo Kobe Japan Some modern exhibits have rocky backgrounds with artificial haul out sites and a pool while others have pens with small rocky elevated shelters where the animals can dive into their pools More elaborate exhibits contain deep pools that can be viewed underwater with rock mimicking cement as haul out areas The most common pinniped species kept in captivity is the California sea lion as it is both easy to train and adaptable Other popularly kept species include the grey seal and harbor seal Larger animals like walruses and Steller sea lions are much less common 164 Some organizations such as the Humane Society of the United States and World Animal Protection object to keeping pinnipeds and other marine mammals in captivity They state that the exhibits could not be large enough to house animals that have evolved to be migratory and a pool could never replace the size and biodiversity of the ocean They also state that the tricks performed for audiences are exaggerated variations of their natural behaviors and distract the people from the animal s unnatural environment 166 California sea lions are used in military applications by the U S Navy Marine Mammal Program including detecting naval mines and enemy divers In the Persian Gulf the animals have been trained to swim behind divers approaching a U S naval ship and attach a clamp with a rope to the diver s leg Navy officials say that the sea lions can do this in seconds before the enemy realizes what happened 167 Organizations like PETA believe that such operations put the animals in danger 168 The Navy insists that the sea lions are removed once their mission is complete 169 Hunting Edit Main article Seal hunting Men killing northern fur seals on Saint Paul Island Alaska in the mid 1890s Humans have hunted seals since the Stone Age Originally seals were hit with clubs during haul out Eventually seal hunters used harpoons to spear the animals from boats out at sea and hooks for killing pups on ice or land They were also trapped in nets The use of firearms in seal hunting during the modern era drastically increased the number of killings Pinnipeds are typically hunted for their meat and blubber The skins of fur seals and phocids are made into coats and the tusks of walruses continue to be used for carvings or as ornaments 170 There is a distinction between the subsistence hunting of seals by indigenous peoples of the Arctic and commercial hunting subsistence hunters typically use seal products for themselves and depend on them for survival 171 National and international authorities have given special treatment to aboriginal hunters since their methods of killing are seen as less destructive and wasteful This distinction is being questioned as indigenous people are using more modern weaponry and mechanized transport to hunt with and are selling seal products in the marketplace Some anthropologists argue that the term subsistence should also apply to these cash based exchanges as long as they take place within local production and consumption More than 100 000 phocids especially ringed seals as well as around 10 000 walruses are harvested annually by native hunters 170 Protests of Canada s seal hunts Commercial sealing was historically just as important an industry as whaling Exploited species included harp seals hooded seals Caspian seals elephant seals walruses and all species of fur seal 171 The scale of seal harvesting decreased substantially after the 1960s 170 after the Canadian government reduced the length of the hunting season and implemented measures to protect adult females 172 Several species that were commercially exploited have rebounded in numbers for example Antarctic fur seals may be as numerous as they were prior to harvesting The northern elephant seal was hunted to near extinction in the late 19th century with only a small population remaining on Guadalupe Island It has since recolonized much of its historic range but has a population bottleneck 171 Conversely the Mediterranean monk seal was extirpated from much of its former range which stretched from the Mediterranean to the Black Sea and northwest Africa and only remains in the northeastern Mediterranean and some parts of northwest Africa 173 Several species of pinniped continue to be harvested The Convention for the Conservation of Antarctic Seals allows limited hunting of crabeater seals leopard seals and Weddell seals However Weddell seal hunting is prohibited between September and February if the animal is over one year of age to ensure breeding stocks are healthy Other species protected are southern elephant seals Ross seals and Antarctic fur seals 171 The Government of Canada permits the hunting of harp seals This has been met with controversy and debate Proponents of seal hunts insist that the animals are killed humanely and the white coated pups are not taken while opponents argue that it is irresponsible to kill harp seals as they are already threatened by declining habitat 174 175 The Caribbean monk seal has been killed and exploited by Europeans settlers and their descendants since 1494 starting with Christopher Columbus himself The seals were easy targets for organized sealers fishermen turtle hunters and buccaneers because they evolved with little pressure from terrestrial predators and were thus genetically tame In the Bahamas as many as 100 seals were slaughtered in one night In the mid nineteenth century the species was thought to have gone extinct until a small colony was found near the Yucatan Peninsula in 1886 Seal killings continued and the last reliable report of the animal alive was in 1952 The IUCN declared it extinct in 1996 176 The Japanese sea lion was common around the Japanese islands but overexploitation and competition from fisheries drastically decreased the population in the 1930s The last recorded individual was a juvenile in 1974 177 Conservation issues EditAs of 2021 the International Union for Conservation of Nature IUCN recognizes 36 pinniped species With the Japanese sea lion and the Caribbean monk seal recently extinct ten more are considered at risk as they are ranked Endangered Hawaiian monk seal Mediterranean monk seal Galapagos fur seal Australian sea lion New Zealand sea lion Caspian seal and Galapagos sea lion or Vulnerable northern fur seal hooded seal and walrus 178 There has been some debate over the cause of the decline of Steller sea lions in Alaska since the 1970s 179 Pinnipeds face various threats They are unintentionally caught in fishing nets by commercial fisheries and accidentally swallow fishing hooks Gillnetting and Seine netting is a significant cause of mortality in seals and other marine mammals Species commonly entangled include California sea lions Hawaiian monk seals northern fur seals and brown fur seals 171 Pinnipeds are also affected by marine pollution High levels of organic chemicals accumulate in these animals since they are near the top of food chains and have large reserves of blubber Lactating mothers can pass the toxins on to their young These pollutants can cause gastrointestinal cancers decreased reproductivity and greater vulnerability to infectious diseases 180 Other man made threats include habitat destruction by oil and gas exploitation encroachment by boats 171 and underwater noise 181 Grey seal on beach occupied by humans near Niechorze Poland Pinnipeds and humans may compete for space and resources Species that live in polar habitats are vulnerable to the effects of climate change on oceans particularly declines in sea ice 182 In 2010 and 2011 sea ice in the Northwest Atlantic was at or near an all time low and harp seals as well as ringed seals that bred on thin ice saw increased death rates 89 183 Antarctic fur seals in South Georgia in the South Atlantic Ocean saw extreme reductions over a 20 year study during which scientists measured increased sea surface temperature anomalies 184 Some species have become so numerous that they conflict with local people In the United States pinnipeds are protected under the Marine Mammal Protection Act of 1972 MMPA Since that year California sea lion populations have risen to 250 000 These animals began exploiting more man made environments like docks for haul out sites Many docks are not designed to withstand the weight of several resting sea lions Wildlife managers have used various methods to control the animals and some city officials have redesigned docks so they can better withstand use by sea lions 185 186 The return of sea lions in New Zealand has caused unique human conflicts for pinnipeds as breeding females move up to 2 kilometres 1 2 mi inland to protect their pups 85 87 As consequence they have been hit by cars on roads deliberately killed and disturbed by domestic dogs Human infrastructures such as residential areas roads fences and private lands have also affected their dispersal and breeding success 187 Conservation efforts are being made by predicting potential areas of human wildlife conflict to direct proactive measures that facilitate coexistence between humans and this endangered species such as making road signs and engaging with local communities 188 189 187 Seals also conflict with fisherman 190 In 2007 MMPA was amended to permit the lethal removal of sea lions from salmon runs at Bonneville Dam 191 In the 1980s and 1990s South African politicians and fisherman demanded that brown fur seals be culled believing that the animals competed with commercial fisheries Scientific studies found that culling fur seals would actually have a negative effect on the fishing industry and the culling option was dropped in 1993 192 Notes Edit This term typically excludes the walrus in everyday English In science it is also sometimes restricted to the true seals of the family Phocidae This article uses it for all pinnipeds References Edit Illiger J K W 1811 Prodromus Systematis Mammalium et Avium in Latin Sumptibus C Salfeld pp 138 39 Elias J S 2007 Science 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the original on 28 December 2021 Retrieved 22 November 2021 Pannett Rachel Francis Ellen 13 November 2021 Cheeky sea lions are returning to New Zealand s shores and locals are learning to share the coast The Washington Post Retrieved 21 November 2021 Sheets B 3 February 2012 As sea lion populations grow conflicts increase Herald Net Archived from the original on 21 September 2013 Retrieved 17 August 2013 Endangered Salmon Predation Prevention Act Northwest Regional Office National Oceanic and Atmospheric Administration 26 July 2012 Archived from the original on 15 October 2011 Retrieved 9 June 2012 Lavigne D 2003 Marine mammals and fisheries The role of science in the culling debate In Gales N Hindell M Kirkwood R eds Marine Mammals Fisheries Tourism and Management Issues Fisheries Tourism and Management Csiro Publishing p 41 ISBN 978 0 643 06953 4 Bibliography Edit Berta Annalisa 2012 Return to the Sea The life and evolutionary times of marine mammals University of California Press ISBN 978 0 520 27057 2 Berta Annalisa Sumich James L Kovacs Kit M 2006 Marine Mammals Evolutionary Biology 2nd ed Academic Press ISBN 978 0 12 088552 7 MacDonald David ed 2001 The Encyclopedia of Mammals 2nd ed Oxford University Press ISBN 978 0 7607 1969 5 Perrin William F Wursig Bernd Thewissen J G M eds 2009 Encyclopedia of Marine Mammals 2nd ed Academic Press ISBN 978 0 12 373553 9 Riedman Marianne 1990 The Pinnipeds Seals sea lions and walruses University of California Press ISBN 978 0 520 06497 3 Scheffer Victor B 1958 Seals Sea Lions and Walruses A Review of the Pinnipedia Stanford University Press ISBN 978 0 8047 0544 8 External links Edit Look up pinniped in Wiktionary the free dictionary Wikimedia Commons has media related to Pinnipedia Wikiquote has quotations related to Pinniped Wikisource has the text of the 1911 Encyclopaedia Britannica article Seal Seal Conservation home page Seal Conservation Society Pinnipeds Seals sea lions and walruses Department of Fisheries National Oceanographic and Atmospheric Administration Archived from the original on 19 July 2014 Pinniped Research Lab PEARL home page Pinniped Ecology Applied Research Laboratory Oregon State University Archived from the original on 5 July 2019 Retrieved 11 August 2013 Pinniped Laboratory home page Pinniped Cognition amp Sensory Systems Laboratory University of California Santa Cruz Retrieved from https en wikipedia org w index php title Pinniped amp oldid 1136145062, wikipedia, wiki, book, books, library,

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