Benthos is the
community of
organisms that live in the benthic zone, that is, on, in, or near the bottom of a
stream,
river,
lake, or
ocean. This community lives in or near marine or freshwater
sedimentary environments, from
tidal pools along the
foreshore, out to the
continental shelf, and then down to the
abyssal depths. The term
benthos, coined by
Haeckel in 1891, comes from the
Greek noun 'depth of the ocean'. Additionally to oceans,
benthos is also used in
freshwater biology to refer to organisms at the bottom of freshwater
bodies of water, such as streams, rivers, and lakes. There is also a redundant, occasionally used synonym,
benthon. Benthos is also referred to more loosely and informally as
bottom dwellers or
bottom feeders. Light is an important energy source for shallow benthic systems. However, because light is
absorbed before it can reach deep ocean water, the energy source for deep benthic ecosystems is often organic matter from higher up in the water column that drifts down to the depths. This
dead and decaying matter sustains the benthic
food chain; most organisms in the benthic zone are
scavengers or
detritivores. Many organisms adapted to deep-water pressure cannot survive in the upper parts of the
water column. The pressure difference can be significant (approximately one
atmosphere for every 10 metres of water depth). Compared to the relatively featureless
pelagic zone, the benthic zone offers physically diverse habitats. There is a huge range in how much light and warmth is available, and in the depth of water or extent of
intertidal immersion. The seafloor varies widely in the types of
sediment it offers.
Burrowing animals can find protection and food in soft, loose sediments such as
mud,
clay and
sand.
Sessile species such as
oysters and
barnacles can attach themselves securely to hard, rocky substrates. As adults they can remain at the same site, shaping depressions and crevices where mobile animals find refuge. This greater diversity in benthic habitats has resulted in a higher diversity of benthic species. The number of benthic animal species exceeds one million. This far exceeds the number of pelagic animal species (about 5000 larger zooplankton species, 22,000 pelagic fish species and 110 marine mammal species). Benthos are the organisms that live in the benthic zone, and are different from those elsewhere in the
water column; even within the benthic zone variations in such factors as substrate, light penetration, temperature and salinity give rise to distinct differences, delineated vertically, in the groups of organisms supported. Many organisms adapted to deep-water pressure cannot survive in the upper parts of the water column: the pressure difference can be very significant (approximately one
atmosphere for each 10 meters of water depth). Many have adapted to live on the substrate (bottom) or within the upper layers of the bottom. In their habitats they can be considered as dominant creatures, but they are often a source of prey for
Carcharhinidae such as the
lemon shark. Because light does not penetrate very deep into ocean-water, the energy source for the benthic ecosystem is often
marine snow. Marine snow is organic matter from higher up in the water column that drifts down to the depths. This
dead and decaying matter sustains the benthic
food chain; most organisms in the benthic zone are
scavengers or
detritivores. Some
microorganisms use
chemosynthesis to produce
biomass. Benthic organisms can be divided into two categories based on whether they make their home on the ocean floor or a few centimeters into the ocean floor. Those living on the surface of the ocean floor are known as
epifauna. Those who live burrowed into the ocean floor are known as
infauna. File:Floridian seagrass bed.jpg|
Seagrass File:Nerr0878.jpg|
Echinoderms File:Ascidian (Rhopalaea Crassa) (4 cm).png|
Sea squirts
Meiobenthos Meiobenthos, prefix , comprises tiny benthic organisms that are less than about 1 mm but greater than about 0.1 mm in size. Some examples are
nematodes,
foraminiferans,
tardigrades,
gastrotriches and smaller
crustaceans such as
copepods and
ostracodes. File:Ammonia tepida.jpg|
Foraminiferan File:Gastrotrich.jpg|
Gastrotrich File:copepodkils.jpg|
Copepod File:SEM image of Milnesium tardigradum in active state - journal.pone.0045682.g001-2.png|
Tardigrade (water bear)
Microbenthos Microbenthos, prefix from the Greek
mikrós 'small', comprises microscopic benthic organisms that are less than about 0.1 mm in size. Some examples are
bacteria,
diatoms,
ciliates,
amoeba,
flagellates. File:Diatoms through the microscope.jpg|
Diatoms File:Paramecium bursaria.jpg|
Ciliate File:CSIRO ScienceImage 7609 SEM dinoflagellate.jpg|
Dinoflagellates Marine microbenthos are microorganisms that live in the benthic zone of the ocean – that is, near or on the seafloor, or within or on surface seafloor sediments. Microbenthos are found everywhere on or about the seafloor of continental shelves, as well as in deeper waters, with greater diversity in or on seafloor sediments. In
photic zones benthic diatoms dominate as photosynthetic organisms. In
intertidal zones changing
tides strongly control opportunities for microbenthos. File:Elphidium-incertum hg.jpg|
Elphidium a widespread abundant genus of benthic forams File:FMIB 50025 Textilaria.jpeg|
Heterohelix, an extinct genus of benthic forams File:Gastrotrich.jpg|
Darkfield photo of a
gastrotrich, 0.06-3.0 mm long, a worm-like animal living between sediment particles File:Pliciloricus enigmatus.jpg|Armoured
Pliciloricus enigmaticus, about 0.2 mm long, live in spaces between marine gravel Both foraminifera and diatoms have
planktonic and
benthic forms, that is, they can drift in the
water column or live on
sediment at the bottom of the ocean. Regardless of form, their shells sink to the seafloor after they die. These shells are widely used as
climate proxies. The chemical composition of the shells are a consequence of the chemical composition of the ocean at the time the shells were formed. Past water temperatures can be also be inferred from the ratios of stable
oxygen isotopes in the shells, since lighter isotopes evaporate more readily in warmer water leaving the heavier isotopes in the shells. Information about past climates can be inferred further from the abundance of forams and diatoms, since they tend to be more abundant in warm water.The sudden
extinction event which killed the dinosaurs 66 million years ago also rendered extinct three-quarters of all other animal and plant species. However, deep-sea benthic forams flourished in the aftermath. In 2020 it was reported that researchers have examined the chemical composition of thousands of samples of these benthic forams and used their findings to build the most detailed climate record of Earth ever. Some
endoliths have extremely long lives. In 2013 researchers reported evidence of endoliths in the ocean floor, perhaps millions of years old, with a generation time of 10,000 years. These are slowly metabolizing and not in a dormant state. Some
Actinomycetota found in
Siberia are estimated to be half a million years old.
By trophic level Zoobenthos Zoobenthos, prefix , animals belonging to the benthos. Examples include
polychaete worms, starfish and anemones.
Phytobenthos Phytobenthos, prefix , plants belonging to the benthos, mainly benthic
diatoms and
macroalgae (
seaweed).
By location Endobenthos Endobenthos (or endobenthic), prefix , lives buried, or burrowing in the sediment, often in the
oxygenated top layer, e.g., a
sea pen or a
sand dollar.
Epibenthos Epibenthos (or epibenthic), prefix , lives on top of the sediments, e.g.,
sea cucumber or a sea snail.
Hyperbenthos Hyperbenthos (or hyperbenthic), prefix , lives just above the sediment, e.g., a
rock cod.
By habitat Modern
seafloor mapping technologies have revealed linkages between seafloor geomorphology and benthic habitats, in which suites of benthic communities are associated with specific geomorphic settings. Examples include
cold-water coral communities associated with seamounts and submarine canyons,
kelp forests associated with inner shelf rocky reefs and
rockfish associated with rocky escarpments on continental slopes. In
oceanic environments,
habitats can also be zoned by depth. From the shallowest to the deepest are: the
epipelagic (less than 200 meters), the
mesopelagic (200–1,000 meters), the
bathyal (1,000–4,000 meters), the
abyssal (4,000–6,000 meters) and the deepest, the
hadal (below 6,000 meters). Human impacts have occurred at all ocean depths, but are most significant on shallow continental shelf and slope habitats. Many benthic organisms have retained their historic evolutionary characteristics. Some organisms are
significantly larger than their relatives living in shallower zones, largely because of higher oxygen concentration in deep water. It is not easy to map or observe these organisms and their habitats, and most modern observations are made using
remotely operated underwater vehicles (ROVs), and rarely crewed
submersibles.
Tide pools provide somewhat demanding benthic homes for organisms such as
sea stars,
mussels and
clams. Inhabitants deal with a frequently changing
environment: fluctuations in water
temperature, salinity, and
oxygen content. Hazards include
waves, strong
currents, exposure to midday sun and predators.
Waves can dislodge mussels and draw them out to sea.
Gulls pick up and drop
sea urchins to break them open. Sea stars prey on mussels and are eaten by gulls themselves.
Black bears are known to sometimes feast on intertidal creatures at low tide. Although tide pool organisms must avoid getting washed away into the
ocean, drying up in the sun, or being eaten, they depend on the tide pool's constant changes for food. Tide pools contain complex
food webs that can vary based on the climate. == Ecological roles ==