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Underwater environment

The underwater environment refers to the totality of habitats and ecosystems immersed in liquid within natural or artificial bodies such as , seas, lakes, rivers, and reservoirs, where water serves as the primary medium shaping physical, chemical, and biological processes. These environments span vast scales, with alone covering approximately 70% of Earth's surface and holding an average depth of 3,682 meters (12,080 feet), creating diverse zones influenced by factors like depth, currents, and . Physical characteristics define the underwater environment's variability, beginning with pressure, which increases by roughly 1 atmosphere (14.7 pounds per ) for every 10 of depth due to the weight of overlying , reaching extremes of over 1,100 times at the 's deepest points. Temperature gradients form distinct layers: surface waters in the epipelagic (0–200 ) range from -2°C to 36°C depending on and season, while deeper zones stabilize near 4°C, with the marking a rapid transition around 200–1,000 . Salinity, averaging 35 parts per thousand (3.5%) in , affects and circulation, varying slightly with , , and freshwater inflows but remaining relatively constant in open s. Light penetration diminishes rapidly, fully illuminating only the sunlit epipelagic up to 200 , fading to twilight in the mesopelagic (200–1,000 ), and absent in deeper bathypelagic (1,000–4,000 ), abyssopelagic (4,000–6,000 ), and hadalpelagic (beyond 6,000 ) zones, where often substitutes for . These properties interact to drive circulation, nutrient distribution, and sediment dynamics across submarine features like continental slopes, canyons, and volcanic structures. Biologically, underwater environments host extraordinary , estimated to include 700,000 to 1 million species, representing a significant portion of through adapted ecosystems. In sunlit coastal and open-ocean areas, marine ecosystems thrive on high , with estuaries supporting high productivity and reefs in the euphotic zone nurturing up to 25% of all marine species despite covering less than 1% of the ocean floor. Deeper realms rely on at hydrothermal vents or from above, fostering unique communities of extremophiles, including tube worms and with specialized traits like large jaws and slow metabolisms to cope with darkness, cold, and pressure. Overall, these habitats underpin global processes, including and oxygen production, with in sunlit waters generating approximately 50% of Earth's oxygen. Human interactions with underwater environments include , resource extraction, and efforts, revealing both opportunities and challenges like geohazards from landslides and the impacts of on acidification and warming. As of 2025, approximately 27.3% of the global seafloor has been mapped to high resolution, with less than 0.001% visually explored, underscoring the vast unknowns in these realms.

Extent and Distribution

Oceans and Seas

The world's oceans constitute the primary components of the underwater environment, encompassing vast saline bodies that cover approximately 71% of Earth's surface with a total area of 361 million square kilometers. These are conventionally divided into five principal basins: , the largest by both area and volume; ; ; , the smallest and northernmost; and , encircling . Together, they hold about 1.335 billion cubic kilometers of water, representing over 97% of Earth's total water volume. These oceans are interconnected through a global network of currents, most notably the , also known as the global , which drives the movement of water masses based on differences in and . This system facilitates the exchange of , nutrients, and oxygen across basins, influencing global climate patterns and marine ecosystems from polar to equatorial regions. For instance, deep waters formed in the North Atlantic flow southward, connecting to the before in the Pacific and Indian Oceans. Vertically, the oceans are stratified into distinct depth zones that reflect variations in light, pressure, and temperature. The epipelagic zone extends from the surface to 200 meters, where sunlight penetrates and supports . Below this lies the (200–1,000 meters), characterized by dim twilight conditions; the (1,000–4,000 meters), a dark midnight realm; the abyssopelagic zone (4,000–6,000 meters), with extreme cold and ; and the hadalpelagic zone beyond 6,000 meters, confined to deep ocean trenches. These zones host diverse adaptations to environmental gradients, from photosynthetic communities near the surface to chemosynthetic life in the depths. Adjacent to the open oceans are semi-enclosed seas, which serve as extensions influenced by continental boundaries, coastal inputs, and restricted water exchange. Examples include the , connected to the Atlantic via the and marked by high salinity due to exceeding inflow; and the , linked to the Atlantic through numerous passages and featuring warmer, nutrient-rich waters from river outflows. These seas exhibit unique hydrological dynamics, such as amplified temperature fluctuations and localized circulation patterns, distinct from the broader oceanic basins.

Inland Waters

Inland waters encompass a diverse array of freshwater bodies situated on landmasses, distinct from systems due to their ecological isolation and reliance on terrestrial inputs. These environments include standing waters like lakes and ponds, flowing systems such as rivers, and transitional zones like wetlands, each playing critical roles in regional , , and nutrient cycling. Unlike vast marine expanses, inland waters exhibit high spatial variability and are often in close proximity to human populations, influencing local climates and . Lakes represent large, relatively still bodies of freshwater, varying from shallow coastal basins to profound tectonic depressions; for instance, in is the deepest, reaching 1,637 meters. Ponds, by contrast, are smaller and shallower, typically with a maximum depth of 5 meters and surface area under 5 hectares, supporting dense aquatic and seasonal fluctuations in levels. Rivers form dynamic, flowing networks characterized by alternating shallow, turbulent riffles—where flows rapidly over substrates—and deeper, slower pools that provide refugia and deposition sites. Wetlands, including marshes and swamps, serve as saturated or inundated transitional zones between land and open , often featuring emergent and acting as buffers for nutrient filtration and flood storage. Globally, inland waters are abundant, with approximately 117 million lakes larger than 0.002 km² covering about 4.2 million km², or roughly 3% of Earth's surface. Including impoundments and reservoirs, the total surface area of standing inland waters exceeds 4.6 million km², accounting for more than 3% of continental . River networks span an estimated 35.9 million kilometers worldwide, forming interconnected systems that drain vast catchments and transport sediments and nutrients across landscapes. These distributions highlight the patchwork nature of inland waters, concentrated in regions like forests and high latitudes where glacial legacies prevail. The hydrological cycles of inland waters are driven primarily by terrestrial processes, with inputs from and dominating recharge, while outputs occur through , infiltration, or downstream flow to . In closed-basin lakes, often balances , leading to stable volumes, whereas river-fed systems contribute to oceanic discharge, with global river runoff estimated at about 40,000 km³ annually. Seasonal variations are pronounced in temperate zones, where winter ice cover can persist for months, reducing and altering thermal profiles until melt initiates turnover. These cycles underscore the vulnerability of inland waters to climatic shifts, as altered patterns can amplify droughts or floods. A distinctive feature of many inland lakes is thermal , which divides the into layers: the warm, well-mixed at the surface; the colder, denser hypolimnion at depth; and the intervening , a narrow zone of rapid temperature decline that inhibits vertical mixing. This , most evident in summer, creates distinct habitats—oxygen-rich in the for photosynthetic organisms and potentially anoxic in the hypolimnion—while fall and spring cooling promotes seasonal overturns that redistribute nutrients. Such dynamics are less uniform in shallow or fast-flowing , where or prevents strong layering.

Subsurface and Artificial Bodies

Subterranean waters encompass a variety of isolated underwater environments, including aquifers, caves, and hydrothermal vents, which are characterized by their limited connectivity to surface systems and unique hydrological dynamics. Aquifers, such as the in , represent vast subterranean reservoirs that store and transmit through porous rock formations over immense areas. This basin covers more than 1.7 million square kilometers, underlying parts of , , , and the , and serves as a critical freshwater resource despite its confined nature. Underwater caves, including cenotes and anchialine systems, further exemplify subsurface isolation, often forming in landscapes where soluble bedrock like dissolves over time. Cenotes in the , , are sinkholes created by the collapse of cavern roofs in porous , providing access to underground rivers and aquifers that were vital to ancient civilizations for water supply. These features typically exhibit clear, oligotrophic waters with depths ranging from shallow pools to over 100 meters, supporting specialized ecosystems adapted to low nutrient levels. Anchialine systems, defined as coastal caves or pools with subsurface connections to the sea but no surface outlet, occur in regions like the , , and the , featuring stratified waters that mix freshwater from inland sources with saline intrusions, resulting in brackish conditions ideal for endemic crustaceans and other stygobitic organisms. Hydrothermal vents, particularly black smokers along mid-ocean ridges, add a dynamic geothermal dimension to subsurface underwater environments, where circulates through fractured heated by underlying . These vents, such as those at the or , expel superheated, mineral-rich fluids at temperatures up to 400°C through chimney-like structures formed by precipitated sulfides, creating dark plumes that give black smokers their name. The resulting chemosynthetic ecosystems thrive independently of sunlight, relying on microbial oxidation of for energy. Artificial underwater bodies, engineered by humans for resource management, research, or industry, mimic and modify natural subsurface conditions while introducing controlled isolation. Reservoirs like the lake in form expansive artificial lakes by impounding rivers, with the holding a total capacity of 39.3 km³ across a 660 km stretch, altering regional and creating stable, deep-water habitats. Aquaculture ponds, often shallow and undrainable, are constructed worldwide for intensive , featuring earthen or lined basins typically 1-2 meters deep that maintain optimal through and fertilization to support like or in high densities. Flooded mines, such as open-pit operations converted to lakes after extraction ceases, become inadvertent underwater repositories; for instance, the Island Copper pit lake in was intentionally flooded with seawater to over 90% capacity, forming a stratified, metal-laden that requires ongoing management. Underwater laboratories, exemplified by the off , provide pressurized habitats at 20 meters depth, enabling to conduct extended dives for marine research in a controlled, isolated setting equivalent to space analogs. Isolation in these subsurface and artificial bodies stems from physical barriers like impermeable rock layers, limited light penetration leading to aphotic conditions, and stable thermal regimes decoupled from surface fluctuations. Groundwater temperatures in aquifers remain relatively constant year-round, often between 10-15°C in temperate regions, due to the insulating effects of overlying sediments. Flow rates in porous aquifers typically range from 1 to 10 meters per day, facilitating slow but persistent movement through fractures and matrix pores, which enhances by minimizing exchange with surface waters. Human activities profoundly influence these environments, particularly through engineering and land use, amplifying contamination risks in both natural and artificial settings. In karst topography prevalent in cave systems like cenotes, rapid conduit flow through dissolved limestone channels accelerates pollutant transport from surface spills or agriculture, rendering shallow aquifers highly vulnerable to nitrates, pathogens, and heavy metals with minimal natural filtration. Artificial bodies face similar threats; reservoirs and aquaculture ponds can accumulate sediments and chemicals from upstream runoff, while flooded mines often harbor acidic, metal-rich waters that leach into adjacent groundwater, necessitating remediation to prevent broader ecological harm.

Physical Properties

Density, Pressure, and Buoyancy

The density of water in underwater environments varies primarily with temperature, salinity, and pressure, influencing all fluid dynamics beneath the surface. In freshwater systems at the surface and standard temperature (around 4°C), water density is approximately 1000 kg/m³. Seawater density at the surface typically ranges from 1025 to 1030 kg/m³, owing to the addition of dissolved salts that increase mass without proportionally increasing volume. A linear approximation for these variations, valid for small changes near reference conditions (e.g., ρ₀ = 1025 kg/m³, T₀ = 25°C, S₀ = 35 psu), is given by ρ ≈ ρ₀ [1 - β (T - T₀) + α (S - S₀)], where β ≈ 2 × 10^{-4} °C^{-1} is the thermal expansion coefficient (density decreases with rising temperature), and α ≈ 8 × 10^{-4} psu^{-1} is the saline contraction coefficient (density increases with salinity). This equation captures how warmer water expands and becomes less dense, while saltier water contracts and becomes denser, driving stratification in aquatic bodies. Hydrostatic pressure in underwater environments arises from the weight of the fluid column above a given point and follows the equation P = ρ g h, where ρ is fluid density, g is gravitational acceleration (≈9.8 m/s²), and h is depth. This pressure increases linearly with depth, adding approximately 1 atmosphere (atm) for every 10 meters of descent in seawater, due to the combined effects of density and gravity. At the surface, pressure is atmospheric (about 1 atm absolute), but underwater measurements often use gauge pressure (relative to surface atmospheric pressure) for practical purposes, such as in diving or instrumentation; absolute pressure is the total, including the surface component. Over the ocean's average depth of about 3700 m, this results in pressures exceeding 370 atm, profoundly affecting submerged objects and structures. Buoyancy, the upward force on an object in a , is governed by , which states that the buoyant force F_b equals the weight of the displaced : F_b = ρ_f g V_d, where ρ_f is the density, V_d is the displaced , and g is . For full submersion, V_d is the object's ; partial submersion occurs when F_b balances the object's weight. is achieved when an object's average density matches the surrounding 's, allowing it to remain suspended without active , as seen in or marine organisms. Water's low compressibility—its is approximately 2.2 GPa, making it about 20,000 times less compressible than air ( ≈ 10^5 Pa)—ensures that density and buoyant forces remain relatively stable with depth, unlike in gaseous media where significantly alters . Density variations create distinct layers in underwater environments, notably and . A forms where temperature decreases rapidly with depth, causing a sharp density gradient (often 100–1000 m below the surface in temperate oceans) that inhibits vertical mixing and traps heat in surface layers. Similarly, a arises from abrupt changes, such as in estuaries or polar regions, leading to density jumps that further stratify the and influence circulation patterns. These interfaces, where density can change by 1–5 /m³ over tens of meters, act as barriers to exchange between layers, shaping the overall structure of underwater environments.

Light Penetration and Visibility

Light penetration in underwater environments is governed by the attenuation of electromagnetic radiation, primarily visible , as it travels through water. The intensity of light decreases exponentially with depth according to the Beer-Lambert law, expressed as I = I_0 e^{-k d}, where I is the light intensity at depth d, I_0 is the surface intensity, and k is the , typically ranging from 0.05 to 0.2 m⁻¹ in clear oceanic water. This arises from by water molecules and by suspended particles, limiting the depth to which sufficient reaches for biological processes like . In the clearest waters, blue wavelengths (around 450-500 nm) penetrate the deepest, up to approximately 200 meters, while red wavelengths (above 600 ) are absorbed within the first few meters due to strong molecular by water. Key factors influencing light penetration include inherent absorption by pure water, which is minimal for light but increases for longer wavelengths, and turbidity caused by such as , sediments, and dissolved organic compounds. These elements elevate the , reducing visibility and the extent of the —the uppermost layer (generally 0-200 meters) where light supports net and . Below this lies the , where perpetual darkness prevails, and light levels drop to less than 1% of surface intensity, rendering visual navigation without sources. Visibility in underwater settings is often quantified using the Secchi depth, a simple metric obtained by lowering a white disk until it disappears from view, with global oceanic ranges typically from 1 to 80 meters depending on . In turbid coastal waters, Secchi depths are shallower (often under 10 meters) due to high particle loads, whereas open ocean gyres can exceed 50 meters. In the deep sea's aphotic regions, from organisms like and provides a compensatory light source, enabling visibility for predation and communication in otherwise lightless environments. Variations in light penetration are pronounced between environments: coastal and estuarine waters exhibit murkiness with coefficients exceeding 1 m⁻¹ from sediment resuspension and algal blooms, contrasting sharply with the clarity of open pelagic zones where k values remain low, allowing deeper . These differences profoundly shape ecological zonation, though 's role in defining habitats is further explored elsewhere.

Temperature and Heat Transfer

The underwater environment exhibits distinct temperature profiles that vary with depth, , and season, profoundly influencing circulation patterns and ecological habitability. In most oceans, surface waters are warmed by solar radiation, typically ranging from 0°C in polar regions to over 30°C in the during peak seasons. Below the surface , which extends to about 100 meters in low latitudes, temperatures drop sharply in the —a transition zone where the vertical temperature gradient can reach approximately 1°C per 100 meters in tropical regions, creating a barrier to vertical mixing. Deeper waters, below 1,000 meters, remain uniformly cold at 0–4°C due to limited heat penetration and the sinking of dense, cold polar waters, maintaining near-constant conditions across vast abyssal plains. These profiles contribute to thermal stratification, where warmer, less dense water overlies colder, denser layers, stabilizing the and inhibiting vertical mixing except in regions of strong winds or . In oceans, this is largely permanent, with a persistent in subtropical and tropical zones that persists year-round, driven by consistent solar input and large-scale circulation. In contrast, many inland lakes experience seasonal overturn: during summer, surface heating establishes temporary , but cooling in autumn leads to mixing as denser surface water sinks, redistributing heat and nutrients before winter re-stratification or ice cover. Such dynamics in lakes, exemplified by dimictic systems like , can shift under climate warming, shortening mixing periods and altering deep-water temperatures. Heat transfer in underwater environments occurs primarily through conduction, , and limited , each governed by 's physical properties. Conduction, the molecular transfer of heat, follows Fourier's law, expressed as the heat flux q = -k \nabla T, where k is the thermal conductivity of (approximately 0.6 W/m·K at 25°C) and \nabla T is the ; this process is relatively slow in due to its high but dominates in stagnant, stratified layers. , driven by differences from temperature variations, facilitates large-scale heat transport via currents such as the , where warm surface waters flow equatorward and cold deep waters poleward, redistributing global heat. is minimal beyond the surface because 's opacity to wavelengths absorbs and within the upper few meters, preventing deep penetration and emphasizing the role of mixing in heat distribution. Extreme temperatures highlight the underwater environment's variability beyond typical profiles. Hydrothermal vents at mid-ocean ridges expel superheated fluids reaching up to 400°C, where prevents and supports unique chemosynthetic ecosystems despite the conditions. At the opposite end, polar regions under feature water temperatures around -2°C, near the freezing point of , where brine exclusion during ice formation concentrates salts and sustains under-ice habitats in near-freezing conditions. These extremes underscore how localized geological and climatic factors can override broader stratification patterns.

Sound Propagation and Acoustics

Sound propagation in the underwater environment differs significantly from that in air due to water's higher and elasticity, enabling sound waves to travel much farther and faster. The in is approximately 1500 m/s, compared to about 343 m/s in air at standard conditions./Book%3A_University_Physics_I_-Mechanics_Sound_Oscillations_and_Waves(OpenStax)/17%3A_Sound/17.03%3A_Speed_of_Sound) This higher results from water's greater relative to its , as described by the Newton-Laplace equation: c = \sqrt{\frac{K_s}{\rho}} where c is the speed of sound, K_s is the adiabatic bulk modulus, and \rho is the density of the medium./Book%3A_University_Physics_I_-Mechanics_Sound_Oscillations_and_Waves(OpenStax)/17%3A_Sound/17.03%3A_Speed_of_Sound) The speed varies with environmental factors, increasing by about 4.6 m/s per degree Celsius rise in temperature and by 1.3 m/s per practical salinity unit (‰) increase in salinity. Attenuation of in occurs primarily through and , limiting over distance. , dominated by chemical relaxation processes such as those involving at frequencies around 1 kHz, results in losses of approximately 0.001 to 0.1 dB/km at that frequency. arises from interactions with inhomogeneities like bubbles, particles, or biological scatterers, further reducing signal intensity. Despite these losses, certain features enhance long-range ; the SOFAR (Sound Fixing and Ranging) channel, a deep layer where speed reaches a minimum due to and temperature gradients, can trap and guide low-frequency sounds over thousands of kilometers. Acoustic phenomena in the underwater environment are influenced by the ocean's layered structure. bends rays toward regions of lower speed, such as colder waters, creating convergence zones that focus energy and extend detection ranges. , the formation of vapor bubbles under intense from high-amplitude , occurs above thresholds typically around 0.3 to 1 peak in degassed , generating that can interfere with . Marine animals exploit these properties for communication; for instance, songs reach source levels up to 185 dB re 1 μPa at 1 m, allowing transmission over hundreds of kilometers via low-frequency channels. Human technologies leverage for detection and navigation, particularly through systems. Active emits pulses and measures echoes, achieving detection ranges of several kilometers to tens of kilometers depending on and conditions, such as 20-30 miles in zones for low-frequency systems. Passive listens for ambient noises from targets like , offering potentially longer ranges—up to hundreds of kilometers for loud sources in the —without revealing the listener's position.

Chemical Properties

Salinity and Dissolved Gases

Salinity refers to the concentration of dissolved salts in , primarily measured in parts per thousand (‰). In the open ocean, the average salinity is approximately 35‰, with the major ions constituting the bulk of this : (Cl⁻) accounts for about 55% by weight, sodium (Na⁺) for around 30%, followed by sulfate (SO₄²⁻), magnesium (Mg²⁺), calcium (Ca²⁺), and potassium (K⁺), which together make up over 99% of the total salts. These ions remain in relatively constant proportions across the oceans due to conservative mixing, influencing osmotic regulation in organisms and contributing to density gradients. In contrast, freshwater bodies such as rivers and lakes typically have salinities below 0.5‰, creating sharp transitions in estuarine environments. A is a vertical zone of rapid increase with depth, often forming a barrier to vertical mixing and affecting the distribution of heat, nutrients, and oxygen in stratified waters. For instance, in polar regions like the , the halocline helps maintain a stable stratification that isolates warmer surface waters from colder deep layers, influencing formation and dynamics. Dissolved gases in underwater environments, such as oxygen (O₂), (CO₂), and (N₂), are governed by principles that vary with , , and pressure. The of O₂ decreases as and rise; for example, in at 20°C and 35‰ , saturation is approximately 7.2 mg/L, supporting aerobic in but becoming limiting in warmer, saltier conditions. CO₂ leads to the formation of upon dissolution, while N₂ can become supersaturated in turbulent freshwater rapids due to , potentially causing in fish. The equilibrium concentration of dissolved gases follows , expressed as C = k P, where C is the concentration in solution, P is the of the gas above the , and k is the temperature- and salinity-dependent . This explains how surface waters equilibrate with atmospheric gases, but subsurface processes like upwelling disrupt this balance by bringing nutrient-rich, low-O₂ waters from deeper layers to the surface, enhancing productivity while risking oxygen depletion. Spatial and temporal variations in dissolved gases often result in hypoxic zones, areas with O₂ below 2 mg/L that stress aquatic life; a prominent example is the annual dead zone, which exceeded 15,000 km² in 2024 due to nutrient-driven and respiration.

pH and Nutrient Cycles

The pH of open ocean waters typically ranges from 7.8 to 8.4, with a global surface average of approximately 8.1, due to the buffering effect of the - system that resists changes in acidity. This buffering involves species, primarily ions, which maintain stability despite inputs of . However, absorption of atmospheric CO₂ has driven , lowering average surface by about 0.1 units since pre-industrial times (from ~8.2 to ~8.1). Projections indicate a further decline of 0.3 to 0.4 units by 2100 under high-emission scenarios, potentially reducing the saturation states of minerals essential for shell-forming organisms. Nutrient cycles in underwater environments sustain primary through the and supply of elements like , , and silica. The involves biological fixation of atmospheric N₂ into bioavailable forms by diazotrophs, followed by , where is oxidized to by in oxygenated waters. cycles primarily through the release from sediments, where organic matter and reductive under low-oxygen conditions liberate back into the water column, supporting growth. Silica, crucial for formation, enters the cycle via inputs and is recycled through , with accounting for up to 40% of despite silica often limiting their blooms in surface waters. These cycles are stoichiometrically linked by the , which describes the approximate atomic composition of biomass as C:N:P = 106:16:1, guiding uptake and regeneration in balanced ecosystems. Excess nutrient inputs from anthropogenic sources, such as agricultural runoff, disrupt these cycles by causing , where elevated and levels fuel excessive algal growth. This leads to blooms that, upon decay, deplete oxygen and create hypoxic or anoxic zones, severely impacting aquatic life. On a global scale, natural processes deliver deep-water nutrients to sunlit surface layers, supporting roughly 50% of the world's marine fisheries productivity despite covering only about 1% of the ocean surface area.

Pollutants and Contaminants

pollutants and contaminants significantly alter the of underwater environments, introducing persistent synthetic substances that disrupt natural biogeochemical processes. These include plastics, , and hydrocarbons from oil spills, which enter aquatic systems through various pathways and accumulate over time, posing long-term risks to . Plastics represent a major class of marine contaminants, with an estimated 11 million metric tons entering the oceans annually from land-based sources such as mismanaged waste and coastal litter. , particles smaller than 5 mm, are particularly pervasive, with global estimates exceeding 170 trillion plastic particles afloat in seawater, derived from the breakdown of larger debris and direct emissions like microbeads from . These fragments adsorb other toxins, amplifying their environmental impact. , including mercury, contaminate underwater systems through industrial discharges and atmospheric emissions; mercury undergoes , concentrating up to thousands of times in top predators like via trophic transfer in food webs. Oil spills introduce hydrocarbons that form toxic plumes, as exemplified by the 2010 incident, which released approximately 4.9 million barrels of crude oil into the , creating subsurface dispersant-oil mixtures that persisted for months. The persistence of these contaminants varies by type but often spans decades, complicating remediation efforts. Polychlorinated biphenyls (PCBs), once widely used in industrial applications, exhibit half-lives in marine sediments ranging from several years to over 38 years for certain congeners, allowing them to bioaccumulate in benthic organisms and persist in coastal ecosystems. similarly endure indefinitely due to their , with pieces remaining in the or sediments for centuries without significant degradation. This longevity enables , where contaminants build up in organisms' tissues, and , where concentrations increase at higher trophic levels, altering underwater chemical dynamics. Primary pathways for these pollutants include terrestrial runoff from and agricultural areas, which carries plastics and metals via rivers and into coastal waters, and atmospheric deposition, where volatile compounds like mercury settle directly onto ocean surfaces or are scavenged by . Over 80% of originates from land-based activities through these routes, exacerbating contamination in enclosed or semi-enclosed underwater bodies. This influx has contributed to the expansion of hypoxic "dead zones," areas of low oxygen caused by pollutant-driven algal blooms; globally, the number of such zones has more than quadrupled since , linked to nutrient and contaminant loading. from runoff overlaps here, indirectly worsening chemical imbalances through . International efforts to mitigate these contaminants focus on regulatory frameworks like the International Convention for the Prevention of Pollution from Ships (), adopted in 1973 and modified by the 1978 Protocol, which sets standards for preventing operational and accidental discharges of oil, chemicals, and garbage from vessels into marine environments. MARPOL's annexes, ratified by over 150 countries, have reduced ship-sourced by mandating equipment like oil-water separators and prohibiting disposal at , though enforcement challenges persist in addressing land-based inputs. Ongoing global initiatives build on these to target broader sources, emphasizing source reduction and cleanup technologies. As of November 2025, negotiations for a global plastics treaty under the Environment Programme's Intergovernmental Negotiating Committee adjourned without consensus following the fifth session in August 2025, with further sessions anticipated.

Ecosystems and Biology

Zonation and Habitats

The underwater environment exhibits distinct vertical zonation, dividing the and seafloor into layers influenced by physical gradients such as depth, pressure, and light availability. The encompasses the open above the seafloor, extending from the surface to the deepest abyssal depths, where it supports floating and swimming adapted to varying conditions. In contrast, the refers to the seafloor itself, including sediments and substrates that host bottom-dwelling communities shaped by substrate type and nutrient availability. Shallow benthic habitats, such as coral reefs, typically occur from the surface to about 50 meters depth, where they form complex structures in warm, clear waters. forests, another key benthic feature, thrive in cooler temperate regions from roughly 5 to 45 meters, creating three-dimensional canopies that influence water flow and sediment stability. Deeper benthic areas include abyssal plains, vast flat expanses beyond 3,000 meters depth covering much of the global seafloor, characterized by low energy and fine sediments. Horizontally, the underwater environment is zoned from coastal margins to the open ocean, reflecting gradients in , , and exposure to terrestrial influences. The , overlying the continental shelf at depths less than 200 meters, represents the coastal horizontal division where nutrient-rich waters from land runoff support high . Seaward of this lies the oceanic , encompassing the vast open waters beyond the shelf break, with lower nutrient levels but extensive horizontal expanse. Estuaries serve as dynamic horizontal mixing zones at the land-sea interface, where freshwater and blend, creating unique gradients and sediment dynamics. Specific habitats illustrate these zonations, with transitions marking shifts in environmental conditions. meadows, found in shallow neritic benthic areas, act as significant carbon sinks, sequestering about 10% of the carbon buried in ocean sediments annually through sediment burial and . Mangroves occupy intertidal coastal zones, functioning as grounds by providing sheltered structures that stabilize sediments and buffer against waves. In the deep ocean, habitats like the represent extreme benthic features, plunging to approximately 11 kilometers depth and hosting communities under immense pressure. Key transitions include shelf breaks, sharp escarpments at the neritic-oceanic boundary around 200 meters where seafloor slope steepens dramatically, influencing currents and . Oxygen minimum zones, occurring between 200 and 1,000 meters in the pelagic realm, form mid-water layers of low dissolved oxygen due to , creating barriers to vertical migration.

Biodiversity and Adaptations

The underwater environment hosts an extraordinary diversity of , with estimates suggesting up to 2.2 million marine exist globally, of which less than 10% have been formally described and documented. Recent efforts, such as the Ocean Census project, have discovered over 800 new marine as of March 2025, highlighting the continued expansion of known . This vast undiscovered underscores the ocean's role as the planet's largest habitat, encompassing everything from microscopic to massive whales, with the majority of adapted to specific depth zones and conditions. Regional hotspots amplify this richness; for instance, the Coral Triangle in the region contains 76% of the world's known , supporting over 600 types and serving as a cradle for marine evolutionary innovation. Marine organisms exhibit remarkable physiological and evolutionary adaptations to the underwater realm's challenges, including extreme , low , and salinity variations. Deep-sea piezophiles, or barophiles, thrive under hydrostatic pressures exceeding 1,000 atmospheres through specialized pressure-resistant proteins that maintain structural and enzymatic , enabling growth in the abyssal zones where pressures would crush most surface life. In the dim , approximately 70% of species produce via symbiotic bacteria or intrinsic photophores, using this light for , predation, and communication in perpetual twilight. Cartilaginous fishes like sharks employ by retaining high levels of and trimethylamine oxide in their blood, achieving near-isosmotic balance with to minimize water loss and energy expenditure on ion . Extremophiles further exemplify adaptive extremes in underwater niches. Thermophilic polychaetes, such as the Pompeii worm (), inhabit hydrothermal vents where their posterior ends endure temperatures up to 80°C, protected by a layer and heat-shock proteins that stabilize cellular processes amid toxic sulfide-rich fluids. Conversely, psychrophiles dominate polar seas and deep cold waters, with enzymes featuring flexible structures and proteins that prevent formation, allowing metabolic activity at temperatures below -10°C and facilitating in frigid environments. These adaptations, however, face escalating threats from anthropogenic . Ocean warming and acidification are projected to severely impact biodiversity, with high risks to calcifying ; for example, coral reefs—home to about 25% of known —could see 70–90% loss under 1.5°C of warming, exacerbating habitat collapse and declines. Additionally, influences at least 41% of already threatened assessed by the IUCN, compounding vulnerabilities through altered distributions and reduced .

Food Webs and Trophic Levels

In marine ecosystems, food webs represent complex networks of energy transfer among organisms, structured around trophic levels that dictate the flow from primary producers to higher consumers. At the base, primary producers such as dominate, accounting for approximately 98% of marine autotrophic production through . These microscopic convert sunlight and nutrients into organic matter, forming the foundation that supports the entire underwater . Primary consumers, including like copepods and , graze on phytoplankton, while secondary and tertiary consumers—such as small fish, larger , and marine mammals—feed upward through the levels. Decomposers, primarily , break down dead organic material, recycling nutrients back into the system to sustain productivity. Energy transfer efficiency across trophic levels is notably low, with only about 10% of energy from one level passing to the next, as the remainder is lost primarily as heat through and metabolic processes—a known as the 10% rule. This inefficiency limits the number of trophic levels in most food webs to three or four, concentrating at lower levels and resulting in inverted biomass pyramids compared to terrestrial systems. food webs underpin global , with capture fisheries yielding around 90 million tonnes annually and providing at least 20% of animal protein for over 3 billion people worldwide. Key dynamics within these webs are influenced by , such as sea otters, which exert disproportionate control by preying on sea urchins and preventing overgrazing of , thereby maintaining and structural integrity in coastal ecosystems. Disruptions like jellyfish blooms can alter these dynamics, as outcompete fish for prey and shunt energy away from higher trophic levels, reducing transfer to commercially important species and causing "dead ends" in the . The , involving and , plays a crucial role in recycling, remineralizing about 55% of back into dissolved and nutrients, which supports sustained . Imbalances in marine food webs often arise from human activities, particularly , which has led to 35.5% of assessed global being fished at biologically unsustainable levels as of 2022, collapsing populations of top predators and cascading effects down to lower trophic levels. Such disruptions reduce overall resilience, diminish primary production utilization, and threaten the webs' capacity to support fisheries that feed billions.

Human Interactions

Exploration Methods

Human exploration of underwater environments has relied on techniques that allow individuals to access depths while managing physiological challenges such as pressure and gas exchange. Early advancements focused on enabling prolonged submersion without surface-supplied air hoses, revolutionizing access to marine realms. The Aqua-Lung, invented in 1943 by French naval officer Jacques-Yves Cousteau and engineer Émile Gagnan, marked a pivotal development as the first practical self-contained (), permitting divers to carry tanks and breathe freely at depth. This innovation shifted diving from tethered operations to mobile exploration, laying the foundation for recreational and scientific endeavors. Free diving, the breath-hold method without breathing apparatus, represents the simplest form of underwater access and pushes human physiological limits. Divers rely on lung capacity, relaxation techniques, and equalization to descend and ascend unaided, with records demonstrating exceptional adaptations to pressure and oxygen conservation. The current men's world record for constant weight freediving with bifins stands at 126 meters, achieved by in September 2025 during the AIDA Depth World Championships. Ambient pressure diving, where divers experience the surrounding water pressure directly, includes systems that supply compressed air or enriched mixtures on demand. Recreational is typically limited to a maximum depth of 40 meters to minimize risks like and , with certification agencies such as PADI and NAUI establishing standardized training that emphasizes buoyancy control, equipment handling, and emergency procedures for safe independent . , a mixture of and oxygen with reduced nitrogen content (often 32% oxygen), extends no-decompression limits and allows slightly deeper profiles within recreational bounds, such as a maximum operating depth of 34 meters for a 32% blend to avoid . Rebreathers enhance diving by recycling exhaled gas, offering advantages like reduced bubble noise for stealthy observation of and extended bottom times through efficient gas use. These closed-circuit systems employ a chemical absorbent, typically , to scrub from the breathing loop, preventing toxic buildup while electronically or manually adding oxygen as needed. For deeper operations, atmospheric diving maintains divers at surface pressure within sealed habitats or suits, with being the primary technique for extended work at significant depths. Divers "saturate" their tissues with inert gases over days or weeks, living in pressurized chambers and using diving bells for transfer to the worksite; breathing mixtures like (helium-oxygen) mitigate narcosis and enable depths up to approximately 500 meters, though most commercial applications occur between 100 and 300 meters. The U.S. Navy pioneered in the 1960s through projects like I in 1964, which tested human tolerance to prolonged exposure at 57 meters using in underwater habitats.

Technological Applications

Technological applications of underwater environments leverage advanced submersibles, remotely operated vehicles (ROVs), and autonomous underwater vehicles (AUVs) to enable exploration, resource extraction, and infrastructure maintenance without direct human presence. These platforms operate in extreme pressures and conditions, supporting scientific research, military operations, and commercial activities. Manned submersibles like the , operated by the (WHOI), allow pilots and scientists to reach depths of up to 6,500 meters for in-situ observations and sample collection during dives lasting 6-10 hours. In military contexts, nuclear-powered submarines such as the Virginia-class fast-attack vessels provide stealthy, long-endurance capabilities for surveillance and strike missions, with over 20 units commissioned by the U.S. Navy as of 2023. ROVs and AUVs extend operational reach through tethered and untethered designs equipped with sensors like for bathymetric mapping, high-definition cameras for , and manipulators for tasks. Tethered ROVs, such as the developed by the Ocean Exploration Trust, have been instrumental in high-profile expeditions, including detailed imaging and artifact recovery from the RMS wreck at 3,800 meters depth during the 2010 Return to Titanic mission. Autonomous AUVs like WHOI's operate independently to 6,000 meters, producing comprehensive seafloor maps using multibeam and sidescan systems while navigating complex terrains such as mid-ocean ridges and hydrothermal vents. These vehicles support diverse applications, including the inspection of oil where ROVs conduct the great majority of structural assessments to detect corrosion and leaks, enhancing safety in deepwater operations. Additionally, ROVs and AUVs facilitate the laying and maintenance of communication cables, which total over 1.48 million kilometers globally and carry 99% of . Recent advances have integrated for improved navigation, enabling AUVs to process real-time data for obstacle avoidance and path optimization in GPS-denied environments, as demonstrated in post-2020 developments like AI-enhanced inertial and acoustic systems. vehicles, such as the UK's Autosub Long Range (ALR) fleet including launched in 2016 by the National Oceanography Centre, combine gliding propulsion with autonomy to survey under-ice regions for extended periods, reaching depths of 944 meters and covering over 100 kilometers per mission to study ocean currents and ecosystems. These innovations prioritize efficiency and reduce operational costs, with AI-driven autonomy projected to expand AUV deployment in commercial sectors by 2030.

Hazards and Mitigation

The underwater environment poses significant physical hazards to human activities, primarily due to its dynamic and unforgiving nature. Strong currents, such as rip currents, can reach speeds of up to 5 miles per hour (approximately 4.3 knots), rapidly pulling swimmers away from shore and contributing to hundreds of drownings annually worldwide. Hypothermia is another critical risk, as water conducts heat away from the body approximately 25 times faster than air, leading to rapid core temperature drops even in relatively mild conditions; for instance, immersion in 50–60°F (10–15.5°C) water can induce severe hypothermia within 30–60 minutes without protective measures. Encounters with marine life further compound dangers, including jellyfish stings that affect an estimated 150 million people globally each year, causing localized pain, systemic reactions, and occasional fatalities or hospitalizations, particularly from species like box jellyfish. Shark attacks, while rare, result in about 5–6 unprovoked fatalities annually on average, often in coastal waters where human presence overlaps with shark habitats. Mitigation strategies emphasize education and preparation: swimmers should escape rip currents by swimming parallel to the shore rather than against them, while wetsuits and insulated gear prevent hypothermia by reducing conductive heat loss; for marine life, protective clothing like stinger suits and awareness of high-risk areas minimize encounters. Decompression sickness, commonly known as "the bends," arises during activities like scuba diving when rapid ascent from depth causes dissolved nitrogen gas to form bubbles in the bloodstream and tissues, leading to symptoms ranging from joint pain and fatigue to neurological impairment or paralysis. This condition affects divers who exceed safe ascent rates or skip decompression stops, with incidence rates varying from 0.01% to 2% per dive depending on depth and profile. Primary mitigation involves adherence to dive tables or computer algorithms that calculate safe ascent limits, including mandatory stops to allow nitrogen off-gassing; in cases of suspected DCS, immediate treatment with hyperbaric oxygen therapy recompresses the body to dissolve bubbles and restore oxygenation, often administered in specialized chambers with success rates exceeding 80% if initiated promptly. Environmental hazards in underwater settings include s and underwater landslides, which can generate massive waves and displace vast water volumes, threatening coastal populations and infrastructure. often originate from submarine landslides triggered by earthquakes, volcanic activity, or slope instability, displacing water to produce waves up to 100 feet (30 meters) high upon reaching shore. Mitigation relies on early warning systems, such as NOAA's Deep-ocean Assessment and Reporting of (DART) network, first operationally deployed in 2000 with expansion following the 2004 ; these seafloor pressure sensors detect wave propagation in real-time and relay data via buoys to forecast centers, enabling evacuations that have reduced fatalities in monitored regions by providing 1–3 hours of advance notice. Ecosystems face risks from human-induced , notably boat anchoring, which physically crushes sensitive structures like reefs and seagrasses, leading to and reduced resilience; studies in the indicate that high-anchoring sites experience approximately 41% less hard cover, along with up to 60% reductions in colony density, species , and structural complexity compared to low-anchoring sites. Regulatory measures, including marine protected areas (MPAs), address these threats by restricting activities in vulnerable zones; as of 2024, approximately 8.4% of global ocean and coastal areas are within protected or conserved regions, with an international commitment under the to expand coverage to at least 30% by 2030 through enhanced enforcement and habitat restoration. In MPAs, anchoring bans and systems preserve habitats, while broader strategies like speed limits and eco-certification programs further mitigate ecological damage.

Scientific Study

Oceanography and Hydrography

encompasses the scientific study of the 's physical, chemical, and geological properties and processes, while focuses on mapping and describing the and characteristics to support and . These disciplines provide foundational understanding of circulation, seafloor , and chemical distributions, essential for modeling and environmental changes. The field traces its origins to the HMS Challenger expedition of 1872–1876, the first global scientific voyage dedicated to , which collected data on , , currents, and deep-sea across over 127,000 kilometers of sailing, establishing benchmarks for systematic ocean sampling. This pioneering effort laid the groundwork for modern programs like GO-SHIP, initiated in 2007 by the Ocean Carbon Coordination and CLIVAR, which coordinates repeat hydrographic surveys along key transects to monitor long-term changes in ocean properties such as temperature, , and carbon content. These surveys repeat lines from earlier initiatives like the World Ocean Circulation Experiment in the 1990s, providing time-series data for detecting trends in ocean circulation and biogeochemistry. Oceanography is traditionally divided into branches that address abiotic processes. examines the dynamics of ocean currents, waves, and , driven by wind, density gradients, and , which transport and influence global patterns. Chemical oceanography investigates the ocean's composition, including dissolved gases, nutrients, and tracers like chlorofluorocarbons (CFCs), which reveal circulation pathways and rates of water mass mixing. , often termed , studies seafloor , sediment distribution, and plate boundaries, elucidating processes like and volcanic activity that shape the ocean basin. Key methods in these fields include the Argo program, which deploys nearly 4,000 autonomous profiling floats worldwide to measure and profiles from the surface to 2,000 meters depth every 10 days, enabling monitoring of and circulation. Complementing this, satellite altimetry measures sea surface height variations to infer subsurface currents and topography, with missions like achieving accuracies of 3.3 centimeters to track mesoscale eddies and global trends. Notable findings include the El Niño-Southern Oscillation (ENSO) cycles, which occur every 2–7 years and involve periodic warming of Pacific surface waters, disrupting global and precipitation patterns. In geological terms, mid-ocean ridges form an interconnected system spanning 65,000 kilometers, representing sites of where new emerges at divergent plate boundaries.

Marine Biology and Ecology

Marine biology encompasses the study of organisms in marine environments, while marine focuses on interactions among these organisms and their surroundings. These subfields integrate , which classifies marine species, and ecological principles, such as that model changes in species abundance through birth, death, immigration, and emigration rates. relies on systematic using the Linnaean to organize marine , aiding in and evolutionary understanding. in marine ecology employ mathematical models, like logistic growth equations, to predict how environmental factors influence species stability and fluctuations. A landmark effort in marine taxonomy was the Census of Marine Life (2000–2010), a global initiative involving over 2,700 scientists that documented approximately 230,000 known marine species and identified more than 5,600 new ones, highlighting the vast undescribed diversity in oceans. This program advanced subfield knowledge by integrating field surveys, genetic analyses, and databases like the (WoRMS), which as of 2025 catalogs approximately 247,000 valid marine species names validated by experts. Key tools in and include , which sequences a standardized region (typically ) to rapidly identify , and environmental DNA (eDNA) metabarcoding, which detects genetic material shed by organisms into water samples to assess without direct capture. has been applied to thousands of marine , refining taxonomic classifications and revealing cryptic diversity in groups like and . eDNA methods excel in elusive marine communities, such as deep-sea or microbial assemblages, by amplifying multiple taxa from a single sample and distinguishing habitat-specific signals with high resolution. Long-term ecological studies provide insights into and , exemplified by monitoring programs for forests, which support diverse . The Global Ocean Biodiversity Initiative (GOBI), an international partnership, facilitates such research by advancing data on coastal and deep-sea habitats, including kelp ecosystems, to inform strategies. For instance, satellite-based analyses of giant kelp along the North American over 35 years have quantified persistence and decline patterns, linking them to climate variability and protection efforts. Conservation in marine biology emphasizes threat assessment and response, with the IUCN Red List evaluating extinction risks for marine species. As of the 2025 update, the Red List includes over 172,600 species assessed overall, with more than 48,600 classified as threatened; for marine species, rates vary by taxon, with reef-building corals facing up to 44% at risk due to bleaching and habitat loss. The 2023–2025 global coral bleaching event, the fourth on record and the most widespread to date, has affected reefs in approximately 84% of the world's areas across 83 countries and territories as of March 2025, driven by record ocean heat and El Niño conditions, underscoring the urgency of ecological interventions. Advances in since 2010 have illuminated the roles of microbiomes in , revealing how microbial communities influence host physiology and ecosystem functions. High-throughput sequencing of uncultured microbes has uncovered novel symbiotic interactions, such as aiding resilience to stress or nitrogen fixation in , expanding understanding of trophic dependencies and support. These post-2010 developments, including whole-genome approaches, have integrated metagenomic data into ecological models, enhancing predictions of community responses to environmental changes.

Applied Underwater Sciences

Applied underwater sciences integrate knowledge from , , and to address practical challenges in resource extraction, environmental protection, and legal frameworks. In the fisheries industry, sustainable quotas are determined using (MSY) models, which estimate the highest catch level that maintains stock productivity over time without depleting populations. These models, rooted in , guide international agreements like those from the (FAO) to prevent while maximizing economic benefits. , a key application, supplied 51% of production in 2022, totaling 94.4 million tonnes and surpassing capture fisheries for the first time. This shift supports but requires site-specific hydrodynamic and ecological assessments to minimize impacts on wild stocks. In , underwater sciences inform the design and placement of farms, with cumulative installed reaching approximately 83 GW as of 2025, powering millions of households through surveys and current modeling. Forensic applications leverage acoustic and technologies for and recovery operations. In the , where anoxic conditions preserve ancient wrecks, projects like the Black Sea Maritime Archaeology Project (Black Sea MAP) have documented over 65 shipwrecks from the BCE to the using remotely operated vehicles (ROVs) and multibeam sonar, revealing insights into Byzantine and trade routes. Similarly, search and recovery efforts for Flight MH370 involved extensive underwater surveys covering 710,000 square kilometers in the southern , employing autonomous underwater vehicles (AUVs) and to map potential debris fields based on drift and acoustic data. These operations highlight the role of hydrodynamic modeling in predicting wreckage locations. Policy frameworks draw on underwater sciences to regulate resource use and mitigate climate effects. The Convention on the Law of the Sea (UNCLOS), adopted in 1982, establishes exclusive economic zones (EEZs) extending 200 nautical miles from coastal baselines, granting sovereign rights over marine resources while requiring environmental impact assessments. initiatives apply sequestration science to coastal ecosystems like mangroves and seagrasses, enabling carbon credit markets that incentivize restoration; the IUCN's policy framework outlines methodologies for verifying storage and integrating these into national climate strategies. Emerging fields expand these applications amid growing demands for minerals and . mining targets polymetallic nodules—potato-sized deposits rich in , , and —on abyssal plains, regulated by the () through exploration contracts and draft exploitation rules developed in the 2020s to balance resource access with protection. In climate adaptation, underwater sciences inform projections of , with IPCC assessments estimating 0.3 to 1 meter by 2100 under low-to-medium emissions scenarios, guiding coastal infrastructure designs and habitat relocation strategies.

References

  1. [1]
    Underwater Environment - an overview | ScienceDirect Topics
    The underwater environment is defined as the entire observable area inside a natural or artificial water source, such as oceans, seas, lakes, and rivers, ...
  2. [2]
    How much of the ocean has been explored? - NOAA Ocean Exploration
    ### Summary of Underwater Ocean Environment Characteristics
  3. [3]
    Layers of the Ocean - NOAA
    Mar 28, 2023 · Epipelagic Zone This surface layer is also called the sunlight zone and extends from the surface to 200 meters (660 feet).Missing: penetration | Show results with:penetration
  4. [4]
    Sea Water | National Oceanic and Atmospheric Administration
    Mar 28, 2023 · The density of sea water, however, is influenced by both its temperature and salinity. Density increases as salinity increases and as ...
  5. [5]
    Marine Ecosystems - National Geographic Education
    Jan 21, 2025 · Marine ecosystems are aquatic environments with high levels of dissolved salt. These include the open ocean, the deep-sea ocean, and coastal marine ecosystems.
  6. [6]
    Our Blue Frontier: Exploring Our Ocean World
    May 30, 2023 · The water column of the open ocean is divided into five zones from the surface to the seafloor. Each zone varies in pressure, light, temperature ...
  7. [7]
    The Ocean | National Oceanic and Atmospheric Administration
    Jul 28, 2023 · The ocean covers 71% of Earth, holds 97% of water, and its heat affects weather. More than half of the world's population lives near it.Wind and Sea Scales · Layers of the Ocean · Sea Water · Rip Currents
  8. [8]
    How much water is in the ocean? - NOAA's National Ocean Service
    Jun 16, 2024 · About 97% of Earth's water is in the ocean, which is 1,335,000,000 cubic kilometers (321,003,271 cubic miles).
  9. [9]
    Ocean and coasts | National Oceanic and Atmospheric Administration
    Dec 16, 2024 · The United States recognizes five named ocean basins: Arctic, Atlantic, Indian, Pacific, and Southern. The ocean and large inland lakes play an integral role ...Missing: principal | Show results with:principal
  10. [10]
    Thermohaline Circulation - Currents - NOAA's National Ocean Service
    Thermohaline circulation begins in the Earth's polar regions. When ocean water in these areas gets very cold, sea ice forms. The surrounding seawater gets ...
  11. [11]
    Ocean Circulations | National Oceanic and Atmospheric Administration
    Mar 28, 2023 · Also called the thermohaline circulation, it is driven by differences in the density of the sea water which is controlled by temperature ( ...
  12. [12]
    Science of the Mediterranean Sea and its applications
    The Mediterranean Sea is a semi-enclosed extension of Atlantic Ocean. Because of its negative water budget, it imports low nutrient, surface Atlantic Water ...
  13. [13]
    Enclosed or Semi-Enclosed Seas - Oxford Public International Law
    Therefore, for example, the Caribbean Sea, having a multitude of outlets connecting it to the Atlantic Ocean, is an 'enclosed or semi-enclosed sea', as is the ...
  14. [14]
    A functional definition to distinguish ponds from lakes and wetlands
    Jun 21, 2022 · Ponds are small and shallow waterbodies with a maximum surface area of 5 ha, a maximum depth of 5 m, and < 30% coverage of emergent vegetation.Introduction · A Functional Pond Definition · Methods
  15. [15]
    The diversity of pool-riffle morphologies - ScienceDirect.com
    Nov 1, 2023 · Many gravel-bed rivers are characterized by an undulating bed morphology, with the deeper areas called pools and the shallower areas called ...
  16. [16]
    Classification and Types of Wetlands | US EPA
    Feb 5, 2025 · The Cowardin system includes five major wetland types: marine, estuarine, lacustrine, palustrine and riverine.
  17. [17]
    The Hydrologic Cycle and Interactions of Ground Water and Surface ...
    Precipitation, which is the source of virtually all freshwater in the hydrologic cycle, falls nearly everywhere, but its distribution is highly variable.
  18. [18]
    [PDF] lake-stratification.pdf - Illinois Environmental Protection Agency
    As dis- cussed above, a warm surface layer (the epilimnion) "floats" on a colder layer (the hypolimnion). Different fish species prefer different water ...
  19. [19]
    Great Artesian Basin | Geoscience Australia
    Dec 10, 2021 · Covering more than 1.7 million square kilometres, the GAB underlies parts of Queensland, New South Wales, South Australia and the Northern ...Missing: km2 source
  20. [20]
    Anchialine pools and cenotes - microbewiki - Kenyon College
    Apr 21, 2011 · They contain very clear water and large channels. The anchialine pools of the Yucatan Peninsula in Mexico are the only known underground aquatic ...
  21. [21]
    Caves Cenotes Geology Hydrology Speleogenesis Speleology
    May 9, 2025 · Cave and cenote systems are subject to mechanical destruction by explosives or machinery, as occurs in many sites adapted for “rafting” in ...
  22. [22]
    [PDF] To Make a Cave - Into The Outdoors
    Anchialine caves are partially or totally submerged caves in coastal areas. Anchialine (pronounced “AN-key-ah-lin”) is a Greek term meaning “near the sea,” and ...
  23. [23]
    What is a hydrothermal vent? - NOAA's National Ocean Service
    Jun 16, 2024 · “Black smokers” are chimneys formed from deposits of iron sulfide, which is black. “White smokers” are chimneys formed from deposits of ...Missing: mid- | Show results with:mid-
  24. [24]
    The Discovery of Hydrothermal Vents
    Jun 11, 2018 · Hydrothermal vents form in volcanic areas where subseafloor chambers of rising magma create undersea mountain ranges known as mid-ocean ridges.
  25. [25]
    Drastic change in China's lakes and reservoirs over the past decades
    Aug 13, 2014 · The Three Gorges Reservoir (TGR) with a total capacity of 39.3 km3, the world's largest hydropower project, began to impound water in June 2003 ...
  26. [26]
    Fish culture in undrainable ponds
    This manual covers freshwater fish culture in undrainable ponds, including pond characteristics, composite carp culture, pond management, and suitable species.
  27. [27]
    [PDF] Creating Lakes from Open Pit Mines: Processes and Considerations ...
    A good example is the Island Copper pit lake of Vancouver Island, B.C., which was flooded to > 90% volume with ocean water, and then capped with a fresh surface ...
  28. [28]
    About FIU Aquarius - FIU Institute of Environment
    Oct 10, 2025 · FIU Aquarius Reef Base allows marine scientists to leave the terrestrial world behind and live among their research subjects for days, even ...
  29. [29]
    [PDF] Measuring methods for groundwater – surface water interactions
    Groundwater temperatures are rel- atively stable throughout the year. In contrast, stream temper- atures vary strongly on a daily and seasonal basis. Therefore,.<|control11|><|separator|>
  30. [30]
    Groundwater - The Physical Environment
    Average ground water flow rate of 15 m per day is common. Highly permeable materials like gravels can have flow velocities of 125 m per day. ground water ...
  31. [31]
    Karst groundwater vulnerability determined by modeled age and ...
    Sep 14, 2023 · Shallow and unconfined parts are more vulnerable to land-surface contamination than the deeper and confined parts, although even the oldest ...
  32. [32]
    [PDF] Potential Environmental Impacts of Quarrying Stone in Karst
    The risk of ground-water pollution may increase if the direction of ground- water flow is modified. New source areas of recharge may be introduced, and.
  33. [33]
    6.2 Temperature – Introduction to Oceanography
    Generally ocean temperatures range from about -2 o to 30 o C (28-86 o F). The warmest water tends to be surface water in low latitude regions.
  34. [34]
    https://pubs.usgs.gov/of/2001/ofr-01-0484/ofr-01-0484po.pdf
  35. [35]
    How does the temperature of ocean water vary?
    Mar 5, 2013 · Therefore, the deep ocean (below about 200 meters depth) is cold, with an average temperature of only 4°C (39°F). Cold water is also more dense, ...
  36. [36]
    Conduction, Convection, and Radiation
    Convection contributes, with radiation and conduction, to the movement of heat in the vertical direction. But advection is essentially the sole process by which ...Missing: mechanisms | Show results with:mechanisms
  37. [37]
    Seasonal overturn and stratification changes drive deep-water ...
    Relationships from the data show a shortened winter season results in higher subsurface temperatures and earlier onset of summer stratification.Missing: permanent | Show results with:permanent
  38. [38]
    Seasonal overturn and stratification changes drive deep-water ...
    Mar 16, 2021 · Here we show how seasonal changes in the timing of overturn and stratification link surface warming trends to deep water temperatures in a ...Missing: permanent | Show results with:permanent
  39. [39]
    Thermophysical properties of seawater - MIT
    This page provides tables and a library of computational routines for the thermophysical properties of seawater.
  40. [40]
    [PDF] Factsheet: Hydrothermal Vents - NOAA Ocean Exploration
    The water rising out of the vents may reach temperature higher than 400°C (750° F), but high pressure in the deep ocean prevents the water from boiling. As ...
  41. [41]
    Five things to understand about an “ice-free” Arctic - Climate
    May 14, 2024 · Sea surface temperatures in the Arctic Ocean, however, hover near the freezing point of saltwater, which is slightly lower than the freezing ...
  42. [42]
    Speed of sound in water: what it is and how it's measured
    In the oceans, the speed of sound varies between 1450m/s and 1570m/s. It increases by approximately 1.3m/s per 1PSU increase in salinity, 4.5m/s per 1°C ...
  43. [43]
    Tutorial: Speed of Sound - Discovery of Sound in the Sea
    Feb 11, 2022 · Salinity has a much smaller effect on sound speed than temperature or pressure at most locations in the ocean. This is because the effect of ...
  44. [44]
    Calculation of absorption of sound in seawater
    The absorption of sound in seawater forms part of the total transmission loss of sound from a source to a receiver. It depends on the seawater properties, ...
  45. [45]
    Underwater sound | McGraw Hill's AccessScience
    This is called chemical relaxation. At about 65 kHz magnesium sulfate dominates absorption, and boric acid is important near 1 kHz. Absorption has been measured ...<|separator|>
  46. [46]
    Sound Scattering Layers - Discovery of Sound in the Sea
    Oct 2, 2023 · Scattering occurs when an underwater sound strikes inhomogeneities, such as the uneven seafloor, sea surface, and objects in the water column.
  47. [47]
    What is SOFAR? - NOAA's National Ocean Service
    Jun 16, 2024 · SOFAR, or Sound Fixing and Ranging Channel, is a naturally-occurring ocean “channel” that allows sound to carry great distances.
  48. [48]
    How far does sound travel in the ocean?
    Jun 16, 2024 · The area in the ocean where sound waves refract up and down is known as the "sound channel." The channeling of sound waves allows sound to ...
  49. [49]
    A general description of the cavitation threshold in acoustic systems
    Jan 7, 2025 · Traditionally, the cavitation threshold is defined by some combination of vapor pressure and surface tension.INTRODUCTION · Estimation of the acoustic... · Application the acoustic...
  50. [50]
    Source levels of humpback whales decrease with frequency ...
    Feb 19, 2019 · Source levels varied from 138 to 187 dB re 1 μPa at 1 m (root mean squared), while peak frequency ranged between 52 and 3877 Hz. Much of the ...
  51. [51]
    Sonar 101 | Proceedings - November 2024 Vol. 150/11/1,461
    Sonar, or 'sound navigation and ranging,' uses sound waves to detect objects underwater. There are two types: active and passive.Sonar 101 · Acoustic Propagation · Propagation Paths<|control11|><|separator|>
  52. [52]
    Detection Threshold for Sonar - Discovery of Sound in the Sea
    Mar 29, 2024 · Passive sonar systems listen to underwater sounds to detect signals of interest, such as those generated by animals, volcanoes, submarines, ...
  53. [53]
    [PDF] Chemical composition of seawater; Salinity and the major constituents
    Major ions in seawater include Cl-, Na+, Mg2+, SO4, Ca2+, and K+. Salinity is the amount of dissolved solids, with standard mean ocean water at about 35.
  54. [54]
    [PDF] pH, Salinity and Temperature - UF/IFAS Extension
    Fresh water has a salinity of 0.5 ppt or less. Estuaries can have ... The average salinity of ocean water is 35 ppt. Plants and animals are often ...
  55. [55]
    [PDF] Water masses and thermohaline structure
    ... environmental change, including ocean warming, ocean acidification and pollutant loading. ... homogeneous surface water, near-surface halocline, and the core of ...
  56. [56]
    Oxygen - Solubility in Fresh and Sea Water vs. Temperature
    The salinity of seawater in oceans ranges 30 to 50 parts per thousand (30,000 - 50,000 ppm), on average 35 ppt. 35 g dissolved salt / kg sea water = 35 ppt = 35 ...
  57. [57]
    [PDF] Gas Supersaturation in Fisheries: Causes, Concerns, and Cures,
    An increase in water temperature can also cause nitro- gen supersaturation, even if the water is at air equi- librium—that is, 100% saturated with nitrogen— ...
  58. [58]
    [PDF] Dissolved Gases other than Carbon Dioxide in Seawater
    Feb 18, 2016 · gas concentrations. 3. Use Henry's Law to explain the equilibrium of gases between the ocean and the atmosphere. 4. Use Weiss' equation to ...
  59. [59]
    Hypoxic Area off Pacific Northwest Coast has Grown Since 1950s
    Apr 24, 2024 · Upwelling pulls nutrient-rich deep water into shallower areas. Nutrients from the upwelled water promote phytoplankton growth, which indirectly ...
  60. [60]
    Above Average Summer 2024 'Dead Zone' Measured in Gulf of Mexico
    Aug 1, 2024 · In June 2024, NOAA forecasted a above-average sized hypoxic zone of 5,827 square miles (the record of 8,776 square miles was set in 2017). While ...
  61. [61]
    [PDF] Part 1: Seawater carbonate chemistry - NOAA/PMEL
    Seawater is a dilute solution of sodium bicarbonate, with bicarbonate, carbonate, and unionized carbon dioxide. It is buffered with respect to hydrogen ion.
  62. [62]
    Ocean acidification | National Oceanic and Atmospheric Administration
    Sep 25, 2025 · The ocean's average pH is now around 8.1 , which is basic (or alkaline), but as the ocean continues to absorb more CO2, the pH decreases and ...Missing: open | Show results with:open
  63. [63]
    Endangerment and Cause or Contribute Findings for Greenhouse ...
    Ocean CO2 uptake has lowered the average ocean pH (increased acidity) level by approximately 0.1 since 1750. Consequences for marine ecosystems may include ...
  64. [64]
    Fluctuating seawater pH/pCO2 regimes are more energetically ... - NIH
    Oct 18, 2017 · The accompanying absorption of atmospheric CO2 by the oceans has led to a 30% increase in average global ocean pH (reduction of pH by 0.1 units) ...
  65. [65]
    [PDF] Ocean, Coastal, and Great Lakes Acidification Research Plan: 2020 ...
    Continued acidification over the coming century will result in a further decline of 0.3-0.4 pH units in the global surface ocean by the year 2100 if CO2 emis-.
  66. [66]
    Changing perspectives in marine nitrogen fixation - Science
    May 15, 2020 · Atmospheric dinitrogen gas (N2) is abundant but must be fixed by reduction to ammonia, a process limited to certain organisms and environments.
  67. [67]
    Stability of the marine nitrogen cycle over the past 165 million years
    Oct 9, 2025 · Where intense ocean upwelling creates high productivity, such as those in the eastern Pacific, along the Benguela or seasonally off the ...
  68. [68]
    Enhanced silica export in a future ocean triggers global diatom decline
    May 25, 2022 · Diatoms account for up to 40% of marine primary production and require silicic acid to grow and build their opal shell.
  69. [69]
    Evolution of the global phosphorus cycle - CalTech GPS
    Jan 19, 2017 · In the original CANOPS model (and in most other large- scale biogeochemical models) the canonical Redfield ratio of C:N:P = 106:16:1 is used ...
  70. [70]
    What is eutrophication? - NOAA's National Ocean Service
    Jun 16, 2024 · Harmful algal blooms, dead zones, and fish kills are the results of a process called eutrophication—which begins with the increased load of ...
  71. [71]
    The Effects: Dead Zones and Harmful Algal Blooms | US EPA
    Feb 5, 2025 · Excess nitrogen and phosphorus can cause algae blooms. The overgrowth of algae consumes oxygen and blocks sunlight from underwater plants.
  72. [72]
    What is upwelling? - NOAA Ocean Exploration
    Although coastal upwelling regions account for only one percent of the ocean surface, they contribute roughly 50 percent of the world's fisheries landings.
  73. [73]
    Chapter: 4 Physical Transport and Pathways to the Ocean
    Major paths of plastics to the ocean are summarized in Figure 4.1. These include urban, coastal, and inland stormwater outfalls; treated wastewater discharges; ...
  74. [74]
    Plastic Pollution - United States Department of State
    An estimated 11 million metric tons of plastic enters the ocean each year. Often stemming from poor waste management, plastic pollution is a major environmental ...
  75. [75]
    Plastic Pollution in the World's Oceans: More than 5 Trillion Plastic ...
    Dec 10, 2014 · Based on our model results, we estimate that at least 5.25 trillion plastic particles weighing 268,940 tons are currently floating at sea (Table ...
  76. [76]
    Study Illuminates Previously Unknown Ocean Mercury Pathway
    Jun 7, 2024 · Through a process known as biomagnification, marine predators such as tuna, swordfish, sharks and dolphins can contain monomethylmercury levels ...
  77. [77]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC4262196/
  78. [78]
    [PDF] Science Support for Evaluating Natural Recovery of Polychlorinated ...
    Once released into the environment, PCBs are remarkably persistent; some congeners have half-life times of more than 38 years (Sinkkonen and Paasivirta, 2000). ...
  79. [79]
    [PDF] ATSDR Polychlorinated Biphenyls (PCBs) Tox Profile
    ... ENVIRONMENT ... Half-lives (Years) of PCB Congeners from Multiple Studies . . . . . . . . . . . . . . . . . . . . 326. 3-10. Apparent Half-lives (Years) of ...
  80. [80]
    Human Health and Ocean Pollution | Annals of Global Health
    Dec 3, 2020 · An increase in HAB frequency has been observed downstream of the massive Three Gorges Dam in China, and this increase is linked to a decrease in ...
  81. [81]
    Coastal phytoplankton blooms expand and intensify in the 21st century
    Mar 6, 2023 · The total global bloom-affected area has expanded by 3.97 million km2 (13.2%) between 2003 and 2020, equivalent to 0.14 million km2 yr−1 (P < ...
  82. [82]
    About IMO Conventions: MARPOL - Pollution Prevention
    MARPOL is the main international convention covering prevention of pollution of the marine environment by ships from operational or accidental causes.
  83. [83]
    The marine biome - University of California Museum of Paleontology
    The benthic zone is the area below the pelagic zone, but does not include the very deepest parts of the ocean (see abyssal zone below). The bottom of the ...
  84. [84]
    [PDF] Activity: Pelagic Zones - Where To Live in the Ocean
    The two major zones of the ocean are the sea floor, or bottom region, called the benthic realm and the watery region above the sea floor called the pelagic ...<|separator|>
  85. [85]
    [PDF] Effects of Sea Level on Reef Habitats of ... - SOEST Hawaii
    building coral species, Porites lobata, is utilized to delineate the PRE from the. MCE. 50m is shown to be the depth where a significant shift in coral cover.
  86. [86]
    [PDF] distribution and abundance of deep water macroalgae in
    My data indicate that Pleurophycus gardneri is one of the most abundant stipitate kelps from 30 to 45 m in central California, forming deep water subsurface ...
  87. [87]
    Abyssal Zone - Woods Hole Oceanographic Institution
    The abyssal zone, or the abyss, is the seafloor and water column from 3000 to 6500 meters (9842 to 21325 feet) depth, where sunlight doesn't penetrate.Missing: >3000m | Show results with:>3000m
  88. [88]
    [PDF] Coastal and Marine Systems of North America
    Neritic regimes extend from 30 m to the continental shelf break, whose average depth is at approximately the 200 m isobath, although this boundary can vary by ...
  89. [89]
    https://scholarworks.calstate.edu/downloads/6d570225s
  90. [90]
    Join us to celebrate World Seagrass Day!
    Feb 27, 2025 · Moreover, they are highly efficient carbon sinks, storing up to 18% of the world's oceanic carbon (UNEP, 2020). This ability to absorb and store ...
  91. [91]
    Mangrove Forest - Florida Keys National Marine Sanctuary - NOAA
    Many commercially and recreationally important reef fish and invertebrates use mangroves as a nursery habitat, finding refuge in their tangled roots. small ...
  92. [92]
    Bizarre jellyfish is spotted in the depths of the Mariana Trench...May ...
    It's one of the most hostile places on Earth and extends seven miles (11km) below the waves at its deepest point, but the Mariana Trench is full of secrets.
  93. [93]
    Coastal Zones: The Margins of Continents - SERC (Carleton)
    The continental shelves of the world transition into the continental slopes at the shelf break where a distinct change in the gradient or slope of the seafloor ...
  94. [94]
    [PDF] OXYGEN MINIMUM ZONE BENTHOS: ADAPTATION AND ...
    These seafloor oxygen minimum zones (OMZs) typically occur at bathyal depths between 200m and 1000m, and are major sites of carbon burial along the continental ...
  95. [95]
    The Ocean Census Mission | Discover Ocean Life
    Up to an estimated 2.2 million marine species exist; we've documented less than 10%. 13 years. It takes an average of 13 years to identify and formally ...Founded By · Our Mission · The Ocean Census Mission Is...<|separator|>
  96. [96]
    Coral Triangle facts | WWF - Panda.org
    Coral Triangle biodiversity. 76% (605) of the world's coral species (798) are found in the Coral Triangle, the highest coral diversity in the world.
  97. [97]
    Marine Extremophiles: A Source of Hydrolases for Biotechnological ...
    Microorganisms called piezophiles (previously named barophile), such as deep-sea bacteria or archaea, live in high pressure environments and are of interest to ...
  98. [98]
    Quantification of bioluminescence from the surface to the deep sea ...
    Apr 4, 2017 · Indeed, the earliest studies estimate that bioluminescence occurs in approximately 70% of fish species, and by number of individuals, 90% of ...
  99. [99]
    Living with high concentrations of urea: They can!
    Marine elasmobranchs retain large amount of urea in order to maintain body fluids isoosmotic or slightly iperosmotic to the surrounding seawater.
  100. [100]
    Pompeii worm - MBARI
    Pompeii worms build their tubes directly on the rocky vent chimneys. The base of these dwellings can experience temperatures up to 105 degrees Celsius (221 ...
  101. [101]
    Chapter 3: Oceans and Coastal Ecosystems and their Services
    Ocean acidification poses a large risk for coralline algae that is further amplified by warming (medium confidence) (Section 3.4.2.2; Cornwall et al., 2019).
  102. [102]
    IUCN Red List: Human activity devastating marine species from ...
    Dec 9, 2022 · Over 1,550 of the 17,903 marine animals and plants assessed are at risk of extinction, with climate change impacting at least 41% of threatened ...
  103. [103]
    Aquatic food webs | National Oceanic and Atmospheric Administration
    including bacteria, phytoplankton, and algae — form the lowest trophic level and the base of the aquatic food web. Primary ...
  104. [104]
    Energy Transfer in Ecosystems - National Geographic Education
    Jan 22, 2024 · At each step up the food chain, only 10% of the energy is passed on to the next level, while approximately 90% of the energy is lost as heat.
  105. [105]
    https://www.ipcc.ch/report/ar6/wg2/chapter/chapter-3/
  106. [106]
    [PDF] What makes the sea otter a keystone species?
    Sep 7, 2012 · By preying on sea urchins, a voracious consumer of kelp, sea otters keep urchin populations in check, which allows kelp forests to thrive (Estes ...
  107. [107]
    Jellyfish blooms result in a major microbial respiratory sink of carbon ...
    Jun 6, 2011 · Voracious jellyfish predation impacts food webs by converting large quantities of carbon (C), fixed by primary producers and consumed by ...<|separator|>
  108. [108]
    Organic matter composition and heterotrophic bacterial activity at ...
    Nov 6, 2020 · Bacteria in seawater were highly responsive to fresh organic matter and remineralized on average 55% of primary production in the upper mixed ...
  109. [109]
    The status of fishery resources
    Based on FAO's assessment, the fraction of fishery stocks within biologically sustainable levels decreased to 64.6 percent in 2019, that is 1.2 percent ...
  110. [110]
    The Aqua-Lung - The Cousteau Society
    The Aqua-Lung didn't just change how we dive, it opened the ocean to the world. Co-invented in 1943 by legendary ocean explorer Jacques-Yves Cousteau and ...
  111. [111]
    AIDA 2025 Depth World Championships Day 4: Alexey Molchanov ...
    Sep 27, 2025 · Alouach successfully dove to 111m/364ft and performed a very quick surface protocol. While the on-water judgment of the surface protocol ended ...
  112. [112]
    What Is Nitrox? - PADI Blog
    Jun 18, 2024 · ... a maximum depth of 34 meters/112 feet. By contrast, if on air, the maximum recreational depth limit is 40 meters/130 feet. Oxygen toxicity ...Why Do Divers Use Nitrox... · How Deep Can You Dive On... · What Are The Benefits Of...<|separator|>
  113. [113]
    PADI vs. SSI vs. NAUI [a 2025 Update] What's the best for you?
    Aug 19, 2024 · It is the NAUI Scuba Diver rank that grants the holder the minimum privileges to dive independently or without supervision around the world.
  114. [114]
    The CO2 Scrubber in a Diver's Rebreather - Shearwater Research
    Jun 26, 2017 · The common way to remove CO2 from a diver's rebreather is by chemical absorption (“scrubbing”). Most modern commercial absorbents consist of a ...
  115. [115]
    Saturation Diving - Divers Alert Network
    Aug 1, 2017 · Below 500 feet, heliox can cause high-pressure nervous syndrome (HPNS), which is characterized by tremors. To combat this, a small amount of ...
  116. [116]
    Capabilities - National Deep Submergence Facility
    Alvin is capable of the following: Operating at any depth from the surface to 6,500 meters (21,325 ft.) at speeds of 0-3.4 km/h (0-2.0 knots), and remaining ...
  117. [117]
    USS Virginia (SSN 774) - Commander, Submarine Force Atlantic
    The Virginia-class, also known as the VA-class or 774-class, is a class of nuclear-powered fast attack submarines in service with the U.S. Navy. The ...
  118. [118]
    Journey to Titanic: ROV Hercules & the "Oiling the Tiki" Tradition
    Sep 1, 2015 · It isn't widely known that both the ROV Hercules and the ROV Argus on board E/V Nautilus have explored the wreck of the Titanic, most notably ...
  119. [119]
    AUV Sentry - National Deep Submergence Facility
    The autonomous underwater vehicle (AUV) Sentry is a programmable, flexible platform capable of exploring the ocean and seafloor down to 6000 meters depth.
  120. [120]
    Comparison of methods (ROV, diver) used to estimate the ...
    Jan 1, 2023 · The great majority of underwater observation at offshore oil platforms is from industry ROVs used for structural inspection, control, and ...Missing: statistics | Show results with:statistics
  121. [121]
    Submarine Cable FAQs - TeleGeography
    How many kilometers of cable are there? As of early 2025, we believe there are over 1.48 million kilometers of submarine cables in service globally. Some cables ...
  122. [122]
    The state of the art in key technologies for autonomous underwater ...
    Aug 7, 2025 · This paper reviews the current state-of-the-art developments in key AUV technologies, focusing on advancements in overall design, power systems, ...Missing: post- | Show results with:post-
  123. [123]
    Boaty McBoatface - National Oceanography Centre
    I'm Boaty McBoatface, an autonomous underwater vehicle. I can travel on my own for miles under water and ice, at great depths, undertaking scientific research.
  124. [124]
    Rip Currents | National Oceanic and Atmospheric Administration
    Sep 19, 2024 · Rip current speeds are typically 1-2 feet per second, but speeds as high as 8 feet per second have been measured. That is faster than an ...
  125. [125]
    Hypothermia and Cold Weather Injuries - Seo Title
    Water conducts heat away from the body 25 times faster than air because it has a greater density (therefore a greater heat capacity). Stay dry = stay alive!
  126. [126]
    Jellyfish Stings: A Review of Skin Symptoms, Pathophysiology ... - NIH
    The estimated number of jellyfish sting incidents per year is approximately 150 million, with fatalities and hospitalizations occurring annually, particularly ...
  127. [127]
    International Shark Attack File - Florida Museum of Natural History
    The International Shark Attack File (ISAF) is the world's only scientifically documented, comprehensive database of all known shark attacks.Yearly Worldwide Shark Attack... · Maps & Data · Report a Shark Attack · Dog AttackMissing: per | Show results with:per
  128. [128]
    Scuba Diving: Decompression Illness and Other Dive-Related Injuries
    Apr 23, 2025 · Decompression sickness ("the bends"). Breathing air under pressure causes excess inert gas (usually nitrogen) to dissolve in and saturate body ...Preparing For Dive Travel · Diving Disorders · Barotrauma
  129. [129]
    Decompression Sickness - StatPearls - NCBI Bookshelf
    Dec 13, 2023 · Decompression sickness (DCS) is a potentially life-threatening condition that occurs when dissolved gases (commonly nitrogen) form bubbles in the bloodstream ...
  130. [130]
    Tsunami Generation: Landslides - NOAA
    Sep 27, 2023 · Tsunamis can be generated when a landslide displaces the water from above (subaerial) or below (submarine).
  131. [131]
    JetStream Max: Deep-ocean Assessment and Reporting of Tsunami
    Jun 12, 2023 · DART systems are designed to sense pressure changes at the bottom of the ocean caused by passing tsunamis and to communicate these changes to the tsunami ...
  132. [132]
    Boat anchoring contributes substantially to coral reef degradation in ...
    May 23, 2019 · Roughly 24% of BVI coral reef by area appears suitable for anchoring, suggesting that impacts associated with boat anchoring may be both locally ...
  133. [133]
    World must act faster to protect 30% of the planet: protected ... - IUCN
    Oct 28, 2024 · The Protected Planet Report 2024 reveals that 17.6% of land and inland waters and 8.4% of the ocean and coastal areas globally are within documented protected ...
  134. [134]
    2030 Targets (with Guidance Notes)
    Ensure that by 2030 at least 30 per cent of areas of degraded terrestrial, inland water, and marine and coastal ecosystems are under effective restoration, in ...
  135. [135]
    What is Oceanography? | Texas A&M University College of Arts and ...
    Traditionally, we discuss oceanography in terms of four separate but related branches: physical oceanography, chemical oceanography, biological oceanography ...
  136. [136]
    History: Timeline: NOAA Office of Ocean Exploration and Research
    1872-1876. The Challenger Expedition circumnavigates the globe in the first great oceanographic expedition. Research is conducted on salinity, density, and ...
  137. [137]
    About - GO-SHIP
    The GO-SHIP Panel was established in 2007 by the IOCCP and CLIVAR to develop a strategy for a sustained global repeat hydrography program as a contribution to ...
  138. [138]
    [PDF] Ship-based Repeat Hydrography: A Strategy for a Sustained Global ...
    The Panel is tasked to develop guidelines and a general strategy for the development of a globally coordinated network of sustained ship-based hydrographic ...
  139. [139]
    Ocean currents | National Oceanic and Atmospheric Administration
    Sep 25, 2025 · Differences in water density, resulting from the variability of water temperature (thermo) and salinity (haline), also cause ocean currents.
  140. [140]
    Live Science Update: CFCs, Unintentional Ocean Tracers
    May 11, 2018 · CFC stands for Chlorofluorocarbons. As the name suggests, these are chemicals that contain chlorine, fluorine, and carbon atoms.
  141. [141]
    Developing the theory [This Dynamic Earth, USGS]
    Jul 11, 2025 · Called the global mid-ocean ridge, this immense submarine mountain chain -- more than 50,000 kilometers (km) long and, in places, more than 800 ...Missing: total length
  142. [142]
    Argo Program - Global Ocean Monitoring and Observing
    The Argo Program was developed in 1999 and today supports a global array of almost 4,000 robotic profiling floats that measure the temperature and salinity of ...Missing: units | Show results with:units
  143. [143]
    Summary | Jason-3 - Ocean Surface Topography from Space
    The altimeter measures sea-level variations over the global ocean with very high accuracy (1.3 inches or 3.3 centimeters, with a goal of achieving 1 inch or 2.5 ...
  144. [144]
    What are El Nino and La Nina? - NOAA's National Ocean Service
    Jun 16, 2024 · El Niño and La Niña events occur every two to seven years, on average, but they don't occur on a regular schedule. Generally, El Niño occurs ...
  145. [145]
    What is a mid-ocean ridge? - NOAA Ocean Exploration
    Jul 8, 2014 · The mid-ocean ridge system is the most extensive chain of mountains on Earth, stretching nearly 65,000 kilometers (40,390 miles) and with more ...
  146. [146]
    World Register of Marine Species - WoRMS
    WoRMS aims to provide an authoritative list of marine organism names, controlled by experts, and is the global database of all marine life.
  147. [147]
    Population Dynamics - an overview | ScienceDirect Topics
    To describe the population dynamics, there are four key factors that need to be considered: birth, death, immigration, and emigration of individuals. These ...
  148. [148]
    [PDF] Census of Marine Life Committee Report
    May 14, 2010 · Census scientists estimate that about 230,000 species of marine animals have been ... display the results of the ten-year Census of Marine Life.<|separator|>
  149. [149]
    Metabarcoding of marine environmental DNA based on ... - Nature
    Oct 4, 2018 · Molecular-DNA-based species-identification methods like DNA barcoding have been established during recent decades for the study of biodiversity.
  150. [150]
    Environmental DNA (eDNA) metabarcoding reveals ... - PubMed
    eDNA metabarcoding can distinguish localized signals between marine habitats, suggesting limited dispersal of eDNA among habitats.
  151. [151]
    About - The Global Ocean Biodiversity Initiative
    GOBI is an international partnership of institutions committed to advancing the scientific basis for conserving biological diversity in the marine environment.
  152. [152]
    New study maps 35 years of giant kelp forest persistence and ...
    Jun 10, 2021 · 35 years of satellite data information along the West Coast of North America to identify and understand potential sanctuaries for these giant kelp forests.Missing: GOBI | Show results with:GOBI
  153. [153]
    Human activity devastating marine species from mammals to corals
    Dec 9, 2022 · The IUCN Red List now includes 150,388 species, of which 42,108 are threatened with extinction. Over 1,550 of the 17,903 marine animals and ...
  154. [154]
    NOAA confirms 4th global coral bleaching event
    Apr 15, 2024 · Since early 2023, mass bleaching of coral reefs has been confirmed throughout the tropics, including in Florida in the U.S.; the Caribbean; ...
  155. [155]
    Microbial Metagenomics: Beyond the Genome - Annual Reviews
    Nov 12, 2010 · We review recent studies and discoveries since 2008, provide a discussion of bioinformatic analyses, including conceptual pipelines and sequence ...
  156. [156]
    Marine Microbial Metagenomics: From Individual to the Environment
    May 19, 2014 · The next boost to metagenomics research was the use of the whole genome shotgun (WGS) approach employing next generation sequencing to bypass ...
  157. [157]
    Introduction to fisheries management advantages, difficulties and ...
    The meaning of the word “sustainable”, which appears in the concept of maximum sustainable yield (MSY) is important and needs to be explained. The two ...
  158. [158]
    FAO Report: Global fisheries and aquaculture production reaches a ...
    Jun 7, 2024 · Global fisheries and aquaculture production in 2022 surged to 223.2 million tonnes, a 4.4 percent increase from the year 2020.Missing: 90 | Show results with:90
  159. [159]
    Deploy Offshore Wind Turbines - Project Drawdown®
    Sep 22, 2025 · As of 2023, the global installed capacity for offshore wind energy reached approximately 73,000 MW (Table 3; IRENA, 2024b). Although we used ...<|separator|>
  160. [160]
    Deep sea archaeological survey in the Black Sea - ScienceDirect.com
    Between 2015 and 2017 the Black Sea Maritime Archaeology Project (Black Sea MAP) discovered and recorded 65 shipwreck sites dating from the 4th Century BC ...
  161. [161]
    [PDF] The Operational Search for MH370 - ATSB
    May 10, 2017 · The search for MH370 included a 52-day surface search, a large underwater search mapping 710,000 sq km, and debris found on Indian Ocean ...
  162. [162]
    [PDF] United Nations Convention on the Law of the Sea
    exclusive economic zones of two or more coastal. States or both within the ... 200 nautical miles . . . . . . . . . . . . . . . . . . . . . . . . . . 52.
  163. [163]
    [PDF] International policy framework for blue carbon ecosystems
    This policy framework, developed by CI and IUCN, provides an overview of the intersections and opportunities for blue carbon ecosystem conservation and ...
  164. [164]
    The Mining Code: Exploration Regulations
    Decision of the Assemby of the International Seabed Authority relating to the regulations on prospecting and exploration for polymetallic sulphides in the Area.Missing: 2020s | Show results with:2020s
  165. [165]
    Chapter 9: Ocean, Cryosphere and Sea Level Change
    This chapter provides a holistic assessment of the physical processes underlying global and regional changes in the ocean, cryosphere and sea level, as well as ...