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Deep ocean water

Deep ocean water refers to the cold, dense water masses occupying the ocean depths below approximately ( feet), where becomes minimal and the begins, resulting in a perpetually dark, , and high-pressure environment with temperatures averaging around 4°C (39°F) and pressures exceeding 40 times atmospheric levels at those depths. These waters, which constitute the majority of the 's volume—covering over 90% of the seafloor—are characterized by stable levels typically between 34.6 and 35 parts per thousand, low nutrient availability except for inputs from sinking known as , and minimal biological productivity compared to surface layers. Formed primarily through in high-latitude regions, deep water originates from surface waters that cool and become denser due to , formation, or atmospheric cooling, leading to in areas like the North Atlantic and around . Key deep ocean water masses include (NADW), formed in the and Seas with temperatures of 1–3.5°C and salinity around 35 , which spreads southward at depths of 2,000–4,000 meters at a rate of about 13–20 Sverdrups (10^6 m³/s), transporting heat and nutrients globally. (AABW), the densest variety at -0.4°C and 34.6 , forms near the through brine exclusion during production and flows northward along ocean bottoms, influencing deep circulation in all major basins. These water masses play a critical role in the global thermohaline conveyor belt, regulating climate by sequestering carbon and heat from the surface, with occurring primarily in the to complete the cycle over centuries to millennia. Despite their isolation, deep ocean waters support unique ecosystems adapted to extreme conditions, including bioluminescent organisms and chemosynthetic communities near hydrothermal vents, highlighting their ecological significance.

Definition and Characteristics

Definition

Deep ocean water refers to the layer of seawater located below approximately 200 meters, below the main thermocline where present—the depth of which varies by region, typically between 200 and 1000 meters—where temperatures stabilize between 0°C and 4°C and remain relatively constant with increasing depth. This threshold marks the boundary from the warmer, more variable intermediate waters above, encompassing the mesopelagic, bathypelagic, abyssopelagic, and hadal zones that constitute the majority of the ocean's volume. Unlike surface waters influenced by solar radiation and atmospheric interactions, deep ocean water forms a stable, stratified reservoir isolated from direct surface processes. The term "deep ocean water" emerged in during the early to describe these submerged water masses, building on foundational expeditions like the Challenger voyage (1872–1876) that revealed the ocean's vertical structure and the isolation of deeper layers from solar heating. It distinguishes water parcels that sink from polar regions and spread equatorward, maintaining distinct physical signatures over vast timescales due to their separation from the mixed surface layer. Distinguishing characteristics of deep ocean water include its profound from the atmosphere, which limits direct of gases and ; minimal arising from weak vertical mixing in the stably stratified ; and extended times spanning centuries to millennia, reflecting slow rates in this vast, remote domain. These traits underscore its role as a long-term for properties, with uniform cold temperatures and elevated densities that contrast sharply with overlying layers.

Physical Properties

Deep ocean water exhibits a narrow temperature range of 0°C to 4°C, reflecting its formation in cold polar regions and subsequent isolation from surface warming. This near-constant profile varies slightly by latitude, with reaching temperatures as low as -0.8°C due to its origin near the freezing point of . In contrast, deep waters at lower latitudes approach 4°C, maintaining uniformity that persists over vast horizontal distances. Salinity in deep ocean water typically spans 34.5 to 35 practical salinity units (psu), a stability driven by conservative mixing after formation. Polar source waters, such as , show slightly elevated salinities around 34.65 psu, resulting from brine rejection during production that concentrates salts in the residual liquid. These levels contribute to the overall uniformity, with minimal variation except near formation sites. Density characteristics are defined by potential density anomalies (σθ) exceeding 27.8 kg/m³, enabling deep water to sink and remain stratified beneath lighter surface layers. This high density stems primarily from the low temperatures and salinities, with σθ values often reaching 28.0 kg/m³ in . Hydrostatic , which increases by about 1 dbar per meter of depth, exceeds 1000 dbar below 1000 meters and alters compressibility, thereby increasing in situ density beyond potential values. The cold conditions of deep ocean water enhance oxygen solubility, resulting in dissolved oxygen concentrations of 5 to 8 ml/L in regions with recent from the surface. These elevated levels, compared to warmer surface waters, support the oxygenation of abyssal environments, though they gradually decline with water mass aging due to biological .

Formation and Sources

Thermohaline Processes

Deep ocean water forms primarily through thermohaline processes, where variations in and alter , driving vertical sinking in polar regions. In these high-latitude areas, surface waters experience intense cooling during winter, which increases density by contracting the water molecules and reducing . This cooling can lower temperatures to near-freezing levels, such as around 0°C in the North Atlantic, prompting denser water to sink and initiate . Evaporation, though less dominant in polar zones compared to subtropical regions, contributes indirectly by increasing in source waters that flow poleward, further enhancing upon cooling. A critical amplifying is brine rejection during sea ice formation: as freezes, pure crystals exclude , releasing concentrated that mixes with underlying water, raising its by up to 2-3 practical salinity units (psu) in severe events. This process promotes , leading to vigorous mixing and plumes that extend deep into the water column. The primary sites of deep convection are the and the Nordic Seas, where these density increases facilitate the formation of major deep water masses like . Seawater density \rho is governed by the equation of state \rho = \rho(T, S, P), where T is , S is , and P is ; this nonlinear relationship means small perturbations in T or S yield outsized changes. For instance, a linear approximation shows \Delta \rho \approx -\alpha \Delta T + \beta \Delta S, with thermal expansion coefficient \alpha \approx 0.15 \, \mathrm{kg/m^3/^\circ C} and haline contraction \beta \approx 0.78 \, \mathrm{kg/m^3/psu}, so a 1°C cooling boosts by about 0.15 kg/m³, while a 0.1 psu increase adds roughly 0.08 kg/m³—shifts sufficient to overcome and drive sinking. These formation events typically unfold over weeks to months, followed by restratification. Once formed, deep water masses "age" slowly, with residence times in the ocean interior spanning 500-1000 years, as traced by geochemical markers like chlorofluorocarbons.

Global Sources

Deep ocean water primarily originates from a few key polar and subpolar regions where intense cooling and brine rejection during formation produce dense water masses that sink to great depths. The two dominant sources are (AABW) and (NADW), which together account for the majority of global deep water volume and drive much of the ocean's . AABW forms along the Antarctic continental shelf, particularly in the and , through shelf processes involving production and dense shelf water overflow. This water mass is the densest in the global , with temperatures near -0.4°C and salinity around 34.6, allowing it to fill the abyssal layers below 4000 meters across multiple ocean basins. AABW constitutes approximately 30-40% of the total deep ocean water volume, estimated at about 0.47 × 10^9 km³ based on hydrographic surveys. In contrast, NADW originates from deep convection in the North Atlantic subpolar gyre, primarily in the and through overflows from the and Seas across the Greenland-Scotland Ridge. This water is warmer and less dense than AABW, with temperatures of 1-2.5°C and near 35, occupying intermediate to lower deep layers at depths of 2000-4000 meters. NADW volume is estimated at around 0.27 × 10^9 km³, representing about 21% of the global deep water. Minor contributions to deep ocean water come from other regions, including the Mediterranean Outflow Water, which provides small quantities of dense, that mixes into the North Atlantic deep layer, and inputs from Circumpolar Deep Water around , which incorporates shelf-derived waters from additional coastal polynyas. These secondary sources add limited volume but influence local deep water properties through mixing. The total global deep water formation rate is estimated at 20-30 Sverdrups (1 Sv = 10^6 m³/s), with AABW production around 8 Sv and NADW at approximately 13 Sv, reflecting the combined sinking from these primary sites. Historical efforts to map these source regions began with the in the 1870s, which conducted the first global deep-sea sampling and revealed uniform abyssal temperatures suggestive of polar origins for deep waters. Recent studies as of 2023-2025 indicate a weakening of deep water formation in these regions due to climate-driven freshening from increased melt and reduced extent, which strengthens surface and suppresses . For instance, projections suggest AABW formation rates could decline by up to 50% by mid-century under high-emission scenarios, potentially impacting global ocean circulation and .

Distribution and Circulation

Vertical and Horizontal Distribution

Deep ocean water exhibits distinct vertical , primarily characterized by the layering of major water masses based on . (NADW) occupies mid-depths, typically between 2000 and 4000 meters, where it forms a prominent layer with neutral densities ranging from 27.90 to 28.10 kg m⁻³. Below this, (AABW), the densest water mass with neutral densities exceeding 28.27 kg m⁻³, fills the ocean abyss below approximately 4000 meters, creating a cold, dense bottom layer that underlies NADW in regions where both are present. This arises from the thermohaline properties of these waters, with AABW's higher preventing it from mixing upward into NADW layers. Horizontally, deep ocean water distribution varies significantly across ocean basins due to differences in water mass formation, density, and basin geometry. In the Atlantic Ocean, NADW and AABW fill the full depth profile, with NADW dominating the deep layer (2000–4000 m) and spreading southward via the Deep Western Boundary Current, while AABW extends northward to about 40°N. In contrast, the features a shallower deep layer, as the absence of NADW formation results in less dense waters like Pacific Deep Water occupying depths above 2000–4000 m, with AABW thinning and penetrating less extensively into the northern Pacific abyss. Similarly, in the , deep waters derived from NADW and AABW are confined to intermediate to lower depths (2000–3500 m in some basins), with zonal variations showing deeper AABW penetration in the Atlantic compared to the shallower limits in the Indian and Pacific Oceans, where less dense intermediate waters overlay the abyss. These patterns reflect the global asymmetry in deep water ventilation, with the Atlantic exhibiting fuller basin-scale filling. Mapping the vertical and horizontal distribution of deep ocean water relies on techniques that account for density-driven structures, such as neutral density surfaces and autonomous profiling floats. Neutral density (γ_n), a variable derived from , , , , and , defines surfaces along which water parcels move with minimal work, enabling accurate labeling and interpolation of water mass properties from hydrographic data for global distribution maps. Deep floats complement this by providing full-depth profiles (to 6000 m) of and , allowing high-resolution mapping of water mass boundaries and properties in remote abyssal regions, with improving spatial coverage and accuracy. Deep ocean water constitutes approximately 50% of the total volume, primarily below 2000 meters, with residence times varying by due to differences in rates. In , deep waters renew on timescales of about 275 years, while in the Pacific abyss, residence times exceed 1000 years, reaching up to 1494 years in the western Pacific; the exhibits intermediate timescales similar to the Pacific, reflecting slower and mixing in these basins.

Role in Ocean Circulation

Deep ocean water integrates into the (THC) primarily through density-driven sinking at polar regions, where surface waters cool and become saline enough to descend below 2000 meters, initiating deep currents that flow slowly equatorward along the ocean bottom. This process forms the southward-moving deep limb of the THC, transporting cold water masses like (NADW) and (AABW) across basins. of this deep water occurs diffusely, mainly in the at intermediate depths of 1000-2000 meters, where it mixes with warmer surface waters to complete the overturning cycle and return nutrients to shallower layers. In the global conveyor belt model of ocean circulation, deep ocean water dominates the lower branch of this interconnected loop, which circulates heat, dissolved gases, and carbon on timescales of 500-1000 years. Cold, dense deep waters sink in the North Atlantic and Southern Ocean, flow northward in the Atlantic and southward in other basins, and upwell to influence surface conditions worldwide, thereby modulating equatorial heat export and polar cooling. This deep limb contrasts with the warmer, shallower northward flow, creating a net poleward heat transport essential for Earth's energy balance. The meridional overturning is often represented by the streamfunction \psi, defined as the depth-integrated meridional velocity: \psi = \int v \, dz where v is the meridional component of velocity and the integral is taken over the water column. In the Atlantic basin, this yields an overturning strength of approximately 15-20 Sverdrups (Sv; 1 Sv = $10^6 m³/s), underscoring the vigorous yet slow deep water flux that sustains global thermohaline balance. Deep ocean water also interacts with wind-driven gyre circulation via mesoscale eddies and intense boundary flows, including the Deep Western Boundary Current (DWBC), which channels southward NADW along continental slopes in at depths exceeding 2000 meters and speeds of 10-30 cm/s. These interactions facilitate deep water ventilation and exchange between interior and boundary pathways, linking thermohaline and wind-forced components. Circulation variability arises from perturbations like increased freshwater input from ice melt, which reduces surface density and weakens sinking; observations indicate an (AMOC) slowdown from ~19 Sv in 2004 to ~17 Sv by the 2010s, with the mean strength from 2004 to 2020 at 16.9 ± 1.2 Sv, and as of 2025, studies suggest continued weakening but limited decline and no collapse before 2100 under moderate emissions scenarios.

Chemical and Biological Aspects

Chemical Composition

Deep ocean water exhibits a stable for major ions, primarily due to conservative mixing processes that maintain proportional concentrations regardless of dilution or effects. The dominant ions include at approximately 19.4 g/kg and sodium at 10.8 g/kg in of 35, with these values varying linearly with across ocean depths. Other major constituents, such as (2.7 g/kg), magnesium (1.3 g/kg), and calcium (0.4 g/kg), similarly follow conservative behavior, reflecting long-term equilibrium from continental inputs and minimal removal in deep waters. Dissolved inorganic carbon (DIC) concentrations in deep ocean water are elevated, typically reaching around 2200 µmol/kg, largely from the remineralization of sinking that releases CO₂ at depth. This accumulation contributes to a lower , averaging about 7.8 in abyssal waters, compared to surface values near 8.1, as the increased CO₂ forms . Trace elements in ocean water show distinct enrichments influenced by geological inputs. Dissolved silica (SiO₂) concentrations often exceed 100 µmol/L, building up from the of biogenic in sinking particles and reaching up to 170 µmol/L in isolated deep basins. Hydrothermal vents contribute elevated levels of trace metals such as iron, , and , dispersing them through buoyant plumes that mix into surrounding waters. The state of deep ocean water varies with depth, featuring oxygen minimum zones (OMZs) at mid-depths (typically 200–1000 m) where oxygen concentrations drop below 20 µmol/kg due to high outpacing supply. Below these zones, waters transition to more oxic conditions , with oxygen levels stabilizing at 100–150 µmol/kg in well-ventilated deep currents. In the system, deep ocean waters below approximately 1000 m in many basins become undersaturated with respect to (Ω_arag < 1), driven by effects, low temperatures, and accumulated that reduce availability. This undersaturation extends deeper in regions like the North Pacific, impacting the preservation of structures.

Nutrient Dynamics and Ecosystems

Deep ocean water is enriched with nutrients such as , , and , primarily due to the remineralization of sinking from surface waters. Typical concentrations in deep waters include at 20-40 µmol/L, at 2-3 µmol/L, and often exceeding 100 µmol/L, reflecting the accumulation from the decay of and other biogenic particles. These elevated levels contrast with nutrient-depleted surface waters and provide essential resources for deep-sea biological processes. The regeneration of these nutrients occurs through bacterial remineralization within the soft tissue pump, a key component of the 's biological carbon pump. As particulate organic carbon sinks from the productive surface layer, heterotrophic decompose it, releasing inorganic nutrients and into deeper waters, thereby exporting carbon to the ocean interior and preventing its rapid return to the atmosphere. This process efficiently transfers approximately 10 Pg C annually to depths below 1,000 m, sustaining the chemical gradients that drive global nutrient cycles. Deep-sea ecosystems thrive on these nutrient dynamics, particularly in chemosynthetic communities around hydrothermal vents and cold seeps. Here, microbes oxidize (H₂S) and other reduced compounds from vent fluids to fix carbon via , forming the base of food webs that support specialized like giant tube worms (Riftia pachyptila), which harbor in their trophosomes for nutrient processing. These oases of life demonstrate how deep ocean nutrients enable energy production independent of , with microbial mats and associated recycling locally abundant chemicals. The deep ocean harbors immense , with adaptations to extreme conditions like perpetual darkness, , and cold temperatures enabling a vast array of . Approximately 90% of the 's volume lies below 200 m, supporting a disproportionate share of , including over 90% of biomass in the and countless undescribed overall. Organisms such as (Melanocetus johnsonii) employ bioluminescent lures for predation in low-light environments, while (Architeuthis dux) exhibit pressure-resistant bodies and large eyes for detecting faint light. These adaptations, including reduced skeletal structures and efficient metabolic rates, allow survival under pressures exceeding 1,000 atm. Nutrient dynamics in deep ocean water link to surface productivity through , where deep nutrients are brought to sunlit zones, indirectly fueling about 50% of global ocean via enhanced growth in regions like eastern boundary currents. This vertical nutrient transport sustains high-biomass areas that support major fisheries, underscoring the deep ocean's role in the broader and .

Human Interactions

Applications

Deep ocean water's low temperature, typically around 4–6°C, and richness enable innovative applications in , production, and marine farming. At the Natural Energy Laboratory of Hawaii Authority (NELHA), established in 1974, cold deep seawater is piped from depths of approximately 900 meters to cool soil and air in land-based systems, facilitating the year-round cultivation of crops that would otherwise struggle in 's . This "cold-bed" approach involves running chilled water through subsurface pipes or hoses, which lowers ground temperatures and condenses atmospheric moisture for , supporting the growth of temperate vegetables and fruits such as strawberries, tomatoes, and papayas with reduced costs for cooling. In energy and desalination, ocean thermal energy conversion (OTEC) harnesses the temperature gradient between warm surface water and cold deep ocean water to generate and produce freshwater. OTEC systems use a like to drive a , with cold deep water condensing the vapor after . A 100 kW closed-cycle OTEC pilot plant at NELHA, operational since 2015, demonstrates this technology, supplying power to the local grid and highlighting efficiencies of around 3%. In Japan, the 100 kW OTEC facility on Kumejima Island, converted from a fisheries site and active since 2013, integrates deep water intake for power generation with efficiencies similarly in the 3–5% range, while also supporting for potable water production; as of 2023, it has plans for expansion to 1 MW by 2026. Aquaculture benefits from deep ocean water's stable cold temperatures and high nutrient content, which promote healthier growth and lower disease incidence in . In , NELHA supplies deep seawater to over 30 tenants for raising species like , , and , where the cold water maintains optimal conditions and reduces risks. Similarly, salmon farms utilize deep-water intakes from 30–160 meters to access cooler, oxygen-rich water, minimizing sea lice infestations and improving survival rates in (Salmo salar) production. Infrastructure for these applications includes extensive pipelines, such as NELHA's approximately 2.7 km offshore cold-water pipe from around 900 meters depth, which delivers up to 21,000 gallons per minute for distribution across facilities. , including deep ocean water, holds potential for mineral extraction of elements like magnesium and , though commercial-scale recovery remains in early research stages. Additionally, the bottled deep ocean water market is growing, valued at approximately USD 1.52 billion in 2025. Economically, OTEC's global potential is estimated at per year, equivalent to meeting a significant portion of tropical regions' needs while providing co-benefits like and support.

Environmental Impacts

is exerting profound effects on deep ocean water through mechanisms such as freshening from melting ice sheets and glaciers, which reduces density and weakens the (THC). In the North Atlantic, increased freshwater input from ice melt and sea ice loss has contributed to this freshening, consistent with observed disruptions to the Atlantic Meridional Overturning Circulation (AMOC), a key component of the THC. Some studies indicate an AMOC weakening of approximately 15% since the , but a 2025 analysis suggests no significant decline over the last 60 years, highlighting ongoing debate and the need for further monitoring. Ocean acidification represents another critical impact, as deep ocean waters absorb a significant fraction of anthropogenic carbon dioxide (CO₂), altering their chemical properties. The oceans as a whole have taken up about 25% of cumulative anthropogenic CO₂ emissions since pre-industrial times, resulting in an average pH decline of 0.1 units, with subsurface and deep waters experiencing progressive acidification as CO₂ diffuses downward over decadal timescales. This process reduces carbonate ion availability, threatening deep-sea calcifying organisms and disrupting biogeochemical cycles in water masses below 1,000 meters. Pollution from human activities is increasingly infiltrating deep ocean environments, with microplastics and persistent organic contaminants sinking through the water column and accumulating in sediments. Microplastics, transported vertically via ocean currents and biological vectors, have been detected in deep-sea sediments across basins like the North Atlantic and Pacific, with abundances reaching several particles per liter in hadal zones. Similarly, contaminants such as polychlorinated biphenyls (PCBs) and other persistent organic pollutants (POPs) bioaccumulate in deep sediments, where organic matter degradation enhances their retention, posing long-term risks to benthic ecosystems. Deep-sea mining activities threaten to disrupt deep ocean water masses through sediment resuspension and plume generation during nodule harvesting. Extraction of polymetallic nodules from abyssal plains disturbs fine sediments, releasing particle clouds that can spread across the , altering , oxygen levels, and circulation patterns in midwater and deep layers. Such operations are projected to commence commercially in the 2030s, pending regulatory approvals, with initial small-scale activities potentially scaling up; as of 2025, negotiations continue, with some companies targeting starts as early as 2026. Ongoing monitoring efforts are essential to quantify these environmental impacts and inform mitigation strategies. Autonomous gliders and cabled observatories enable real-time profiling of deep ocean parameters, including , , , and particle distribution. The Ocean Observatories Initiative (OOI), fully operational since 2016, deploys these technologies across global sites to track changes in deep water properties driven by climate and human pressures.

References

  1. [1]
    What is the “deep” ocean? - NOAA Ocean Exploration
    This means the “deep” is the part of our ocean that is dark, cold, food-poor, subject to intense pressure, and typically deeper than 200 meters. Despite these ...
  2. [2]
    The Deep Sea | Smithsonian Ocean
    About three-fourths of the area covered by ocean is deep, permanently dark, and cold. This is the deep sea. a diagram showing the zones of the ocean.Ecosystems · Ocean Life · Light at the Bottom of the Ocean · Marine Snow
  3. [3]
    Major Deep Water Masses | EARTH 103: Earth in the Future
    Deep-water masses are produced at the surface of the ocean and transported to depth via downwelling. Generally, downwelling occurs where the surface ocean is ...Missing: oceanography | Show results with:oceanography
  4. [4]
    SIO 210: Atlantic - deep circulation and water masses
    Nov 26, 2019 · The formation rate of North Atlantic Deep Water is approximately 13 Sv (1 SV = 106 m3/s) and the mean potential temperature of the water ...
  5. [5]
    6.2 Temperature – Introduction to Oceanography
    This is called the thermocline. Below the thermocline the deep ocean temperature is fairly constant at about 2o C, continuing down to the bottom.Missing: threshold | Show results with:threshold
  6. [6]
    What is a thermocline? - NOAA's National Ocean Service
    Jun 16, 2024 · A thermocline is the transition layer between warmer mixed water at the ocean's surface and cooler deep water below.Missing: threshold | Show results with:threshold
  7. [7]
    Thermocline - an overview | ScienceDirect Topics
    Thermocline is defined as the stable, vertical gradient of ocean temperature that separates warmer upper layers from colder, denser layers below. AI generated ...
  8. [8]
    Reconsidering the term 'deep sea' | ICES Journal of Marine Science
    Jun 4, 2025 · The term 'deep sea', which is often interchangeable with the term 'deep ocean', relies on the definition of the global ocean deeper than 200 m.
  9. [9]
    Deep sea habitat - Coastal Wiki
    Nov 14, 2024 · This export of organic matter to deep ocean water layers and the ocean floor is an important carbon sequestration mechanism, called 'ocean's ...
  10. [10]
    Deep-sea turbulence evolution observed by multiple closely spaced ...
    Feb 16, 2021 · How turbulence generated by internal waves evolves and interacts in the deep-sea environment is still an unsolved question in oceanography.
  11. [11]
    New Data on Deep Sea Turbulence Shed Light on Vertical Mixing
    Dec 1, 1996 · New data on deep sea turbulence shed light on vertical mixing. Rough seafloor topography has far-reaching effect.
  12. [12]
    Fate of dissolved black carbon in the deep Pacific Ocean - Nature
    Jan 13, 2022 · The residence times of DBC in the abyssal layer, calculated from the removal flux and the pool size, are 2074–4148 years (Table 1). Although ...
  13. [13]
    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 ...Missing: thermocline | Show results with:thermocline
  14. [14]
    Atlantic Water Masses and the Conservation of T and S
    Antarctic Bottom Water (AABW) is formed at about 65S near the Antarctic Continent. It has a salinity of 34.65 psu and a potential temperature of -0.25C.
  15. [15]
    Transfer and Storage of Heat in the Oceans
    Water temperatures in the deep ocean are only between about 0° C and 4° C, and are nearly uniform throughout the world's oceans.
  16. [16]
    SIO 210 Talley Topic 2: Properties of seawater
    Seawater density depends on temperature, salinity and pressure. Colder water is denser. Saltier water is denser. High pressure increases density. The dependence ...
  17. [17]
    Layers of the Ocean - NOAA
    Mar 28, 2023 · The temperature never fluctuates far from a chilling 39°F (4°C). The pressure in the bathypelagic zone is extreme and at depths of 4,000 meters ...
  18. [18]
    [PDF] One Man's Advice on the Determination of Dissolved Oxygen in ...
    The equilibrium solubility values for dissolved oxygen increase with decreasing temperature, and salinity, and they range from about 4 to 9 ml/liter throughout ...
  19. [19]
    [PDF] Ocean Circulation: Thermohaline Circulation - NOAA
    Brine rejection from the formation of new sea ice maintains fairly high salinities on the shelf despite the freshening ef- fects of precipitation and the input ...
  20. [20]
    [PDF] Seawater Density - geo
    Seawater density is often expressed as Sigma-t (σt), calculated as ρ(s, t, 0) - 1000.0, where ρ is density, and increases until freezing.
  21. [21]
    How does Arctic sea ice form and decay - Wadhams - NOAA/PMEL
    The salt rejected back into the ocean from this ice formation causes the surface water to become more dense and sink, sometimes to great depths (2500 m or more ...
  22. [22]
    Sea-ice thermodynamics and brine drainage - Journals
    Jul 13, 2015 · In this article, we review some fundamentals of the thermodynamic growth of sea ice (§2) and illustrate the different magnitudes of buoyancy flux.Thermodynamic growth of sea... · Buoyancy fluxes · Experimental observations of...<|separator|>
  23. [23]
    Observations of open‐ocean deep convection in the northwestern ...
    Oct 13, 2016 · Then, the violent vertical mixing of the whole water column lasts between 9 and 12 days setting up the characteristics of the newly formed deep ...
  24. [24]
    Seawater density - Coastal Wiki
    Feb 22, 2021 · Seawater density decreases with increasing temperature and increases with increasing salinity. According to Eq. (3), an increase of 1 g / kg in ...
  25. [25]
    [PDF] Openocean convection Observations, theory, and models
    on a timescale of weeks to months, to the disintegration of the mixed ... Greenland Sea for deep convection: Ice formation and ice drift, J. Geophys ...
  26. [26]
    Tracing water masses with particle trajectories in an isopycnic ...
    ... 500–1000 years. Most of the remaining 70 ... Determination of water component age in ocean models: application to the fate of North Atlantic Deep Water ...
  27. [27]
    Antarctic Bottom Water and North Atlantic Deep Water in CMIP6 ... - OS
    Jan 13, 2021 · We not only investigate the properties of AABW and NADW by their formation region but also their transport into the rest of the global ocean.
  28. [28]
    Slowdown of Antarctic Bottom Water export driven by climatic wind ...
    Jun 12, 2023 · Antarctic Bottom Water (AABW) is the world's most voluminous water mass, comprising 30-40% of the volume of the global ocean. AABW circulates ...
  29. [29]
    Quantifying Antarctic Bottom Water and North Atlantic Deep Water volumes
    ### Extracted Volumes of AABW and NADW
  30. [30]
    Thermohaline Circulation - Fact Sheet by Stefan Rahmstorf
    Deep water formation takes place in a few localised areas: the Greenland-Norwegian Sea, the Labrador Sea, the Mediteranean Sea, the Wedell Sea, the Ross Sea.
  31. [31]
    Circulation, mixing, and production of Antarctic Bottom Water
    Based on water density, Antarctic Bottom Water (AABW) is defined here generically to include all volumes of non-circumpolar water of Antarctic origin. Over the ...Missing: percentage | Show results with:percentage
  32. [32]
    The Challenger Expedition - Dive & Discover
    The Challenger Expedition (1872-1876) gathered data on ocean features, discovered the Marianas Trench, and the first outline of the ocean basin.
  33. [33]
    Water masses in the Atlantic Ocean: characteristics and distributions
    Mar 15, 2021 · ... Sverdrup et al., 1942). The early studies were mainly based on (potential) temperature and (practical) salinity as summarized by Emery and ...
  34. [34]
    Antarctic Bottom Water - an overview | ScienceDirect Topics
    Being the densest water mass of the oceans (Purkey et al., 2018), AABW is found to occupy the depth range below 4000 m.
  35. [35]
    Deep water pathways in the North Pacific Ocean revealed ... - Nature
    Apr 22, 2022 · The residence time of particles is less than 1000 years and is consistent with an observation-based estimate of water age in the deep Pacific ...
  36. [36]
    North Atlantic deep water in the south-western Indian Ocean
    Deep water in the Indian Ocean, derived from NADW, is generally observed in the depth interval of 2000–3500 m (Toole and Warren, 1993; Mantyla and Reid, 1995; ...
  37. [37]
    A Neutral Density Variable for the World's Oceans in - AMS Journals
    Surfaces of constant γn define the neutral surfaces, which provide the proper framework for an ocean model's calculations and analysis. These neutral density ...
  38. [38]
    Deep Argo Improves the Accuracy and Resolution of Ocean ...
    Aug 13, 2025 · Deep Argo floats are automated platforms collecting temperature and salinity profiles from the surface to the seafloor in the deepest regions of ...
  39. [39]
    Rough Estimate of the Annual Changes in Ocean Temperatures ...
    Jul 4, 2013 · -52% of ocean volume below 2000 m. That obviously means that about 48% of the ocean volume is above 2000 meters. Assuming those percentages ...
  40. [40]
    The Age of Water and Ventilation Timescales in a Global Ocean ...
    The oldest water mass mixture (located at 2228-m depth in the western Pacific Ocean) is dated at 1494 years, made up of a combination of sources of water whose ...Missing: residence | Show results with:residence
  41. [41]
    Thermohaline Circulation - Currents - NOAA's National Ocean Service
    Surface water is pulled in to replace the sinking water, which in turn eventually becomes cold and salty enough to sink. This initiates the deep-ocean currents ...
  42. [42]
    Transformation of Deep Water Masses Along Lagrangian Upwelling ...
    Mar 14, 2018 · We quantify water mass transformation along upwelling pathways originating in the Atlantic, Indian, and Pacific and ending at the surface of the Southern Ocean.
  43. [43]
    What is the global ocean conveyor belt?
    Jun 16, 2024 · The global ocean conveyor belt is a constantly moving system of deep-ocean circulation driven by temperature and salinity.
  44. [44]
    [PDF] Global Ocean Meridional Overturning
    The model obtains a global overturning circulation consistent with the various observations, revealing two global-scale meridional circulation cells: an upper ...Missing: equation | Show results with:equation
  45. [45]
    Low variability of the Atlantic Meridional Overturning Circulation ...
    Jul 22, 2025 · From 6.5 ka BP onward, the AMOC strength stabilized, reaching its pre-industrial state around ~18 Sv. Hence, according to future projections, ...
  46. [46]
    [PDF] Characteristics and causes of Deep Western Boundary Current ... - OS
    The Deep Western Boundary Current (DWBC) at 34.5◦ S carries a significant fraction of the cold deep limb of the Meridional Overturning Circulation (MOC).
  47. [47]
    New discovery for deep water transport in the Atlantic Meridional ...
    Mar 26, 2024 · Researchers long thought the Deep Western Boundary Current was the main pathway for deep water movement in the North Atlantic.
  48. [48]
    An extreme event of sea-level rise along the Northeast coast of ...
    Feb 24, 2015 · Regression based on all monthly data from 2004 to 2012 further reveals a 13.2-mm SLR along the NE coast in response to 1 Sv AMOC slowdown. After ...
  49. [49]
    Climate impacts of a weakened Atlantic Meridional Overturning ...
    Jun 26, 2020 · The ensemble mean of AMOC decline trend is 7.713 Sv per Sv of freshwater input. ... AMOC slowdown: dependence on freshwater locations in the North ...
  50. [50]
    [PDF] Chapter 5 — Physical and thermodynamic data
    Oct 12, 2007 · Salinity and the composition of sea water. 6.1 The major ion composition of sea water ... Standard mean chemical composition of sea water (S = 35) ...
  51. [51]
    [PDF] OCN 623 – Chemical Oceanography - SOEST Hawaii
    Why are major ion distributions so consistent? Source of major ions to ocean is continental weathering. Reservoirs and fluxes. Ocean. 1.4 x 1021 L. Evap from ...
  52. [52]
    [PDF] CARBON DIOXIDE, DISSOLVED (OCEAN) - SOEST Hawaii
    Warm low-latitude surface water generally holds less CO2 (~10 µmol kg−1) and. ΣCO2 (~2000 µmol kg−1) than cold high-latitude surface water (CO2 ~15 µmol kg−1.
  53. [53]
    Deep-Sea pH | Science
    In the northeastern Pacific Ocean, north of 22°N and east of 180°W, a deep-sea pH maximum of 7.9 exists near 4000 meters.
  54. [54]
    The biogeochemical cycle of silicon in the modern ocean - BG
    Feb 18, 2021 · In this review, we show that recent advances in process studies indicate that total Si inputs and outputs, to and from the world ocean, are 57 % and 37 % ...
  55. [55]
    Trace Metal Dynamics in Shallow Hydrothermal Plumes at the ...
    Jan 6, 2022 · Hydrothermal vents are a source of many trace metals to the oceans. Compared to mid-ocean ridges, hydrothermal vent systems at arcs occur in ...
  56. [56]
    What is an oxygen minimum zone? - NOAA Ocean Exploration
    Apr 18, 2023 · Oxygen minimum zones are persistent layers in the water column that have low oxygen concentration due to biological, chemical, and physical ...Missing: redox | Show results with:redox
  57. [57]
    The 'oxygen' in oxygen minimum zones - PMC - NIH
    In many places in the global ocean, oxygen is completely removed at mid‐water depths forming anoxic oxygen minimum zones (A‐OMZs).
  58. [58]
    Calcium carbonate dissolution in the upper 1000 m of the eastern ...
    Mar 13, 2014 · Water masses were found to be undersaturated with respect to aragonite at intermediate depths (400–1000 m) in the eastern tropical North ...
  59. [59]
    [PDF] present conditions and Future changes in a high-co World
    For most open-ocean surface waters, aragonite undersaturation occurs when carbonate ion concentrations drop below approximately 66 µmol kg-1. The model ...
  60. [60]
    [PDF] 1. Regulation of nitrate, phosphate, and oxygen in the ocean
    The ratio of phosphate and nitrate concentrations in the deep ocean matches closely the Redfield ratio required by phytoplankton growing in the surface ocean.
  61. [61]
    Deep ocean biogeochemistry of silicic acid and nitrate - AGU Journals
    Mar 17, 2007 · Organic matter remineralizes predominantly in the main thermocline while opal dissolves primarily in the deep ocean.
  62. [62]
    [PDF] Carbon Export in the Ocean: A Biologist's Perspective
    Sep 2, 2022 · Organic matter is converted to DIC and nutrients by bacterial remineralization during sinking. The depth of remineralization determines how long ...
  63. [63]
    Jigsaw puzzle of the interwoven biologically-driven ocean carbon ...
    The biological pump is called soft-tissue pump in Volk and Hoffert (1985). Export mechanisms: (a) gravitational and migrant, and (b) gravitational and mixing.
  64. [64]
    Carbon Pumps in the Oceans | Microbes - Oxford Academic
    Feb 22, 2024 · Nowicki's study says the biological pump exports about 10 petagrams of carbon (Pg C) each year, roughly the same amount of carbon dioxide put ...
  65. [65]
    The Microbes That Keep Hydrothermal Vents Pumping
    Microbes convert mineral-laden fluid into energy via chemosynthesis, using chemical compounds from vents, and are primary producers in the food web.
  66. [66]
    [PDF] How Giant Tube Worms Survive at Hydrothermal Vents
    Deep-sea hydrothermal vent ecosystems rely on chemosynthesis to produce energy-rich organic molecules that are used as food by a diversity of organisms.
  67. [67]
    [PDF] Lesson III: Animal Adaptations and Distributions II
    Deep sea adaptations include higher water content, weak muscles, reduced bones, reduced eyes, large mouths, and the lateral line system for distance touch.<|separator|>
  68. [68]
    Dive Deep: Bioenergetic Adaptation of Deep-Sea Animals - BioOne
    Jan 22, 2025 · Deep-sea fishes may consume oxygen at rates only 5–10% of those that characterize shallow-water species. The biochemical basis of this ...
  69. [69]
    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.
  70. [70]
    7.4 Patterns of Primary Production – Introduction to Oceanography
    Global averages for ocean surface primary production are about 75-150 g C/m2/yr. Some highly productive areas include the California coast (200-300 g C/m2/year) ...
  71. [71]
    Powered by the Natural Energy Laboratory of Hawaii Authority
    Three sets of pipelines deliver cold deep-sea water from up to 2,200 ft. depth as well as warm pristine surface seawater. Current equipment and pipeline ...About HOST Park & NELHA · HOST Park is an Ocean... · Our Clients · Contact Us
  72. [72]
    Sea Power, Part 3 - Renewable Energy World
    Companies are using this deep water for aquaculture at NELHA's site, raising lobsters, abalone, algae, and more. Running the deep-water tubes through soil can ...
  73. [73]
    Natural Energy Lab Fosters its Own Startup Paradise - Page 2 of 2
    Apr 28, 2015 · The cold ocean water, running through hoses above ground, pulls the moisture from the air, which then, one drop at a time, irrigates the plants.
  74. [74]
    NELHA: Diverse Agricultural Products on Hawaii's Big Island
    Nov 29, 2011 · A facility where they pump cool sea water from 2000 feet under the water's surface in order to use ocean water for aquaculture and terrestrial based growing.
  75. [75]
    Success Stories at HOST Park
    Makai has used the deep water infrastructure provided by NELHA to supply OTEC power to the local grid in a demonstration project in 2014, making it the world's ...
  76. [76]
    Hawaii First to Harness Deep-Ocean Temperatures for Power
    Aug 27, 2015 · A new power plant offshore converts the temperature difference between sea surface and deep waters into electricity.
  77. [77]
    [PDF] Applications and Benefits of OTEC - SIDS Lighthouses Initiative
    Nov 11, 2024 · DOW intake infrastructure, installed as a utility can provide economic development, climate and disaster resilient food, water, and jobs –.<|control11|><|separator|>
  78. [78]
    Opinion on ocean thermal energy conversion (OTEC) - Frontiers
    Feb 26, 2023 · The highest efficiency was found to be 4.60% under operation with different superheated ammonia temperatures. Additionally, several united OTEC ...
  79. [79]
    [PDF] investigation of seawater quality issues relating to larval survival ...
    Jun 29, 2024 · This cold, nutrient- rich seawater is used in aquaculture and other marine biotechnology applications and also in cooling solutions for ...
  80. [80]
    Aquaculture in Hawai'i – Ancient Traditions, Modern Innovation
    Dec 16, 2019 · Most of these utilize the deep ocean water provided by HOST Park from offshore pipes descending several thousand feet deep for animal and plant ...
  81. [81]
    Technology - salmonevolution.no
    Deep-water intake. Controlling water conditions. At our production site in Indre Harøy on the Norwegian west coast, seawater intake utilises two inlet pipes ...
  82. [82]
    Andfjord Salmon's “next-generation” patented aquaculture concept ...
    Apr 29, 2020 · The water inlets, at depths of 30 meters to 160 meters, give optimal temperatures of 7 or 12 degrees Celsius, depending on the time of year.<|control11|><|separator|>
  83. [83]
    Aquaculture and energy-generation benefit from pipeline deep under...
    Sep 1, 2002 · The 9,000-foot long, cold water pipeline was successfully deployed last October by the contractor, Healy Tibbitts Builders, Inc. of Honolulu.
  84. [84]
    Harnessing the Ocean's depths: SWAC and OTEC for sustainable ...
    Deep Ocean Water systems offer sustainable solutions for cooling, electricity, and freshwater production in tropical regions. •. Interdisciplinary analysis ...
  85. [85]
    What is the global potential of OTEC?
    Jan 13, 2025 · OTEC could generate 10000 TWh annually, supporting over 3 billion people in the tropical belt, according to the International Renewable ...
  86. [86]
    Changing Ocean, Marine Ecosystems, and Dependent Communities
    The freshening of the high latitudes in the north Atlantic and Arctic basin is consistent with the widely expected weakening of the AMOC (also discussed in ...
  87. [87]
    If you doubt that the AMOC has weakened, read this - RealClimate
    May 28, 2018 · In addition we have the conclusion by Kanzow et al. from hydrographic sections that the AMOC has weakened by ~ 10% since the 1950s (see below). ...Missing: percentage | Show results with:percentage
  88. [88]
    Decades of Data on a Changing Atlantic Circulation | News
    Apr 24, 2024 · Since density is a function of the temperature and salinity of seawater, the density-driven ocean currents system is known as thermohaline ocean ...
  89. [89]
    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 ...
  90. [90]
    An Overview of Ocean Climate Change Indicators: Sea Surface ...
    Ocean Heat Content in the upper 2,000 m shows a linear warming rate of 0.35 ± 0.08 Wm–2 in the period 1955–2019 (65 years). The warming rate during the last ...
  91. [91]
    [PDF] The combined effects of acidification and hypoxia on pH and ...
    The combined effects of acidification and hypoxia decrease pH and aragonite saturation, with enhanced changes in subsurface waters, and aragonite saturation ...
  92. [92]
    The distribution of subsurface microplastics in the ocean | Nature
    Apr 30, 2025 · Taken together, accumulation zones of large microplastics extend into the oceanic water column, primarily constrained to the near-surface waters ...
  93. [93]
    Organic matter degradation causes enrichment of organic pollutants ...
    Apr 10, 2023 · The deep ocean is considered a significant sink for POPs, and burial of PCBs in ocean sediments is estimated to correspond to 60% of cumulative ...<|separator|>
  94. [94]
    https://www.ncei.noaa.gov/news/decades-data-changing-atlantic-circulation
  95. [95]
    https://www.whoi.edu/press-room/news-release/no-amoc-decline/
  96. [96]
    [PDF] 26th Session - International Seabed Authority
    Oct 31, 2022 · It is likely that deep-sea mining will start on a relatively small scale, with activity expected to increase over time as technology develops ...
  97. [97]
    The Ocean Observatories Initiative (OOI)
    The Ocean Observatories Initiative (OOI) is a science-driven ocean observing network that delivers real-time data from more than 900 instruments.The Observatory · Gliders · Cabled Infrastructure · Regional Cabled ArrayMissing: deep 2016
  98. [98]
    Enabling the Ocean Observatory Initiative - Teledyne Marine
    Aug 24, 2021 · The OOI was commissioned and accepted by the NSF in 2016 and has been steadily deliv-ering data from across the OOI through the Internet 24/7/ ...Missing: monitoring | Show results with:monitoring