Ocean heat content

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Over 90% of the thermal energy that has accumulated on Earth from global heating since 1970 is stored in the ocean.[1]

In oceanography and climatology, ocean heat content (OHC) is a term for the energy absorbed by the ocean, where it is stored for indefinite time periods as internal energy or enthalpy. The rise in OHC accounts for over 90% of Earth’s excess thermal energy from global heating between 1971 and 2018.[1][2] It is extremely likely that anthropogenic forcing via rising greenhouse gas emissions was the main driver of this OHC increase.[3] About one third of the added energy has propagated to depths below 700 meters as of 2020.[4][5]

Ocean waters are efficient absorbents of solar energy and have far greater heat capacity than atmospheric gases.[4] The top few meters of the ocean consequently contain more thermal energy than Earth's entire atmosphere.[6] Research vessels and stations have sampled sea temperatures at depth and around the globe since before 1960. Additionally after year 2000, an expanding network of nearly 4000 Argo robotic floats has measured the temperature anomaly, or equivalently the change in OHC. Since at least 1990, OHC has increased at a steady or accelerating rate.[1][7]

Changes in ocean heat content have far-reaching consequences for the planet's marine and terrestrial ecosystems; including multiple impacts to coastal ecosystems and communities. Effects include variations in sea level and polar ice sheets, climate change and shifts in extreme weather phenomena, and the migration and extinction of biological species.[8][9]

Background[edit]

The more abundant equatorial solar irradiance which is absorbed by Earth's tropical surface waters drives the overall poleward propagation of ocean heat. The surface also exchanges energy with the lower troposphere, and thus responds to long-term changes in cloud albedo, greenhouse gases, and other factors in the Earth's energy budget.[4] Over time, a sustained imbalance in the budget enables a net flow of heat either into or out of ocean depth via thermal conduction, downwelling, and upwelling.[10][11]

Diagram showing some of the effects of climate change on oceans [12]

Oceans are Earth's largest thermal reservoir that function to regulate the planet's climate; acting as both a sink and a source of energy.[13] Releases of OHC to the atmosphere occur primarily via evaporation and enable the planetary water cycle.[14] Concentrated releases in association with high sea-surface temperatures help drive tropical cyclones, atmospheric rivers, atmospheric heat waves and other extreme weather events that can penetrate far inland.[15][16]

The ocean also functions as a sink and source of carbon, with a role comparable to that of land regions in Earth's carbon cycle.[17][18] In accordance with the temperature dependence of Henry's law, warming surface waters are less able to absorb atmospheric gases including the growing emissions of carbon dioxide and other greenhouse gases from human activity.[19][20] Warming of the deep ocean has the further potential to melt and release some of the vast store of frozen methane hydrate deposits that have naturally accumulated there.[21] Deep-ocean warming below 2000 m has been largest in the Southern Ocean compared to other ocean basins.[22]

Warming oceans are responsible for coral bleaching[23] and contribute to the migration of marine species.[24] Marine heat waves are regions of life-threatening and persistently elevated water temperatures.[25] Redistribution of the planet's internal energy by atmospheric circulation and ocean currents produces internal climate variability, often in the form of irregular oscillations,[26] and helps to sustain the global thermohaline circulation.[27][28]

The increase in OHC accounts for 30–40% of global sea-level rise from 1900 to 2020 because of thermal expansion.[29][30] It is also an accelerator of sea ice, iceberg, and tidewater glacier melting. The resulting ice retreat has been rapid and widespread for Arctic sea ice,[31] and within northern fjords such as those of Greenland and Canada.[32] Impacts to Antarctic sea ice and the vast Antarctic ice shelves which terminate into the Southern Ocean have varied by region and are also increasing due to warming waters.[33][34] Breakup of the Thwaites Ice Shelf and its West Antarctica neighbors contributed about 10% of sea-level rise in 2020.[35][36]

Definition[edit]

Graph of different thermoclines (depth versus temperature) based on seasons and latitude

The areal density of ocean heat content between two depths is defined as a definite integral:[37][38]

where is the specific heat capacity of sea water, h2 is the lower depth, h1 is the upper depth, is the seawater density profile, and is the temperature profile. In SI units, has units of Joules per square metre (J·m−2).

In practice, the integral can be approximated by summation of a smooth and otherwise well-behaved sequence of temperature and density data. Seawater density is a function of temperature, salinity, and pressure. Despite the cold and great pressure at ocean depth, water is nearly incompressible and favors the liquid state for which its density is maximized.

Measurements of temperature versus ocean depth generally show an upper mixed layer (0–200 m), a thermocline (200–1500 m), and a deep ocean layer (>1500 m). These boundary depths are only rough approximations. Sunlight penetrates to a maximum depth of about 200 m; the top 80 m of which is the habitable zone for photosynthetic marine life covering over 70% of Earth's surface.[39] Wave action and other surface turbulence help to equalize temperatures throughout the upper layer.

Global Heat Content in the top 2000 meters of the ocean since 1958[40]

Unlike surface temperatures which decrease with latitude, deep-ocean temperatures are relatively cold and uniform in most regions of the world.[41] About 50% of all ocean volume is at depths below 3000 m (1.85 miles), with the Pacific Ocean being the largest and deepest of five oceanic divisions. The thermocline is the transition between upper and deep layers in terms of temperature, nutrient flows, abundance of life, and other properties. It is semi-permanent in the tropics, variable in temperate regions (often deepest during the summer), and shallow to nonexistent in polar regions.[42]

Integrating the areal density of ocean heat over an ocean basin, or entire ocean, gives the total heat content, as indicated in the figure at left. Thus, total ocean heat content is a volume integral of the product of temperature, density, and heat capacity over the three-dimensional region of the ocean for which data is available. The bulk of measurements have been performed at depths shallower than about 2000 m (1.25 miles).[15]

Measurement networks[edit]

The global distribution of active floats in the Argo array[43]

Ocean heat content can be estimated using measurements obtained by a Nansen bottle, bathythermograph, CTD, or ocean acoustic tomography.[44] Sea surface temperatures are also measured by collections of moored and drifting buoys, such as those deployed by the Global Drifter Program and the National Data Buoy Center. The World Ocean Database Project is the largest database for temperature profiles from all of the world’s ocean.[45]

Argo is an international program of robotic profiling floats deployed globally since the start of the 21st century.[46] The program's initial 3000 units had expanded to nearly 4000 units by year 2020. At the start of each 10-day measurement cycle, a float descends to a depth of 1000 meters and drifts with the current there for nine days. It then descends to 2000 meters and measures temperature, salinity (conductivity), and depth (pressure) over a final day of ascent to the surface. At the surface the float transmits the depth profile and horizontal position data through satellite relays before repeating the cycle.[47]

A smaller test fleet of "deep Argo" floats aims to extend the measurement capability down to about 6000 meters. It will accurately sample OHC parameters for a majority of the ocean volume when fully deployed.[48][49]

Recent observations and changes[edit]

Map of the ocean heat anomaly in the upper 700 meters for year 2020 versus the 1993–2020 average.[50] Some regions accumulated more energy than others due to transport drivers such as winds and currents.

Numerous independent studies in recent years have found a multi-decadal rise in OHC of upper ocean regions that has begun to penetrate to deeper regions.[1][51] The upper ocean (0–700 m) has warmed since 1971, while it is very likely that warming has occurred at intermediate depths (700–2000 m) and likely that deep ocean (below 2000 m) temperatures have increased.[52] The heat uptake results from a persistent warming imbalance in Earth's energy budget that is most fundamentally caused by the anthropogenic increase in atmospheric greenhouse gases.[8][53] There is very high confidence that increased ocean heat content in response to anthropogenic carbon dioxide emissions is essentially irreversible on human time scales.[54]

Studies based on ARGO indicate that ocean surface winds, especially the subtropical trade winds in the Pacific Ocean, change ocean heat vertical distribution.[55] This results in changes among ocean currents, and an increase of the subtropical overturning, which is also related to the El Niño and La Niña phenomenon. Depending on stochastic natural variability fluctuations, during La Niña years around 30% more heat from the upper ocean layer is transported into the deeper ocean.

Model studies indicate that ocean currents transport more heat into deeper layers during La Niña years, following changes in wind circulation.[56][57] Years with increased ocean heat uptake have been associated with negative phases of the interdecadal Pacific oscillation (IPO).[58] This is of particular interest to climate scientists who use the data to estimate the ocean heat uptake.

A study in 2015 concluded that ocean heat content increases by the Pacific Ocean were compensated by an abrupt distribution of OHC into the Indian Ocean.[59]

The upper ocean heat content in most North Atlantic regions is dominated by heat transport convergence (a location where ocean currents meet), without large changes to temperature and salinity relation.[60]

Although the upper 2000 m of the oceans have experienced warming on average since the 1970s, the rate of ocean warming varies regionally with the subpolar North Atlantic warming more slowly and the Southern Ocean taking up a disproportionate large amount of heat due to anthropogenic greenhouse gas emissions.[61]

Tutorial gallery[edit]

  • Oceanographer Josh Willis discusses the heat capacity of water, performs an experiment to demonstrate heat capacity using a water balloon and describes how water's ability to store heat affects Earth's climate.

  • This animation uses Earth science data from a variety of sensors on NASA Earth observing satellites to measure physical oceanography parameters such as ocean currents, ocean winds, sea surface height and sea surface temperature. These measurements can help scientists understand the ocean's impact on weather and climate. (in HD)

See also[edit]

References[edit]

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  51. ^ Abraham; et al. (2013). "A review of global ocean temperature observations: Implications for ocean heat content estimates and climate change". Reviews of Geophysics. 51 (3): 450–483. Bibcode:2013RvGeo..51..450A. CiteSeerX 10.1.1.594.3698. doi:10.1002/rog.20022. S2CID 53350907.
  52. ^ IPCC AR6 WG1 Ch9 2021, p. 1228: …it is virtually certain that the upper ocean (0–700 m) has warmed since 1971, that ocean warming at intermediate depths (700–2000 m) is very likely since 2006, and that it is likely that ocean warming has occurred below 2000 m since 1992.
  53. ^ IPCC AR6 WG1 TS 2021, p. 41: It is unequivocal that the increase of CO 2 , methane (CH 4 ) and nitrous oxide (N 2 O) in the atmosphere over the industrial era is the result of human activities and that human influence is the main driver of many changes observed across the atmosphere, ocean, cryosphere and biosphere.
  54. ^ IPCC AR6 WG1 Ch9 2021, p. 1233: In summary, there is very high confidence that there is a long-term commitment to increased OHC in response to anthropogenic CO 2 emissions, which is essentially irreversible on human time scales.
  55. ^ Balmaseda, Trenberth & Källén (2013). "Distinctive climate signals in reanalysis of global ocean heat content". Geophysical Research Letters. 40 (9): 1754–1759. Bibcode:2013GeoRL..40.1754B. doi:10.1002/grl.50382. Essay Archived 2015-02-13 at the Wayback Machine
  56. ^ Meehl; et al. (2011). "Model-based evidence of deep-ocean heat uptake during surface-temperature hiatus periods". Nature Climate Change. 1 (7): 360–364. Bibcode:2011NatCC...1..360M. doi:10.1038/nclimate1229.
  57. ^ Rob Painting (2 October 2011). "The Deep Ocean Warms When Global Surface Temperatures Stall". SkepticalScience.com. Retrieved 15 July 2016.
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  59. ^ Sang-Ki Lee, Wonsun Park, Molly O. Baringer, Arnold L. Gordon, Bruce Huber & Yanyun Liu (18 May 2015). "Pacific origin of the abrupt increase in Indian Ocean heat content during the warming hiatus" (PDF). Nature Geoscience. 8 (6): 445–449. Bibcode:2015NatGe...8..445L. doi:10.1038/ngeo2438. hdl:1834/9681.{{cite journal}}: CS1 maint: uses authors parameter (link)
  60. ^ Sirpa Häkkinen, Peter B Rhines, and Denise L Worthen (2015). "Heat content variability in the North Atlantic Ocean in ocean reanalyses". Geophys Res Lett. 42 (8): 2901–2909. Bibcode:2015GeoRL..42.2901H. doi:10.1002/2015GL063299. PMC 4681455. PMID 26709321.{{cite journal}}: CS1 maint: uses authors parameter (link)
  61. ^ IPCC AR6 WG1 Ch9 2021, p. 1230: In summary, in the upper 2000 m since the 1970s, the subpolar North Atlantic has been slowly warming, and the Southern Ocean has stored a disproportionally large amount of anthropogenic heat (medium confidence).

Additional bibliography for cited sources[edit]

IPCC reports[edit]

Special Report on the Ocean and Cryosphere in a Changing Climate[edit]

AR6 Working Group I Report[edit]

External links[edit]

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