Carbon sink explained

A carbon sink is a natural or artificial carbon sequestration process that "removes a greenhouse gas, an aerosol or a precursor of a greenhouse gas from the atmosphere". These sinks form an important part of the natural carbon cycle. An overarching term is carbon pool, which is all the places where carbon on Earth can be, i.e. the atmosphere, oceans, soil, florae, fossil fuel reservoirs and so forth. A carbon sink is a type of carbon pool that has the capability to take up more carbon from the atmosphere than it releases.

Globally, the two most important carbon sinks are vegetation and the ocean.[1] Soil is an important carbon storage medium. Much of the organic carbon retained in the soil of agricultural areas has been depleted due to intensive farming. Blue carbon designates carbon that is fixed via certain marine ecosystems. Coastal blue carbon includes mangroves, salt marshes and seagrasses. These make up a majority of ocean plant life and store large quantities of carbon. Deep blue carbon is located in international waters and includes carbon contained in "continental shelf waters, deep-sea waters and the sea floor beneath them".[2]

For climate change mitigation purposes, the enhancement of natural carbon sinks, mainly soils and forests, is important.[3] In the past, human practices like deforestation and industrial agriculture have depleted natural carbon sinks. This kind of land use change has been one of the causes of climate change.

Definition

In the context of climate change and in particular mitigation, a sink is defined as "Any process, activity or mechanism which removes a greenhouse gas, an aerosol or a precursor of a greenhouse gas from the atmosphere".[4]

In the case of non- greenhouse gases, sinks need not store the gas. Instead they can break it down into substances that have a reduced effect on global warming. For example, nitrous oxide can be reduced to harmless N2.[5] [6]

Related terms are "carbon pool, reservoir, sequestration, source and uptake". The same publication defines carbon pool as "a  reservoir in the Earth system where elements, such as carbon [...], reside in various chemical forms for a period of time."

Both carbon pools and carbon sinks are important concepts in understanding the carbon cycle, but they refer to slightly different things. A carbon pool can be thought of as the overarching term, and carbon sink is then a particular type of carbon pool: A carbon pool is all the places where carbon can be stored (for example the atmosphere, oceans, soil, plants, and fossil fuels).

Types

The amount of carbon dioxide varies naturally in a dynamic equilibrium with photosynthesis of land plants. The natural carbon sinks are:

Artificial carbon sinks are those that store carbon in building materials or deep underground (geologic carbon sequestration).[8] [9] No major artificial systems remove carbon from the atmosphere on a large scale yet.[10]

Public awareness of the significance of sinks has grown since passage of the 1997 Kyoto Protocol, which promotes their use as a form of carbon offset.[11]

Natural carbon sinks

See main article: Carbon sequestration.

Soils

Soils represent a short to long-term carbon storage medium, and contain more carbon than all terrestrial vegetation and the atmosphere combined.[12] [13] [14] Plant litter and other biomass including charcoal accumulates as organic matter in soils, and is degraded by chemical weathering and biological degradation. More recalcitrant organic carbon polymers such as cellulose, hemi-cellulose, lignin, aliphatic compounds, waxes and terpenoids are collectively retained as humus.[15]

Organic matter tends to accumulate in litter and soils of colder regions such as the boreal forests of North America and the Taiga of Russia. Leaf litter and humus are rapidly oxidized and poorly retained in sub-tropical and tropical climate conditions due to high temperatures and extensive leaching by rainfall. Areas where shifting cultivation or slash and burn agriculture are practiced are generally only fertile for two to three years before they are abandoned. These tropical jungles are similar to coral reefs in that they are highly efficient at conserving and circulating necessary nutrients, which explains their lushness in a nutrient desert.[16]

Grasslands contribute to soil organic matter, stored mainly in their extensive fibrous root mats. Due in part to the climatic conditions of these regions (e.g. cooler temperatures and semi-arid to arid conditions), these soils can accumulate significant quantities of organic matter. This can vary based on rainfall, the length of the winter season, and the frequency of naturally occurring lightning-induced grass-fires. While these fires release carbon dioxide, they improve the quality of the grasslands overall, in turn increasing the amount of carbon retained in the humic material. They also deposit carbon directly to the soil in the form of biochar that does not significantly degrade back to carbon dioxide.[17]

Much organic carbon retained in many agricultural areas worldwide has been severely depleted due to intensive farming practices.[18] Since the 1850s, a large proportion of the world's grasslands have been tilled and converted to croplands, allowing the rapid oxidation of large quantities of soil organic carbon. Methods that significantly enhance carbon sequestration in soil are called carbon farming. They include for example no-till farming, residue mulching, cover cropping, and crop rotation.

Deep ocean, tidal marshes, mangroves and seagrasses

Enhancing natural carbon sinks

See main article: Carbon sequestration.

Carbon sequestration techniques in oceans

To enhance carbon sequestration processes in oceans the following technologies have been proposed but none have achieved large scale application so far: Seaweed farming, ocean fertilisation, artificial upwelling, basalt storage, mineralization and deep sea sediments, adding bases to neutralize acids. The idea of direct deep-sea carbon dioxide injection has been abandoned.[19]

Artificial carbon sinks

Wooden buildings

See also: Green building and wood. Broad-base adoption of mass timber and their role in substituting steel and concrete in new mid-rise construction projects over the next few decades has the potential to turn timber buildings into carbon sinks, as they store the carbon dioxide taken up from the air by trees that are harvested and used as mass timber.[8] This could result in storing between 10 million tons of carbon per year in the lowest scenario and close to 700 million tons in the highest scenario. For this to happen, the harvested forests would need to be sustainably managed and wood from demolished timber buildings would need to be reused or preserved on land in various forms.[8]

See also

Notes and References

  1. Web site: 2020-03-26. Carbon Sources and Sinks. live. 2021-06-18. National Geographic Society. en. https://web.archive.org/web/20201214082221/https://www.nationalgeographic.org/encyclopedia/carbon-sources-and-sinks/ . 14 December 2020 .
  2. Web site: The ocean – the world's greatest ally against climate change . 2023-04-27 . United Nations . en.
  3. Binkley . Clark S. . Brand . David . Harkin . Zoe . Bull . Gary . Ravindranath . N. H. . Obersteiner . Michael . Nilsson . Sten . Yamagata . Yoshiki . Krott . Max . 2002-05-01 . Carbon sink by the forest sector—options and needs for implementation . Forest Policy and Economics . 4 . 1 . 65–77 . 10.1016/S1389-9341(02)00005-9 . 1389-9341.
  4. IPCC, 2021: Annex VII: Glossary [Matthews, J.B.R., V. Möller, R. van Diemen, J.S. Fuglestvedt, V. Masson-Delmotte, C.  Méndez, S. Semenov, A. Reisinger (eds.)]. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 2215–2256, doi:10.1017/9781009157896.022.
  5. CHAPUIS-LARDY L, WRAGE N, CHOTTE J, BERNOUX M . Soils, a sink for N2O? A review . . 13. 1–17 . 2007 . 1 . 10.1111/j.1365-2486.2006.01280.x . 2007GCBio..13....1C . 86551302 .
  6. Cobo S, Negri V, Valente A, Reiner D, Hamelin L, Dowell N, Guillén-Gosálbez G . Sustainable scale-up of negative emissions technologies and practices: where to focus . . 2023 . 18 . 2 . 023001 . 10.1088/1748-9326/acacb3 . 2023ERL....18b3001C . 254915878 . 20.500.11850/596686 . free .
  7. Blakemore, R.J. . Non-Flat Earth Recalibrated for Terrain and Topsoil . Soil Systems . 2 . 4 . 64 . 2018 . 10.3390/soilsystems2040064 . free .
  8. Churkina . Galina . Organschi . Alan . Reyer . Christopher P. O. . Ruff . Andrew . Vinke . Kira . Liu . Zhu . Reck . Barbara K. . Graedel . T. E. . Schellnhuber . Hans Joachim . 2020 . Buildings as a global carbon sink . Nature Sustainability . en . 3 . 4 . 269–276 . 2020NatSu...3..269C . 10.1038/s41893-019-0462-4 . 2398-9629 . 213032074.
  9. Web site: carbon sequestration Definition, Methods, & Climate Change . 2021-06-18 . Encyclopedia Britannica . en.
  10. Web site: Carbon Sinks: A Brief Review. 2020-12-02. Earth.Org - Past Present Future. en-GB.
  11. Web site: carbon sink — European Environment Agency . 2021-06-18 . www.eea.europa.eu . en.
  12. Soil Science . 166 . 11 . 858–71 . Swift . Roger S. . Sequestration of Carbon by soil . November 2001 . 10.1097/00010694-200111000-00010 . 2001SoilS.166..858S . 96820247 .
  13. Batjes . N.H. . 1996 . Total carbon and nitrogen in the soils of the world . European Journal of Soil Science . en . 47 . 2 . 151–163 . 10.1111/j.1365-2389.1996.tb01386.x . 1996EuJSS..47..151B . 1351-0754.
  14. Batjes . N.H. . 2016 . Harmonized soil property values for broad-scale modelling (WISE30sec) with estimates of global soil carbon stocks . Geoderma . en . 269 . 61–68 . 10.1016/j.geoderma.2016.01.034. 2016Geode.269...61B .
  15. Klaus Lorenza . Rattan Lala . Caroline M. Prestonb . Klaas G.J. Nieropc . Strengthening the soil organic carbon pool by increasing contributions from recalcitrant aliphatic bio(macro)molecules . Geoderma . 142 . 1–2 . 1–10 . 15 November 2007 . 10.1016/j.geoderma.2007.07.013 . 2007Geode.142....1L .
  16. Web site: 19 Sep 2021 . Coral Reefs Biome "Underwater Rainforests" .
  17. Woolf. Dominic. Amonette. James E.. Street-Perrott. F. Alayne. Lehmann. Johannes. Joseph. Stephen. 2010-08-10. Sustainable biochar to mitigate global climate change. Nature Communications. en. 1. 5. 56. 10.1038/ncomms1053. 2041-1723. 2964457. 20975722. 2010NatCo...1...56W.
  18. Web site: 17 October 2009 . Organic Farming Can Cool the World that Chemical Farming Overheated . 18 Sep 2021.
  19. Benson . S.M. . Surles . T. . 2006-10-01 . Carbon Dioxide Capture and Storage: An Overview With Emphasis on Capture and Storage in Deep Geological Formations . live . Proceedings of the IEEE . 94 . 10 . 1795–1805 . 10.1109/JPROC.2006.883718 . 0018-9219 . https://web.archive.org/web/20200611063420/https://zenodo.org/record/1232299 . June 11, 2020 . September 10, 2019 . 27994746.

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