Terrestrial biological carbon cycle

The carbon cycle is an essential part of life on Earth. About half the dry weight of most living organisms is carbon. It plays an important role in the structure, biochemistry, and nutrition of all living cells. Living biomass holds about 550 gigatons of carbon[1], most of which is made of terrestrial plants (wood), while some 1,200 gigatons of carbon are stored in the terrestrial biosphere as dead biomass.[2]

Carbon is cycled through the terrestrial biosphere with varying speeds, depending on what form it is stored in and under which circumstances.[3] It is exchanged most quickly with the atmosphere, although small amounts of carbon leave the terrestrial biosphere and enter the oceans as dissolved organic carbon (DOC).

Movement of carbon in the terrestrial biosphere

Most carbon in the terrestrial biosphere is stored in forests: they hold 86% of the planet's terrestrial above-ground carbon and forest soils also hold 73% of the planet's soil carbon.[4] Carbon stored inside plants can be transferred into other organisms during plant consumption. When animals eat plants, for example, the organic carbon stored in the plants is converted into other forms and utilized inside the animals. The same is true for bacteria and other heterotrophs. Dead plant material in or above soils remains there for some time before being respired by heterotrophs. Thus carbon is transferred in every step of the food chain from one organism to another.

Carbon exchange between the terrestrial biosphere and other systems

Atmosphere

Interconnection between carbon, hydrogen and oxygen cycle in metabolism of photosynthesizing plants

Autotrophs, such as trees and other green plants, use photosynthesis to convert carbon dioxide during primary production, releasing oxygen in the process. This process occurs most quickly in ecosystems with high amounts of growth, such as in young forests. Because carbon is consumed in the process of autotrophic growth, more carbon is consumed in spring and summer during daytime than in winter and at night, when photosynthesis no longer takes place in most plants. Carbon storage in the biosphere is influenced by a number of processes on different time-scales: while carbon uptake through autotrophic respiration follows a diurnal and seasonal cycle, carbon can be stored in the terrestrial biosphere for up to several centuries, e.g. in wood or soil.

Most carbon leaves the terrestrial biosphere through respiration. When oxygen is present, aerobic respiration occurs, producing carbon dioxide. If oxygen is not present, e.g. as is the case in marshes or in animals' digestive tracts, anaerobic respiration can occur, which produces methane. About half of the gross primary production is respired by plants directly back into the atmosphere. Part of the net primary production, or the remaining carbon absorbed by the biosphere, is emitted back into the atmosphere through fires and heterotrophic respiration. The rest is converted into soil organic carbon, which is released more slowly, or "inert" dissolved carbon, which can remain in the biosphere for an unknown period of time.[3]

Geosphere

Carbon in the terrestrial biosphere enters the geosphere only through highly specialized processes. When anaerobic decomposition converts organic material into hydrocarbon rich materials and is then deposited as sediment, the carbon can enter the geosphere through tectonic processes and remain there for several million years. This process can lead to the creation of fossil fuels.

Anthropogenic influences

Human activity has large effects on the terrestrial biosphere, changing the way that it acts as a carbon reservoir. Anthropogenically caused fires release large amounts of carbon as CO2 directly into the atmosphere. More significantly, however, humans modify land cover. Land cover change greatly decreases the amount of carbon uptake in the terrestrial biosphere. It modifies the local ecosystem, often replacing carbon-rich forest with agricultural or urban land use. This releases the carbon stored in the former land cover type and simultaneously decreases the biosphere's ability to absorb carbon from the atmosphere.

Indirectly, human-induced changes in the global climate cause widespread modifications to the terrestrial ecosystem's function in the carbon cycle. As local climates transition, locations that have long been conducive to one type of ecosystem can become more favorable for other ecosystem types. For example, warming in the Arctic has caused stress in North American boreal forests,[5] thus decreasing primary production and carbon uptake, while the same warmer temperatures have led to increased shrub growth in the same areas,[6] producing an opposite effect. Changes in weather patterns can also affect animals. For example, changed weather patterns may create favorable conditions for pine beetles, leading to large beetle outbreaks and forest destruction.[7] Modified precipitation patterns can also lead to droughts or extreme precipitation events, causing additional stress for ecosystems and more erosion. Not only do such influences on the terrestrial ecosystem modify its carbon exchange with the atmosphere - they also can lead to increased outwashing of carbon into the oceans through the transport of organic material in rivers. These widespread changes in land cover also causes changes to the planetary albedo, inducing complex feedbacks in the Earth's planetary radiation budget.

Higher CO2 levels in the atmosphere can cause photosynthesis to take place more efficiently, thus increasing plant growth and primary production. This could lead to the biosphere extracting more carbon dioxide from the atmosphere. How long this carbon would remain sequestered in the terrestrial biosphere before being rereleased into the atmosphere is unclear, however, and it is likely that other limiting factors (e.g. nitrogen availability, moisture, etc.) would prevent CO2 fertilization from significantly increasing primary production.

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References

  1. Bar-On YM, Phillips R, Milo R (June 2018). "The biomass distribution on Earth". Proceedings of the National Academy of Sciences of the United States of America. 115 (25): 6506–6511. doi:10.1073/pnas.1711842115. PMC 6016768. PMID 29784790.
  2. Falkowski P, Scholes RJ, Boyle E, Canadell J, Canfield D, Elser J, Gruber N, Hibbard K, Högberg P, Linder S, Mackenzie FT, Moore B, Pedersen T, Rosenthal Y, Seitzinger S, Smetacek V, Steffen W (October 2000). "The global carbon cycle: a test of our knowledge of earth as a system". Science. 290 (5490): 291–6. Bibcode:2000Sci...290..291F. doi:10.1126/science.290.5490.291. PMID 11030643.
  3. Prentice, I.C. (2001). "The carbon cycle and atmospheric carbon dioxide". Climate change 2001: the scientific basis: contribution of Working Group I to the Third Assessment Report of the Intergouvernmental Panel on Climate Change / Houghton, J.T. [edit.] Retrieved 31 May 2012.
  4. Sedjo, Roger (October 1993). "The carbon cycle and global forest ecosystem". Water, Air, and Soil Pollution. 70: 295–307. doi:10.1007/BF01105003.
  5. Verbyla, D. (2011). "Browning boreal forests of western North America". Environmental Research Letters. 6 (4): 041003. Bibcode:2011ERL.....6d1003V. doi:10.1088/1748-9326/6/4/041003.
  6. Loranty MM, Goetz SJ (2012). "Shrub expansion and climate feedbacks in Arctic tundra". Environmental Research Letters. 7 (1): 011005. Bibcode:2012ERL.....7a1005L. doi:10.1088/1748-9326/7/1/011005.
  7. Sambaraju KR, Carroll AL, Zhu J, Stahl K, Moore RD, Aukema BH (2012). "Climate change could alter the distribution of mountain pine beetle outbreaks in western Canada". Ecography. 35 (3): 211–223. doi:10.1111/j.1600-0587.2011.06847.x.

See also

Deep Carbon Observatory

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