Jump to content

Canopy (biology)

From Wikipedia, the free encyclopedia
(Redirected from Vegetation canopy)

The canopy of a forest in Sabah, Malaysia
Canopy of tropical evergreen forest, Andaman Islands
Canopy layers of primary tropical forest, Thailand
Macrocystis pyrifera – giant kelp – forming the canopy of a kelp forest
Bamboo canopy in the Western Ghats of India
Urban canopy of Atlanta, Georgia

In biology, the canopy is the aboveground portion of a plant cropping or crop, formed by the collection of individual plant crowns.[1][2][3] In forest ecology, the canopy is the upper layer or habitat zone, formed by mature tree crowns and including other biological organisms (epiphytes, lianas, arboreal animals, etc..).[4] The communities that inhabit the canopy layer are thought to be involved in maintaining forest diversity, resilience, and functioning.[5] Shade trees normally have a dense canopy that blocks light from lower growing plants.

Observation

[edit]

Early observations of canopies were made from the ground using binoculars or by examining fallen material. Researchers would sometimes erroneously rely on extrapolation by using more reachable samples taken from the understory. In some cases, they would use unconventional methods such as chairs suspended on vines or hot-air dirigibles, among others. Modern technology, including adapted mountaineering gear, has made canopy observation significantly easier and more accurate, allowed for longer and more collaborative work, and broadened the scope of canopy study.[6]

Structure

[edit]
A monkey-ladder vine canopy over a road

Canopy structure is the organization or spatial arrangement (three-dimensional geometry) of a plant canopy. Leaf area index, leaf area per unit ground area, is a key measure used to understand and compare plant canopies. The canopy is taller than the understory layer. The canopy holds 90% of the animals in the rainforest. Canopies can cover vast distances and appear to be unbroken when observed from an airplane. However, despite overlapping tree branches, rainforest canopy trees rarely touch each other. Rather, they are usually separated by a few feet.[7]

Dominant and co-dominant canopy trees form the uneven canopy layer. Canopy trees are able to photosynthesize relatively rapidly with abundant light, so it supports the majority of primary productivity in forests. The canopy layer provides protection from strong winds and storms while also intercepting sunlight and precipitation, leading to a relatively sparsely vegetated understory layer.

Forest canopies are home to unique flora and fauna not found in other layers of forests. The highest terrestrial biodiversity resides in the canopies of tropical rainforests.[8] Many rainforest animals have evolved to live solely in the canopy and never touch the ground. The canopy of a rainforest is typically about 10 m thick, and intercepts around 95% of sunlight.[9] The canopy is below the emergent layer, a sparse layer of very tall trees, typically one or two per hectare. With an abundance of water and a near ideal temperature in rainforests, light and nutrients are two factors that limit tree growth from the understory to the canopy.

In the permaculture and forest gardening community, the canopy is the highest of seven layers.[10]

Ecology

[edit]

Forest canopies have unique structural and ecological complexities and are important for the forest ecosystem. They are involved in critical functions such as rainfall interception, light absorption, nutrient and energy cycling, gas exchange, and providing habitat for diverse wildlife.[11] The canopy also plays a role in modifying the internal environment of the forest by acting as a buffer for incoming light, wind, and temperature fluctuations.[11]

The forest canopy layer supports a diverse range of flora and fauna. It has been dubbed "the last biotic frontier" as it provides a habitat that has allowed for the evolution of countless species of plants, microorganisms, invertebrates (e.g., insects), and vertebrates (e.g., birds and mammals) that are unique to the upper layer of forests.[12] Forest canopies are arguably considered some of the most species-rich environments on the planet.[13] It is believed that the communities found within the canopy layer play an essential role in the functioning of the forest, as well as maintaining diversity and ecological resilience.[12]

Climate regulation

[edit]

Forest canopies contribute to forest microclimate by controlling and buffering variations in climatic conditions. Forest canopies intercept rain and snowfall, thereby buffering the effects of precipitation on the local climate.[14] Forest canopies also buffer the effects of temperature within forests by creating vertical light gradients.[15] Variations in forest microclimate are also driven by the structure and physiology of canopy trees and epiphytes. This produces feedback loops where the species identity, growth traits, and forest stand composition of canopy trees determine forest microclimate.[14]

Forest canopies are significantly involved in maintaining the stability of the global climate. They are responsible for at least half of the global carbon dioxide exchange between terrestrial ecosystems and the atmosphere. Forest canopies act as carbon sinks, reducing the increase of atmospheric CO2 caused by human activity. The destruction of forest canopies would lead to the release of carbon dioxide, resulting in an increased concentration of atmospheric CO2. This would then contribute to the greenhouse effect, thereby causing the planet to become warmer.[16]

Canopy interception

[edit]

Canopy interception is the rainfall that is intercepted by the canopy of a tree and successively evaporates from the leaves. Precipitation that is not intercepted will fall as throughfall or stemflow on the forest floor.

Many methods exist to measure canopy interception. The most often used method is by measuring rainfall above the canopy and subtract throughfall and stem flow[17]). However, the problem with this method is that the canopy is not homogeneous, which causes difficulty in obtaining representative throughfall data.

A method employed to avoid this problem is covering forest floor with plastic sheets and collecting the throughfall.[18][19][20] The disadvantage of this method is that it is not suitable for long periods, because in the end the trees will dry from water shortage, and the method is also not applicable for snow events.

The method by Hancock and Crowther[21] avoided these problems by making use of the cantilever effect of branches. If leaves on a branch hold water, it becomes more heavy and will bend. By measuring the displacement, it is possible to determine the amount of intercepted water. this method was refined in 2005 by making use of strain gauges.[22] However, the disadvantages of these methods are that only information about one single branch is obtained and it would be quite laborious to measure an entire tree or forest.

See also

[edit]

References

[edit]
  1. ^ Campbell, G.S.; Norman, J.M. (1989). "The description and measurement of plant canopy structure". In Russell, Graham; Marshall, Bruce; Jarvis, Paul G. (eds.). Plant Canopies: Their Growth, Form and Function. Cambridge University Press. pp. 1–19. doi:10.1017/CBO9780511752308.002. ISBN 978-0-521-39563-2. LCCN 87032902.
  2. ^ Moffett, Mark W. (December 2000). "What's "Up"? A Critical Look at the Basic Terms of Canopy Biology". Biotropica. 32 (4): 569–596. doi:10.1646/0006-3606(2000)032[0569:WSUACL]2.0.CO;2. S2CID 45947367.
  3. ^ Hay, Robert K.M.; Porter, John R. (2006). The Physiology of Crop Yield (Second ed.). Blackwell Publishing. ISBN 978-1-4051-0859-1. LCCN 2006005216.
  4. ^ Parker, Geoffrey G. (1995). "Structure and microclimate of forest canopies". In Lowman, Margaret D.; Nadkarni, Nalini M. (eds.). Forest Canopies (First ed.). Academic Press. pp. 73–106. ISBN 978-0124576506. LCCN 94041251.
  5. ^ Nadkarni, Nalini M. (February 1994). "Diversity of Species and Interactions in the Upper Tree Canopy of Forest Ecosystems". American Zoologist. 34 (1): 70–78. doi:10.1093/icb/34.1.70 – via Oxford Academic.
  6. ^ Lowman, Margaret D.; Wittman, Philip K. (1996). "Forest Canopies: Methods, Hypotheses, and Future Directions" (PDF). Annual Review of Ecology, Evolution, and Systematics. 27: 55–81. doi:10.1146/annurev.ecolsys.27.1.55. JSTOR 2097229. Archived (PDF) from the original on 7 February 2019.
  7. ^ Butler, Rhett (30 July 2012). "The Rainforest Canopy". Mongabay. Archived from the original on 5 May 2020.
  8. ^ Lowman, Margaret D.; Moffett, Mark (March 1993). "The ecology of tropical rain forest canopies" (PDF). Trends in Ecology & Evolution. 8 (3): 104–107. doi:10.1016/0169-5347(93)90061-S. PMID 21236120. Archived (PDF) from the original on 2 February 2020.
  9. ^ "Light in the Rain Forest". garden.org. Archived from the original on 23 November 2015. Retrieved 23 November 2015.
  10. ^ "The Seven Layers of a Forest". The Permaculture Research Institute. 8 March 2017. Retrieved 12 September 2023.
  11. ^ a b Forest canopies. Margaret Lowman, H. Bruce Rinker (2nd ed.). Amsterdam: Elsevier Academic Press. 2004. ISBN 978-0-12-457553-0. OCLC 162129566.{{cite book}}: CS1 maint: others (link)
  12. ^ a b Nadkarni, Nalini M.; Merwin, Mark C.; Nieder, Jurgen (1 January 2013), "Forest Canopies, Plant Diversity", in Levin, Simon A (ed.), Encyclopedia of Biodiversity (Second Edition), Waltham: Academic Press, pp. 516–527, doi:10.1016/b978-0-12-384719-5.00158-1, ISBN 978-0-12-384720-1, retrieved 26 February 2022
  13. ^ Erwin, Terry L. (1 January 2013), "Forest Canopies, Animal Diversity", in Levin, Simon A (ed.), Encyclopedia of Biodiversity (Second Edition), Waltham: Academic Press, pp. 511–515, doi:10.1016/b978-0-12-384719-5.00057-5, ISBN 978-0-12-384720-1, retrieved 26 February 2022
  14. ^ a b Nakamura, Akihiro; Kitching, Roger L.; Cao, Min; Creedy, Thomas J.; Fayle, Tom M.; Freiberg, Martin; Hewitt, C. N.; Itioka, Takao; Koh, Lian Pin; Ma, Keping; Malhi, Yadvinder (1 June 2017). "Forests and Their Canopies: Achievements and Horizons in Canopy Science". Trends in Ecology & Evolution. 32 (6): 438–451. doi:10.1016/j.tree.2017.02.020. hdl:2440/114347. ISSN 0169-5347. PMID 28359572.
  15. ^ Pfeifer, Marion; Gonsamo, Alemu; Woodgate, William; Cayuela, Luis; Marshall, Andrew R.; Ledo, Alicia; Paine, Timothy C. E.; Marchant, Rob; Burt, Andrew; Calders, Kim; Courtney-Mustaphi, Colin (8 January 2018). "Tropical forest canopies and their relationships with climate and disturbance: results from a global dataset of consistent field-based measurements". Forest Ecosystems. 5 (1): 7. doi:10.1186/s40663-017-0118-7. hdl:2164/9969. ISSN 2197-5620. S2CID 31219827.
  16. ^ Didham, R. K.; Fagan, L. L. (1 January 2004), "ECOLOGY | Forest Canopies", in Burley, Jeffery (ed.), Encyclopedia of Forest Sciences, Oxford: Elsevier, pp. 68–80, doi:10.1016/b0-12-145160-7/00013-2, ISBN 978-0-12-145160-8, retrieved 26 February 2022
  17. ^ Helvey, J. D., Patric, J. H., 1965. Canopy and litter interception of rainfall by hardwoods of Eastern United States. Water Resources Research 1 (2), 193–206.
  18. ^ Shuttleworth, W. J., Gash, J. H. C., Lloyd, C. R., Moore, C. J., Roberts, J. M., et.al, 1984. Eddy correlation measurements of energy partition for Amazonian forest. Quarterly Journal of the Royal Meteorological Society 110, 1143–1162.
  19. ^ Calder, I. R., 1986. A stochastic model of rainfall interception. Journal of Hydrology 89, 65–71.
  20. ^ Calder, I. R., 1990. Evaporation in the uplands. John Wiley & Sons.
  21. ^ Hancock, N. H., Crowther, J. M., 1979. A technique for the direct measurement of water storage on a forest canopy. Journal of Hydrology 41, 105–122.
  22. ^ Huang, Y. S., Chen, S. S., Lin, T. P., 2005. Continuous monitoring of water loading of trees and canopy rainfall interception using the strain gauge method. Journal of Hydrology 311, 1–7.

Further reading

[edit]
[edit]