Evergreen

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This article is about plant types. For other uses, see Evergreen (disambiguation).
A silver fir shoot showing three successive years of retained leaves.

In botany, an evergreen is a plant which has foliage that remains green and functional through more than one growing season. This also pertains to plants that retain their foliage only in warm climates, and contrasts with deciduous plants, which completely lose their foliage during the winter or dry season.

Evergreen species[]

There are many different kinds of evergreen plants, both trees and shrubs. Evergreens include:

The Latin binomial term sempervirens, meaning "always green", refers to the evergreen nature of the plant, for instance

Cupressus sempervirens (a cypress)
Lonicera sempervirens (a honeysuckle)
Sequoia sempervirens (a sequoia)

Leaf longevity in evergreen plants varies from a few months to several decades (over thirty years in the Great Basin Bristlecone Pine[1]).

Evergreen families[]

Family name Example
Araucariaceae Kauri
Cupressaceae Sequoia
Pinaceae Pine
Podocarpaceae Real yellowwood
Taxaceae Yew
Cyatheaceae Australian tree fern
Aquifoliaceae Holly
Fagaceae Live oak
Oleaceae Shamel ash
Myrtaceae Eucalyptus
Arecaceae Coconut
Lauraceae Bay
Magnoliaceae Southern magnolia
Cycadaceae Queen sago

Japanese umbrella pine is unique in that it has its own family of which it is the only species.

Differences between evergreen and deciduous species[]

Evergreen and deciduous species vary in a range of morphological and physiological characters. Generally, broad-leaved evergreen species have thicker leaves than deciduous species, with a larger volume of parenchyma and air spaces per unit leaf area.[2] They have larger leaf biomass per unit leaf area, and hence a lower specific leaf area. Construction costs do not differ between the groups. Evergreens have generally a larger fraction of total plant biomass present as leaves (LMF),[3] but they often have a lower rate of photosynthesis.

Reasons for being evergreen or deciduous[]

A southern live oak in South Carolina during winter

Deciduous trees shed their leaves usually as an adaptation to a cold or dry/wet season. Evergreen trees do lose leaves, but each tree loses its leaves gradually and not all at once. Most tropical rainforest plants are considered to be evergreens, replacing their leaves gradually throughout the year as the leaves age and fall, whereas species growing in seasonally arid climates may be either evergreen or deciduous. Most warm temperate climate plants are also evergreen. In cool temperate climates, fewer plants are evergreen. In this climate, there is a predominance of conifers because few evergreen broadleaf plants can tolerate severe cold below about −26 °C (−15 °F).

In areas where there is a reason for being deciduous, e.g. a cold season or dry season, evergreen plants are usually an adaptation of low nutrient levels. Additionally, they are usually sclerophyllous,(meaning hard-leaved) and have an excellent water economy due to scarce resources in the area in which they reside.[4] The excellent water economy within the evergreen species is due to high abundance when compared to deciduous species.[5] Whereas, deciduous trees lose nutrients whenever they lose their leaves. In warmer areas, species such as some pines and cypresses grow on poor soils and disturbed ground. In Rhododendron, a genus with many broadleaf evergreens, several species grow in mature forests but are usually found on highly acidic soil where the nutrients are less available to plants. In taiga or boreal forests, it is too cold for the organic matter in the soil to decay rapidly, so the nutrients in the soil are less easily available to plants, thus favoring evergreens.

In temperate climates, evergreens can reinforce their own survival; evergreen leaf and needle litter has a higher carbon-nitrogen ratio than deciduous leaf litter, contributing to a higher soil acidity and lower soil nitrogen content. This is the case with Mediterranean evergreen seedlings, which have unique C and N storages that allow stored resources to determine fast growth within the species, limiting competition and bolstering survival.[6] These conditions favor the growth of more evergreens and make it more difficult for deciduous plants to persist. In addition, the shelter provided by existing evergreen plants can make it easier for younger evergreen plants to survive cold and/or drought.[7][8][9]

Threats to evergreens[]

A major threat to evergreen trees is the fungus Rhizosphere kalkhoffii, which causes the commonly green needles to appear brown or purple in color.[10] This disease is called needle cast disease, and is widespread in Minnesota and other US states.[11] This fungi spreads through splashing water to adjacent trees and needles. It has been found that needle infection occur at an average temperature of 25 degrees Celsius.[12] Some particular trees are in fact resistant to the disease, such as Plant Norway (P. abides) or white spruce (P. glaucid), while others such as Colorado blue spruce (Pica pungent) are extremely at risk of contracting the disease.[13] Preventative efforts to protect the evergreens include fungicide, mulch at the base of the tree and increased sprinkler control to prevent the water contamination.[14] Within recent years, this detrimental disease has entered into Canada and provides challenges for commercial conifer tree growers (such as Christmas trees), and extensive research was conducted into possible fungicides for this disease with no clear cut option being presented.[15] Therefore the future research regarding evergreen longevity is highly linked to additional counter measures to Rhizosphere kalkhoffii by looking at other fungicide potions.[15]

See also[]

  • Semi-deciduous (semi-evergreen)

References[]

  1. ^ Ewers, F. W. & Schmid, R. (1981). "Longevity of needle fascicles of Pinus longaeva (Bristlecone Pine) and other North American pines". Oecologia 51: 107–115
  2. ^ Villar, Rafael; Ruiz-Robleto, Jeannete; Ubera, José Luis; Poorter, Hendrik (October 2013). "Exploring variation in leaf mass per area (LMA) from leaf to cell: An anatomical analysis of 26 woody species". American Journal of Botany. 100 (10): 1969–1980. doi:10.3732/ajb.1200562. PMID 24107583.
  3. ^ Poorter, Hendrik; Jagodzinski, Andrzej M.; Ruiz-Peinado, Ricardo; Kuyah, Shem; Luo, Yunjian; Oleksyn, Jacek; Usoltsev, Vladimir A.; Buckley, Thomas N.; Reich, Peter B.; Sack, Lawren (2015). "How does biomass distribution change with size and differ among species? An analysis for 1200 plant species from five continents". New Phytologist. 208 (3): 736–749. doi:10.1111/nph.13571. PMC 5034769. PMID 26197869.
  4. ^ Álvarez-Yépiz, Juan C.; Búrquez, Alberto; Martínez-Yrízar, Angelina; Teece, Mark; Yépez, Enrico A.; Dovciak, Martin (2017-02-01). "Resource partitioning by evergreen and deciduous species in a tropical dry forest". Oecologia. 183 (2): 607–618. Bibcode:2017Oecol.183..607A. doi:10.1007/s00442-016-3790-3. ISSN 1432-1939. PMID 27915413. S2CID 3798020.
  5. ^ Álvarez-Yépiz, Juan C.; Búrquez, Alberto; Martínez-Yrízar, Angelina; Teece, Mark; Yépez, Enrico A.; Dovciak, Martin (2017-02-01). "Resource partitioning by evergreen and deciduous species in a tropical dry forest". Oecologia. 183 (2): 607–618. Bibcode:2017Oecol.183..607A. doi:10.1007/s00442-016-3790-3. ISSN 1432-1939. PMID 27915413. S2CID 3798020.
  6. ^ Uscola, Mercedes; Villar-Salvador, Pedro; Gross, Patrick; Maillard, Pascale (2015-05-01). "Fast growth involves high dependence on stored resources in seedlings of Mediterranean evergreen trees". Annals of Botany. 115 (6): 1001–1013. doi:10.1093/aob/mcv019. ISSN 0305-7364. PMC 4407060. PMID 25817313.
  7. ^ Aerts, R. (1995). "The advantages of being evergreen". Trends in Ecology & Evolution 10 (10): 402–407.
  8. ^ Matyssek, R. (1986) "Carbon, water and nitrogen relations in evergreen and deciduous conifers". Tree Physiology 2: 177–187.
  9. ^ Sobrado, M. A. (1991) "Cost-Benefit Relationships in Deciduous and Evergreen Leaves of Tropical Dry Forest Species". Functional Ecology 5 (5): 608–616.
  10. ^ "Rhizosphere needle cast". extension.umn.edu. Retrieved 2021-02-16.
  11. ^ "Rhizosphere needle cast". extension.umn.edu. Retrieved 2021-02-16.
  12. ^ "Rhizosphere needle cast". extension.umn.edu. Retrieved 2021-02-16.
  13. ^ "Rhizosphere needle cast". extension.umn.edu. Retrieved 2021-02-16.
  14. ^ "Rhizosphere needle cast". extension.umn.edu. Retrieved 2021-02-16.
  15. ^ a b "Screening of fungicides for needlecraft diseases on conifers". Agriculture and Agri-Food Canada. 2018-10-12. Retrieved 2021-02-16.

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