Quercus rubra explained

Quercus rubra, the northern red oak, is an oak tree in the red oak group (Quercus section Lobatae). It is a native of North America, in the eastern and central United States and southeast and south-central Canada. It has been introduced to small areas in Western Europe, where it can frequently be seen cultivated in gardens and parks. It prefers good soil that is slightly acidic. Often simply called red oak, northern red oak is so named to distinguish it from southern red oak (Q. falcata), also known as the Spanish oak. Northern red oak is sometimes called champion oak.

Description

In many forests, Quercus rubra grows straight and tall, to 28m (92feet), exceptionally to tall, with a trunk of up to NaNcm (-2,147,483,648inches) in diameter. Open-grown trees do not get as tall, but can develop a stouter trunk, up to in diameter. It has stout branches growing at right angles to the stem, forming a narrow round-topped head.[1]

Under optimal conditions and full sun, northern red oak is fast growing and a 10-year-old tree can be tall.[2] Trees may live up to 400 years;[3] a living example of 326 years was noted in 2001.[4]

Northern red oak is easy to recognize by its bark, which features ridges that appear to have shiny stripes down the center. A few other oaks have bark with this kind of appearance in the upper tree, but the northern red oak is the only tree with the striping all the way down the trunk.

As with most other deciduous oaks, leafout takes place in spring when day length has reached 13 hours—it is tied entirely to photoperiod and will take place regardless of air temperature. As a consequence (see below), in cooler regions, northern red oaks often lose their flowers to late spring frosts, resulting in no seed crop for the year. The catkins and leaves emerge at the same time. The acorns develop on the tree for two growing seasons and are released from the tree in early October, and leaf drop begins when day length falls under 11 hours. The timing of leafout and leaf drop can vary by as much as three weeks in the northern and southern US. Seedlings emerge in spring when soil temperatures reach .

Red oak acorns, unlike the white oak group, display epigeal dormancy and will not germinate without a minimum of three months' exposure to temperatures below . They also take two years of growing on the tree before development is completed.

Distribution and habitat

The species grows from the north end of the Great Lakes, east to Nova Scotia, south as far as Georgia, Mississippi, Alabama, and Louisiana, and west to Oklahoma, Kansas, Nebraska, and Minnesota.

It grows rapidly and is tolerant of many soils and varied situations, although it prefers the glacial drift and well-drained borders of streams. In the southeastern United States, it is frequently a part of the canopy in an oak-heath forest, but generally not as important as some other oaks.[5] [6]

Northern red oak is the most common species of oak in the northeastern US after the closely related pin oak (Q. palustris). The red oak group as a whole are more abundant today than they were when European settlement of North America began as forest clearing and exploitation for lumber much reduced the population of the formerly dominant white oaks.

Reproduction

“Northern red oak (Quercus rubra) is monoecious, dichogamous, wind-pollinated, and self-incompatible”.[7] Pollination occurs in the first growing season, but fertilization and acorn maturation occur during the second growing season.[8]

Ecology

Over the last few decades, the northern red oak has dealt with several environmental factors, mainly disease, predation by insects, and limited opportunities for dispersal. These stresses have impacted the species' ability to proliferate in both the Northeast and Europe.[9] The various environmental responses observed in Quercus rubra across several temperate environmental conditions have allowed for it to serve as a model organism for studying symbiotic relationships, dispersal, and habituation between tree species.

Pests and diseases

Canker pathogen, Diplodia corticola, has become a major pathogen to the species over the last decade, causing leaf browning, bark cracking and bleeding, and high rates of tree mortality across the northeastern United States.[10] The northern red oak is also characterized as one of the most susceptible species to plant fungi Phytophthora cinnamomi and Phytophthora ramorum, which have caused severe, red-black cankers in the trunk region of the species.[11] [12] [13] Both P. cinnamomi and P. ramorum grow under warmer temperature conditions; as a result, northern red oak trees found in California, France, and northern Spain all have a higher incidence of fungal infection.[14] Oak Wilt caused by the fungus Bretziella fagacearum is a major pathogen found in eastern North America that can kill trees quickly.[15]

There has been a recent northern red oak decline in Arkansas which is “unique in that it is associated with increases in red oak borer” (Enaphalodes rufulus) which “is native to the eastern United States and usually occurs in mixed oak forests”. “It damages the phloem, sapwood, and heartwood which means the ability for growth and repair is attacked as well as the stability of the tree”.[16]

Abiotic stresses

Northern red oak seedlings have been known to have a high mortality rate in northeast regions prone to spring freeze, particularly in Massachusetts. Acorns produced by oaks in this region are typically smaller in size as an adaptation to frost produced in high latitudes; however, the resulting smaller seedlings have produced limited opportunities for animal consumption and dispersal.[17] Flooding along the continental United States has been shown to be a major issue for the northern red oak, in which decreased phloem transport and photosynthetic activity has been observed, but only after multiple days of flooding, indicating that the northern red oak has adapted moderate resistance to excess water exposure.[18] The northern red oak has also developed tolerance mechanisms for heat stress, particularly observed in deciduous forests in the Southeastern United States, where, during summer heat waves, temperatures can exceed . The leaves of the northern red oak have been observed to have an acclimation to Rubisco activase activity that is directly correlated to acclimations with repeated exposure to heat waves. Consistent photosynthetic activity in the red oak has also been observed in the presence of high carbon dioxide levels that often occur as a result of elevated temperatures.[19] [20]

Animals

Northern red oak kernels have highly concentrated amounts of bitter-tasting tannin, a biochemical classified as a predator deterrent, which has limited appeal for consumption among animals. Despite this, the acorns are eaten by deer, squirrels and birds. In Europe, the acorns are consumed by several moth species, particularly Cydia fagiglandana and Cydia splendana, which increases their niche breadths and reduces their competition with Curculio weevils.[21] Due to this, germination rates among the northern red oak acorns have decreased significantly and resulted in less seed dispersal by animals within Poland. In addition, limited opportunities for dispersal have become costly for the northern red oak in Europe. European animals known for dispersing tendencies, such as the European jay and wood mouse, have been found to be more attracted to local oak species.[22]

Fungi

Quercus rubra has effective ectomycorrhizal relationships that have been correlated with increased growth rates. Northern red oak trees have been shown to increase growth in the presence of various ascomycetes that coil at the base of the oak trunk. The fungi, which eventually proliferate at the stumps of deciduous trees, have been found to be host-specific to both Quercus rubra and Quercus montana[23] and primarily promote growth upon infection.

Invasiveness in Europe

It was introduced to Europe in the 1700s and has naturalized throughout most of western and central Europe.Across western and central Europe, the northern red oak has become the fourth-most significant invasive species, colonizing several regions across Belgium, Germany, Northern Italy, Lithuania, Poland, Ukraine, European Russia,[24] the Urals and Western Siberia). The northern red oak is primarily found on the edges of woodland reserves in Europe, where light availability, tannin concentration, and animal dispersal are the most necessary component for the species' longevity and survival.[25] The high influx of the species in Europe is primarily based on its economic productivity as a fast-growing source of timber; however, it has been linked to lower percentages of trace elements and minerals found in the surrounding soil and reduced richness among native oak species such as Quercus robur.[26] [27]

Uses

The northern red oak is one of the most important oaks for timber production in North America. Quality red oak is of high value as lumber and veneer, while defective logs are used as firewood. Other related oaks are also cut and marketed as red oak, although their wood is not always of as high a quality. These include eastern black oak, scarlet oak, pin oak, Shumard oak, southern red oak and other species in the red oak group. Construction uses include flooring, veneer, interior trim, and furniture. It is also used for lumber, railroad ties, and fence posts.

Red oak wood grain is so open that smoke can be blown through it from end-grain to end-grain on a flat-sawn board. For this reason, it is subject to moisture infiltration and is unsuitable for outdoor uses such as boatbuilding or exterior trim.

The acorns can be collected in autumn, shelled, tied up in a cloth, and leached to remove bitterness. They can then be eaten whole or ground into meal.[28]

Ornamental use

Quercus rubra is grown in parks and large gardens as a specimen tree.[29] It is not planted as often as the closely related pin oak as it develops a taproot and quickly becomes difficult to transplant, however modern growing pots have made starting seedlings with taproots easier than in the past.

Culture

It is the state tree of New Jersey and the provincial tree of Prince Edward Island.

Famous specimens

Notes and References

  1. Book: Keeler, Harriet L. . Our Native Trees and How to Identify Them . Charles Scribner's Sons . 1900 . New Roak . 349–354.
  2. http://www.arborday.org/trees/treeGuide/TreeDetail.cfm?id=20 Arbor Day Foundation, Northern Red Oak
  3. http://plants.usda.gov/plantguide/pdf/cs_quru.pdf United States Department of Agriculture Plant Guide
  4. http://people.eku.edu/pedersonn/OLDLISTeast Lamont–Doherty Earth Observatory and Columbia University, Eastern US oldlist
  5. http://www.dcr.virginia.gov/natural_heritage/ncTIIIe.shtml The Natural Communities of Virginia Classification of Ecological Community Groups (Version 2.3), Virginia Department of Conservation and Recreation, 2010
  6. Schafale, M. P. and A. S. Weakley. 1990. Classification of the natural communities of North Carolina: third approximation. North Carolina Natural Heritage Program, North Carolina Division of Parks and Recreation.
  7. Alexander, L., & Woeste, K. (2017). Pollen gene flow, male reproductive success, and genetic correlations among offspring in a northern red oak (Quercus rubra L.) seed orchard. PloS One, 12(2), e0171598–e0171598. https://doi.org/10.1371/journal.pone.0171598
  8. Cecich . Robert A. . Notes: Pollen Tube Growth in Quercus . Forest Science . February 1997 . 43 . 1 . 140–146 . 17 December 2023.
  9. Book: Mycorrhizal Symbiosis. Smith. Sally E.. Read. David J.. 2010-07-26. Academic Press. 9780080559346. en.
  10. Top. Sara M.. Preston. Caroline M.. Dukes. Jeffrey S.. Tharayil. Nishanth. 2017. Climate Influences the Content and Chemical Composition of Foliar Tannins in Green and Senesced Tissues of Quercus rubra. Frontiers in Plant Science. en. 8. 423. 10.3389/fpls.2017.00423. 28559896. 5432568. 1664-462X. free.
  11. Marĉais. B.. Dupuis. F.. Desprez-Loustau. M. L.. 1996-06-01. Susceptibility of the Quercus rubra root system to Phytophthora cinnamomi; comparison with chestnut and other oak species. European Journal of Forest Pathology. en. 26. 3. 133–143. 10.1111/j.1439-0329.1996.tb00718.x. 83704321 . 1439-0329.
  12. Bergot. Magali. 2004. Simulation of potential range expansion of oak disease caused by Phytophthora cinnamomi under climate change. Global Change Biology. 10. 9. 1539–1552. 10.1111/j.1365-2486.2004.00824.x. 2004GCBio..10.1539B. 85844009.
  13. Davidson. J. M.. Werres. S.. Garbelotto. M.. Hansen. E. M.. Rizzo. D. M.. Sudden Oak Death and Associated Diseases Caused by Phytophthora ramorum. Plant Health Progress. 4. 12. 10.1094/php-2003-0707-01-dg. 2003.
  14. Marcais. B. June 1995. Modelling the influence of winter frosts on the development of the stem canker of red oak, caused by Phytophthora cinnamomi. Annales des Sciences Forestières. 53. 2–3. 369–382. 10.1051/forest:19960219. free.
  15. Book: Sudden Oak Death. 2002. U.S. Department of Agriculture, Forest Service, State and Private Forestry, Northeastern Area. 2–.
  16. Haavik, L. J., Stephen, F. M., Fierke, M. K., Salisbury, V. B., Leavitt, S. W., & Billings, S. A. (2008). Dendrochronological parameters of northern red oak (Quercus rubra L. (Fagaceae)) infested with red oak borer (Enaphalodes rufulus (Haldeman) (Coleoptera: Cerambycidae)). Forest Ecology and Management, 255(5), 1501–1509. https://doi.org/10.1016/j.foreco.2007.11.005
  17. Aizen . Marcelo . 1996 . Effects of acorn size on seedling survival and growth in Quercus rubra following simulated sporing freeze. . Canadian Journal of Botany . 74 . 2 . 308–314 . 10.1139/b96-037.
  18. Sloan . Joshua L. . Islam . M. Anisul . Jacobs . Douglass F. . 2016-01-01 . Reduced translocation of current photosynthate precedes changes in gas exchange forQuercus rubraseedlings under flooding stress . Tree Physiology . en . 36 . 1 . 54–62 . 10.1093/treephys/tpv122 . 0829-318X . 26655380 . free.
  19. Bauweraerts . Ingvar . Ameye . Maarten . Wertin . Timothy M. . McGuire . Mary Anne . Teskey . Robert O. . Steppe . Kathy . 2014-07-01 . Acclimation effects of heat waves and elevated [CO2] on gas exchange and chlorophyll fluorescence of northern red oak (Quercus rubra L.) seedlings . Plant Ecology . en . 215 . 7 . 733–746 . 10.1007/s11258-014-0352-9 . 2014PlEco.215..733B . 1385-0237 . 14230195.
  20. Cavender-Bares . J. . Jeannine Cavender-Bares . Potts . M. . Zacharias . E. . Bazzaz . F. A. . 2000-12-01 . Consequences of CO2 and light interactions for leaf phenology, growth, and senescence in Quercus rubra . Global Change Biology . en . 6 . 8 . 877–887 . 2000GCBio...6..877C . 10.1.1.337.1253 . 10.1046/j.1365-2486.2000.00361.x . 1365-2486 . 15753586.
  21. Myczko. Łukasz. Dylewski. Łukasz. Chrzanowski. Artur. Sparks. Tim H.. 2017-08-01. Acorns of invasive Northern Red Oak (Quercus rubra) in Europe are larval hosts of moths and beetles. Biological Invasions. en. 19. 8. 2419–2425. 10.1007/s10530-017-1452-y. 2017BiInv..19.2419M . 9609205. 1387-3547.
  22. Merceron. Natalie. 2017. Removal of acorns of the alien oak Quercus rubra on the ground by scatter-hoarding animals in Belgian forests.. Biotechnology, Agronomy, Society, and Environment. 21. 127–130. 10.25518/1780-4507.13613. 90139551. free.
  23. Dickie. Ian A.. Koide. Roger T.. Steiner. Kim C.. 2002. Influences of Established Trees on Mycorrhizas, Nutrition, and Growth of Quercus rubra Seedlings. 3100054. Ecological Monographs. 72. 4. 505–521. 10.2307/3100054.
  24. Web site: Figure 1. The distribution of Q. Rubra in Europe (Based on NOBANIS data.
  25. Wagner. Viktoria. Chytrý. Milan. Jiménez-Alfaro. Borja. Pergl. Jan. Hennekens. Stephan. Biurrun. Idoia. Knollová. Ilona. Berg. Christian. Vassilev. Kiril. 2017-09-01. Alien plant invasions in European woodlands. Diversity and Distributions. en. 23. 9. 969–981. 10.1111/ddi.12592. 2017DivDi..23..969W . 1472-4642. free.
  26. Riepas. Edvardas. 2008. https://www.balticforestry.mi.lt/bf/PDF_Articles/2008-14[2/122_130%20Riepsas%20&%20Straigyte.pdf Invasiveness and ecological effects of red oak (Quercus rubra) in Lithuanian forests.]. Baltic Forestry. 14. 122–130.
  27. Woziwoda. Beata. Kopeć. Dominik. Witkowski. Janusz. 2014-03-18. The negative impact of intentionally introduced Quercus rubra L. on a forest community. Acta Societatis Botanicorum Poloniae. en. 83. 1. 39–49. 10.5586/asbp.2013.035. 2083-9480. free.
  28. Book: Elias. Thomas S.. Edible Wild Plants: A North American Field Guide to Over 200 Natural Foods. Dykeman. Peter A.. Sterling. 2009. 978-1-4027-6715-9. New York. 233. 244766414. 1982.
  29. Web site: Quercus rubra . RHS Gardening . Royal Horticultural Society . 27 June 2013.
  30. Web site: Toronto city council votes to save historic red oak . Cotterill . Madigan . 3 December 2020 . Canadian Geographic . 18 May 2021.