User:Eleios/Minerotrophic
Minerotrophic refers to environments that receive nutrients primarily through groundwater that flows through mineral-rich soils or rock[1], or surface water flowing over land[2]. Minerotrophic, “minerogenous”, and “geogenous” are now often used interchangeably, although the latter two terms refer primarily to hydrological systems, while the former refers to nutrient dynamics[3]. The hydrologic process behind minerotrophic wetlands results in water that has acquired dissolved chemicals which raise the nutrient levels and reduce the acidity[3]. This in turn affects vegetation assemblages and diversity in the wetland in question[4]. If dissolved chemicals include chemical bases such as calcium or magnesium ions, the water is referred to as base-rich and is neutral or alkaline[3]. In contrast to minerotrophic environments, ombrotrophic environments get their water mainly from precipitation, and so are very low in nutrients and more acidic[5]. Of the various wetland types, fens and rich fens are often minerotrophic while poor fens and bogs are often ombrotrophic[1]. Marshes and swamps may also be fed through groundwater sources to a degree [6].
Hydrology
[edit]The hydrological setting of a wetland strongly influences its characteristics[4]. Chemical ions are transported to wetlands via their hydrological system, and in turn affect pH, conductivity, and nutrient levels[7]. Chemical and nutrient dynamics may differ depending on a minerotrophic wetland’s hydrological setting, which could include water discharge dominated, recharge dominated, or some combination of both[4]. These characteristics also vary seasonally, as average groundwater levels increase and decrease at different times of the year[8]. This seasonality can raise water below ground or above the surface to become free standing[9]. Additional factors such as geological conditions, soil type, and surface morphology may also influence the characteristics of a wetland in tandem with hydrological setting[4].
Vegetation Communities
[edit]Stable water and nutrient availability via groundwater systems allows for a diverse array of plant species to grown in minerotrophic wetlands[4]. This also allows for peat to accumulate provided the water does not flow too quickly[4]. A minerotrophic wetland may be alkaline or weakly acidic, which also influences vegetation communities[6]. Rich fens are often characterized by alkaline hydrologic conditions, allowing for more plant diversity[6]. These areas may be dominated by brown mosses of the family Amblystegiaceae and sedges in the genus Carex[6]. Acidic poor fens are often dominated by peat mosses of the genus Sphagnum which tend to further increase acidity[6].
Examples
[edit]A notable example of a minerotrophic wetland is the Everglades, a large subtropical wetland located in Western Florida, USA[10].
See also
[edit]References
[edit]- ^ a b Environment Canada (2014). Ontario wetland evaluation system: Northern Manual, 1st edition, version 3.2. Queen’s printer for Ontario.
- ^ Wang, Meng; Tian, Jianqing; Bu, Zhaojun; Lamit, Louis J.; Chen, Huai; Zhu, Qiuan; Peng, Changhui (2019-04-01). "Structural and functional differentiation of the microbial community in the surface and subsurface peat of two minerotrophic fens in China". Plant and Soil. 437 (1): 21–40. doi:10.1007/s11104-019-03962-w. ISSN 1573-5036.
- ^ a b c Rydin, Håkan (2006). The biology of peatlands. J. K. Jeglum, Aljosja Hooijer. Oxford: Oxford University Press. ISBN 978-1-4294-6992-0. OCLC 137237177.
- ^ a b c d e f Brinson, M. M. (1993). A Hydrogeomorphic Classification for Wetlands. Environmental Laboratory (U.S.) & Engineer Research and Development Center (U.S.). Retrieved from https://erdc-library.erdc.dren.mil/jspui/bitstream/11681/6483/1/TR-WRP-DE-4.pdf
- ^ Pakarinen, P. (1995), "Classification of boreal mires in Finland and Scandinavia: A review", Classification and Inventory of the World’s Wetlands, Dordrecht: Springer Netherlands, pp. 29–38, ISBN 978-94-010-4190-4, retrieved 2021-03-15
- ^ a b c d e Zoltai, S. C.; Vitt, D. H. (1995), "Canadian wetlands: Environmental gradients and classification", Classification and Inventory of the World’s Wetlands, Dordrecht: Springer Netherlands, pp. 131–137, ISBN 978-94-010-4190-4, retrieved 2021-03-15
- ^ Vitt, Dale H.; Chee, Wai-Lin (1990). "The relationships of vegetation to surface water chemistry and peat chemistry in fens of Alberta, Canada". Vegetatio. 89 (2): 87–106. doi:10.1007/bf00032163. ISSN 0042-3106.
- ^ Shaffer, Paul W.; Kentula, Mary E.; Gwin, Stephanie E. (1999-09-01). "Characterization of wetland hydrology using hydrogeomorphic classification". Wetlands. 19 (3): 490–504. doi:10.1007/BF03161688. ISSN 1943-6246.
- ^ Semeniuk, C. A.; Semeniuk, V. (1995), "A geomorphic approach to global classification for inland wetlands", Classification and Inventory of the World’s Wetlands, Dordrecht: Springer Netherlands, pp. 103–124, ISBN 978-94-010-4190-4, retrieved 2021-03-15
- ^ Richardson, Curtis J. (2009-08-27). "The Everglades: North America's subtropical wetland". Wetlands Ecology and Management. 18 (5): 517–542. doi:10.1007/s11273-009-9156-4. ISSN 0923-4861.