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Test

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Soils that accumulate charcoal exhibit a black color. [1] [2] [3]


Vernadsky

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1[4]


2"Большая российская энциклопедия: ВЕРНА́ДСКИЙ" [The Great Russian Encyclopedia: VERNADSKY]. Archived from the original on 2021-12-08. Retrieved 2022-03-22. His theory of the role of the kaolin core and the structure of aluminosilicates formed the basis of the modern crystallography.</ref>

soil carbon sponge

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Soil carbon sponge (or soil sponge)[5] is porous, well-aggregated soil[6] in good health. Walter Jehne first articulated the concept of the soil carbon sponge in his 2017 paper Regenerate Earth[7] to draw a connection between improved soil carbon and improved water cycle.[8]

EDS cite

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Signs vary widely based on the specific EDS the person has. This group of disorders affects connective tissues, most typically in the joints, skin, and blood vessels and causes effects ranging from mildly loose joints to life-threatening complications. What can make diagnosis complicated, is cross-over symptoms. A patient diagnosed with Type 3 (Hypermobility type) can display the thin translucent skin typically found in the vascular type, and so on [9]

I know this prolly has been asked a lot, but I was wondering that with a project, is there a way to add our other classes such as List, Image, etc to our assessment. I work with the Illinois Project, and on our Assessment Page we have that list off to the right. Is there a way currently for us to add the other classes to this list so that we can keep track of them better and know what we have. If there isn't, is this something that could be created? I am sure there are other projects that would be interested in knowing this, so any help in this matter would be much appreciated. Thank you!--Kranar drogin 02:01, 14 September 2007 (UTC)

There is a new bot (User:Erwin85Bot) that counts any category you wish, with the right codes. I use it to create the following page: {{Wikipedia:WikiProject Aviation/Maintenance/Assessment}}
Article
class
Project
Aviation Aircraft Airlines Airports Military
Aviation
Aviation
accident
Rotorcraft Gliding Defunct
Airlines
Air sports Biography Aero
engine
  FA 147 19 1 4 193 17 1 1 0 1 81 2
  FL 5 0 1 1 8 1 0 0 1 2 3 0
  A 23 12 0 0 95 1 2 0 0 0 40 1
  GA 150 175 24 56 550 70 1 6 13 2 138 3
B 783 2,142 89 406 3,382 298 129 177 71 44 778 171
C 2805 4,624 224 943 7,995 637 292 398 93 370 1,156 432
Start 10811 5,841 1,082 4,707 12,379 1,008 472 631 762 348 2,003 935
Stub 17340 1,321 1,410 9,101 2,691 175 89 85 545 223 1,363 88
List 1579 444 463 596 613 147 22 13 74 6 105 10
Template 1260 1,243 277 572 819 206 24 10 6 96 22 122
Category 6053 5,661 856 1,545 3,220 1,005 94 100 433 84 488 192
Disambig 511 23 24 467 57 34 1 0 1 1 1 1
File 250 237 1,188 535 573 7 7 0 7 3 29 139
Portal 632 36 1 1 0 4 0 0 0 0 18 0
Project 45 18 12 6 4 8 1 3 5 1 1 7
Unassessed 353 31 0 6 0 0 0 0 0 0 0 1
Total 78,908 22,356 6,005 19,652 35,365 3,815 1,173 1,447 2,069 1,201 6,491 2,172

.

I also use it to create a multitude of maintenance pages, see:Wikipedia:WikiProject Aviation/Maintenance. - Trevor MacInnis (Contribs) 02:25, 22 November 2007 (UTC)

Test welcome to soil project

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Hello, Paleorthid/Sandbox, and welcome to the Soil WikiProject! I hope you will be happy helping here. You should begin by reading these pages: help, policies and guidelines, and how to write better articles. If you want some ideas of which pages to work on, read the project to to do list or the worklist.

Even though it is a good idea to research an article (like looking at the discussion page) before making large changes, please be bold and try! Any changes you make that are not perfect can be fixed later. We are also working most on soil science stubs, and creating new articles from a list of new soil science articles needed.

If you want to ask a question or talk with other members, you can visit the "village pump" at Wikipedia:Village pump. Administrators on Wikipedia can also help you with more difficult problems. You can also ask me for help. The best way to do that is to leave a message on my talk page. You should always sign your messages on Talk pages by typing "~~~~" (four tildes) at the end of your words.

Good luck and happy editing!

State Soil

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San Joaquin is an officially designated state symbol, the State Soil of California.

The California Central Valley has more than 500,000 acres of San Joaquin soils, named for the south end of that valley. This series is the oldest continuously recognized soil series within the State. It is one of California's Benchmark Soils, and a soil profile of it is displayed in the International Soil Reference and Information Centre's World Soil Museum.

The San Joaquin series became the Official State Soil on August 20 1997,[10] the result of efforts by students and teachers from Martin Luther King, Jr. Middle School in Madera, natural resource professionals, the Professional Soil Scientists Association of California, legislators, and various state universities.

These soils are used for irrigated crops, such as wheat, rice, figs, almonds, orangess, and grapes, and for pasture and urban development. San Joaquin soils formed in old alluvium on hummocky topography. A cemented hardpan a few feet beneath the surface restricts roots and water percolation.[11]

San Joaquin soils are classified in USDA soil taxonomy as fine, mixed, active, thermic Abruptic Durixeralfs [12]

San Joaquin Soil Profile

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  • Surface layer: brown loam
  • Subsoil - upper: brown loam
  • Subsoil - lower: brown clay
  • Substratum: light brown and brown, indurated duripan with 70 to 90 percent silica-sesquioxide cementation

See also

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References

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  1. ^ Krug, Edward C.; Hollinger, Steven E. (2003). "Identification of Factors that Aid Carbon Sequestration in Illinois Agricultural Systems" (PDF). Champaign, Illinois: Illinois State Water Survey. p. 10. Archived from the original (PDF) on 2017-08-09. Retrieved 2019-01-06. While humus (especially in organomineral form) helps give soils a black color (Duchaufour, 1978), the literature shows correlation between forest and grassland soil color to BC - the blacker the soil the higher its BC content (Schmidt and Noack, 2000)
  2. ^ Gonzalez-Perez, Jose A.; Gonzalez-Vila, Francisco J.; Almendros, Gonzalo; Knicker, Heike (2004). "The effect of fire on soil organic matter-a review" (PDF). Environment International. 30 (6). Elsevier: 855–870. doi:10.1016/j.envint.2004.02.003. PMID 15120204. Retrieved 2019-01-04. As a whole, BC represents between 1 and 6% of the total soil organic carbon. It can reach 35% like in Terra Preta Oxisols (Brazilian Amazonia) (Glaser et al., 1998, 2000) up to 45 % in some chernozemic soils from Germany (Schmidt et al., 1999) and up to 60% in a black Chernozem from Canada (Saskatchewan) (Ponomarenko and Anderson, 1999)
  3. ^ Jordanova, Neli, ed. (2017). "Chapter 8 - The discriminating power of soil magnetism for the characterization of different soil types". Soil Magnetism. Academic Press. pp. 349–365. doi:10.1016/B978-0-12-809239-2.00008-5. ISBN 978-0-12-809239-2. Chernozem soils exhibit similar features worldwide and are generally characterized by significant magnetic enhancement in the upper soil horizons.
  4. ^ "Vladimir Ivanovich Vernadsky". European Geosciences Union (EGU). Archived from the original on 2021-10-23. Retrieved 2022-03-22. Vladimir Ivanovich Vernadsky was an Ukranian-Russian scientist
  5. ^ Pershouse, Didi. "Why Communities Should Invest in Regenerative Agriculture and the Soil Sponge". The soil sponge (or "soil carbon sponge") is a living matrix that soaks up, stores, and filters water; holds landscapes in place; and provides nutrients for an entire food chain, from what would otherwise be bare rock, hardened clay, and desert sands.
  6. ^ "Fungi fights forest fire and builds the Global Carbon Soil Sponge". 10 January 2021. The Soil Carbon Sponge is porous, well-aggregated soil rich in plant roots, diverse life forms, nutrient availability, air, and often holding lots of water.
  7. ^ "Enrich the soil, cool the planet - The Berkshire Edge". September 2, 2019. In his 2017 paper "Regenerate Earth" for Healthy Soils Australia, Jehne draws his reader's attention to the capacity for healthy soils to cool the planet by restoring the water cycle and sequestering carbon."
  8. ^ Jehne, Walter. Regenerate Earth (PDF). p. 12. This mixture of mineral and organic detritus and air (with vast exposed surface areas) formed the Earth's soil carbon sponge with its greatly enhanced capacity to infiltrate and retain rain, enhance access to essential nutrients, and support a diverse range of microbial processes. {{cite book}}: |work= ignored (help)
  9. ^ Wilson, Eugene. "EDS is as real as the air you breathe!". CEDSA. Retrieved 2019-01-10. EDS is an especially complex medical condition because it can involve many more issues. The effects of EDS are as individual as the people with the condition
  10. ^ "San Joaquin: The California State Soil". Professional Soil Science Association of California. Retrieved 2006-11-11.
  11. ^ "San Joaquin - California State Soil" (PDF). USDA - NRCS. Retrieved 2006-11-11.
  12. ^ Soil Survey Staff. "Official Soil Series Descriptions". USDA - NRCS. Retrieved 2006-11-11.

{{California-geo-stub}} {{soil-sci-stub}} Category:Pedology

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roots

fire and grass stuff

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fire and the nitrogen cycle

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https://www.sciencedaily.com/releases/2010/08/100809093645.htm Forest fires help power the nitrogen cycle August 9, 2010 American Society of Agronomy Years after a forest fire, soil bacteria communities have changed and convert more ammonia to nitrates, increasing soil fertility.


"Chasing game such as bison or mastodons into traps, or over cliffs with torches or set fires has been a standard of illustrators of stone-age life for decades." <comment: needs verification.

Source: http://www.primitiveways.com/uses_of_fire.html

"Pruetz has observed chimps monitoring the progress of a passing wildfire from a few meters away and then moving in to forage in the burned-out area. So while chimps cannot build or contain fires, they understand how fire moves across the landscape, and they use this knowledge to their benefit. "

Source: https://www.sapiens.org/archaeology/neanderthal-fire/

"Anthropogenic burning was far and away the most important of these nonagricultural techniques."

Source: https://oregonencyclopedia.org/articles/anthropogenic_fire

"The notion that establishing a Native American burning regime will prevent catastrophic fires is demonstrably incorrect based on the 2007 re-burning of approximately 70,000 acres scorched in Southern California during 2003 fires. "

Source: http://www.californiachaparral.com/enativeamericans.html

More generally, fire is now regarded as a 'natural disturbance', similar to flooding, wind-storms, and landslides, that has driven the evolution of species and controls the characteristics of ecosystems.[1] Excerpted from: fire ecology

prairie and grasslands

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Prairie soils are the most extensive type of soil in the United States. Called Mollisol in the USA, and Chernozem in Canada, dark colored prairie soils cover 21.5 percent of the country's land mass. These deep, dark soils formed because for thousands of years the grass would put down deep roots, it would get really cold and the foliage and the roots would die back. That turnover created copious amounts of organic matter, which gave the soil that deep dark brown color that people associate with good, fertile soil. Something else that contributed to the quality of the soil in the prairies was that the prairies were not a monoculture of grass. Instead, they consisted of grasses, grains and a diversity of flowers and legumes. Anytime you have that kind of plant diversity, you have a more diverse community of soil microorganisms, an important component of soil health.[2]. A fascinating aspect of prairie soils in the United States and Canada is high charcoal content, a product of grassland fire ecology. In some prairie soils, 60% of soil organic carbon is black carbon, [3] sufficient to contribute significantly to the black color of North American tallgrass prairie soils, as well as their superior nutrient and water handling characteristics. [4]

Tallgrass prairie is regularly renewed by fire and grazing, which also keep back the growth of trees and shrubs. Prominent grass species are big bluestem (Andropogon gerardi), switchgrass (Panicum virgatum) and Indian grass (Sorghastrum nutans). excerpted from: Excerpted from: flint hills

Grasslands burn more readily than forest and shrub ecosystems, with the fire moving through the stems and leaves of herbaceous plants and only lightly heating the underlying soil, even in cases of high intensity. In most grassland ecosystems, fire is the primary mode of decomposition, making it crucial in the recycling of nutrients.[5] It has been hypothesized that fire only recently became the primary mode of decomposition in many grassland ecosystems after the removal or extinction of large migratory herds of browsing or grazing megafauna driven by predator pressure. In this view, in the absence of functional communities of large migratory herds of herbivorous megafauna and attendant predators, overuse of fire to maintain grassland ecosystems may lead to excessive oxidation, loss of carbon, and desertification in susceptible climates.[6] excerpted from: Fire ecology

"... managed fire during the dormant season is most effective at increasing the grass and forb cover, biodiversity and plant nutrient uptake in shortgrass prairies.[7] excerpted from: Fire ecology

"The shortgrass prairie has a long human history. The Kiowa, Comanche, and Arapahoe peoples occupied the land, hunting bison and pronghorn. Seasonally, these tribes would stage hunts in the adjacent mountains such as the Rocky Mountains. To manage the prairie these tribes and their predecessors likely used fire. They would create fuel breaks, a gap in vegetation or other combustible material that acts as a barrier to slow or stop the progress of a brushfire or wildfire. A firebreak may occur naturally in areas without vegetation or other fuel, such as a river, lake or canyon around their settlements. These fuel breaks would also entice large herbivores to patches of fresh new growth. " excerpted from: Shortgrass prairie

"The Central Shortgrass Prairie has a long human history, with the Kiowas, Comanches, and Arapahoes once occupying much of the land to hunt bison and antelope and stage seasonal hunts into the adjacent mountains. These tribes and their predecessors likely used fire to manage the prairie, both to create fuel breaks around their settlements and to entice large herbivores to patches of fresh new growth." [8]

The shortgrass prairie is a long thin stretch of territory that starts at the top of the country and makes its way to the bottom. Due to this, the climate varies from North to South, but is essentially the same from East to West. The temperature in the North is significantly colder on average then the temperature in the South. Also, there is more precipitation to the south, and more precipitation to the East. An interesting distinction about the shortgrass prairie compared to the tall and mixed grass prairies is that it has a one to two month summer drought, where the other two do not. This means that it also the driest prairie of the three.

[9] Excerpt from Shortgrass prairie

"The tallgrass prairie biome depends on prairie fires, a form of wildfire, for its survival and renewal."[10] Excerpted from: Tallgrass prairie

"...the prairie is the natural habitat of fire."[11]

"The Plains Indians started fires to attract game to new grasses. They sometimes referred to fire as the "Red Buffalo." " Excerpt from NPD Fire and Grazing: [12]

"The east-to-west gradient of increasing altitude, decreasing precipitation, and increasing temperature and the north-to-south gradient of temperature and humidity have created zones of tall, medium, and short-grass prairies. . ... The short grass prairies found in the 15-25 inch annual precipitation zone ..." Excerpt from OS short and tall grasses: [13]

Savanna

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The frequent fires which maintained the savannas were started by the region's many thunderstorms and Native Americans, with most fires burning the forest understory and not affecting the mature trees above. Before the arrival of humans about 15,000 years ago, lightning would have been the major source of ignition, the region having the most frequent wind and lightning storms in North America.[14][15][16][17] The European settlers who displaced the natives blended the local use of fire with their customary use of fire as pastoral herdsmen in the British Isles, Spain, and France.[14] Excerpt from : Eastern savannas of the United States

The effect of fire on soil organic matter—a review

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Source: http://www.fsl.orst.edu/ltep/Biscuit/Biscuit_files/Refs/Gonzales-Perez%20EI2004%20fire.pdf

"Alterations in the mineralization indices of some soils lasting at least for 2 years after a wildfire have been found, accompanied by an increase in OM stabilization (Fernandez et al., 1999)."

"Forest fires produce more charcoal than savanna or grassland fires (Stocks and Kauffman, 1997)."

"As a whole, BC represents between 1 and 6% of the total soil organic carbon. It can reach 35% like in Terra Preta Oxisols (Brazilian Amazonia) (Glaser et al., 1998, 2000) up to 45 % in some chernozemic soils from Germany (Schmidt et al., 1999) and up to 60% in a black Chernozen from Canada (Saskatchewan) (Ponomarenko and Anderson, 1999)"

"Only a small part of the heat generated during a forest fire is radiated to soil."

"Occurrence of wildfires in forest ecosystems has lasting effects on both the microbial composition and the OM, and hence on the whole soil dynamics. The alteration of natural ecosystems affects OM turnover and therefore productivity and community structure may be also affected (Pastor and Post, 1986)."

"Shindo et al. (1986a,b) compared optical properties, IR spectra and X-ray diffraction patterns of HAs from volcanic ash soils with those from charred plant residues and concluded that charring process could be one out of the possible mechanisms for the formation of HAs in some volcanic soils (Andosols)."

Wild Hearth A Prolegomenon to the Cultural Fire History of Northern Eurasia excerpts

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Source: https://link.springer.com/chapter/10.1007/978-94-015-8737-2_2 Pyne, Stephen J. 1996. Wild hearth. A prolegomenon to the cultural fire history of northern Eurasia. Pages 21-44 In: Goldammer, Johann G.; Furyaev, Valentin V. (Ed.). Fire in ecosystems of boreal Eurasia. Boston, MA: Kluwer Academic Publishers.


"Since the time of Homo erectus hominids have, through fire, interacted with the Earth. Anthropogenic fire has been present throughout northern Eurasia whenever ice sheets, sea levels, and climate have permitted; throughout the Holocene, occupation by Homo sapiens has been continuous. Through their fire practices humans have sought, from the earliest times, to reshape and render habitable their surroundings. The ways by which humans have protected themselves from wildfire and the means by which they have projected their own domesticated fires onto the land have varied considerably — they have changed over historic time as well as across geographic space. But their fires mark human presence as surely as flint arrowheads or burial mounds. Everywhere fire has mediated between humans and the land. The biota of northern Eurasia has thus coexisted, if not coevolved, under the pressures of anthropogenic fire."


Fire as a Soil-Forming Factor

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Source:[18]

"It is also believed that the charcoal left on the ground from incomplete combustion of woody materials participates in increasing soil fertility."

"What is not completely oxidized to ash is often transformed to charcoal, a heterogeneous mixture of thermally altered biomacromolecules (Knicker et al. 2008), whose more refractory pool can last intact in natural environments for centuries or even millennia (Titiz and Sanford 2007; Robin et al. 2013). Charcoal may represent a substantial fraction of soil organic matter in fire-prone ecosystems and as such strongly affect several soil properties (Knicker 2011). It has been also suggested that charcoal is able to stimulate the degradation of the native soil organic matter (Wardle et al. 2008)."

"A few minerals are peculiar ramifications of wildfires, because they form in soil through thermal transformation of other minerals. One of these is maghemite, a magnetic Fe-oxide that occurs, in the presence of oxygen and organic matter, at the expense of other iron oxides or hydroxides, such as ferrihydrite (Campbell et al. 1997) or goethite (Clement et al. 2011)."

"some minerals decompose at temperatures plausible in wildfires, such as kaolinite—perhaps the most common clay mineral in soils—that collapses at 500–550 °C (Ulery et al. 1996; Yusiharni and Gilkes 2012)."

"There are soils where fire plays a so marked role in molding their features (Fig. 3), that they could be meaningfully called Pyrogenic soils."

"Since the 1990s, man began to be recognized as the sixth soil-forming factor (Amundson and Jenny 1991), distinct from the other organisms essentially because he possesses a cultural component that varies from society to society and which operates independently of genotype (Amundson 2006). Fire could be perceived as one of the many ways man influences the pedogenesis, since he lights most of modern fires, voluntarily or involuntarily. Nonetheless, fire is per se independent of man and well before the emergence of people on Earth, it played a key role in plants adaptation and ecosystems distribution (Pausas and Keeley 2009). Furthermore, in spite of the common belief that when there were fewer people there must have been less blazes, the total biomass burning is now lower than at any time in the past 2000 years (Prentice 2010). Actually, man is highly efficacious in fighting fire and in the absence of his intervention, hundreds of square kilometers can burn undisturbed (Mack et al. 2011)."

"One could wonder whether fire ultimately involves all soils. Although most of them actually had such an experience, as confirmed by the usual finding of charcoal in soil and sediments (Schmidt and Noack 2000; Knicker 2011), some other soils may have been never touched by fire because never colonized by vegetation or exceptionally well preserved from flames."

USFS Wildland fire in ecosystems excerpts

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Source[14]

"Lightning as a cause of fire over geologic time is widely appreciated. But humans also have been a major source of ignition, having used fire for various purposes during the past 20,000 years (Wright and Bailey 1982) and beyond. The pervasive influence of intentional burning by Native Americans during the past several centuries is probably not fully appreciated (Denevan 1992; Gruell 1985a). Human influence was particularly significant in grasslands and those communities bordering grasslands (Wright and Bailey 1982). Historically, fire caused by all ignition sources occurred over large areas covering more than half of the United States at intervals of 1 to 12 years; and fire occurred at longer intervals over most of the rest of the country (Frost 1998)." (page 2)

"Native Americans used fire extensively to shape the vegetative mosaic for thousands of years," (page 57)

"Hough (1877) thought the “oak openings,” “barrens,” and prairies east of the Mississippi resulted from Native American use of fire to promote grass growth and attract game. He stated, “Scarcely a year passes without the occurrence of fires of sufficient extent to attract public notice.” Numerous authors (DeViro 1991; Patterson and Sassamen 1988; Stewart 1951, 1963; Van Lear and Waldrop 1989) have discussed the vast extent to which Native Americans used fire." (page 61)

"The vast Shenandoah Valley was burned annually by Native Americans to keep it from reverting to forest (Leyburn 1962)." (p 81-2)

"Prairie—Historically, Native Americans contributed to the creation and maintenance of the tallgrass prairie ecosystem by frequently burning these ecosystems, which controlled woody vegetation and maintained dominance by herbaceous plants. In the Eastern tallgrass prairie, Native Americans were probably a far more important source of ignition than lightning. With grasses remaining green through late summer and a low incidence of dry lightning storms, lightning caused fires were probably relatively infrequent. Few studies of the pre-Euro-American tallgrass prairie have been conducted.." (page 86)

"It appears from these historical accounts that the season when fires were common varied regionally and through time as a result of the cultural practices of the people living in a particular area." (p 87)

"Bison prefer burned to unburned grassland for grazing during the growing season and can contribute to the pattern of burning in prairie (Vinton and others 1993)." (Page 87)

"Alternatively, fuels could be manually removed or raked away and dispersed from around the boles of old growth trees." (page 103)

"In recent centuries, fire regimes in Western oak forests were characterized by frequent, low intensity fires. This was probably due to use of these types by Native Americans, who probably carried out programs of frequent underburning." (page 131)

"In the plains and grasslands, Native Americans ignited fires for a wide variety of cultural reasons. This was the predominant source of ignition in heavy use areas particularly at lower and middle elevations. But, an ever-present ignition source was lightning, which was probably more important in valleys surrounded by forests" (page 142)

"Global change, the combined effect of human activity on atmospheric and landscape processes (Vitousek 1994), affects all aspects of fire management." (p 175)

"Prior to the arrival of Europeans in North America, native people routinely used fire to drive game animals and manage vegetation near encampments (Barrett and Arno 1982; Bonnicksen 1999; Boyd 1999; Clark and Royall 1995, 1996; Pyne 1982). In some regions Native Americans developed large agrarian communities where vegetation was extensively altered. Although the degree to which fire was used to initiate and maintain agriculture is uncertain, agriculture and harvesting of biomass for energy did lead to substantial change in fire regimes and vegetation in some areas. " (page 176)

"Considerable debate exists about the relative importance of Native Americans and lightning in maintaining historical fire regimes ( Barrett and Arno 1982; Frost 1998; Keane and others 1999). The relative importance of Native American fires was probably greater in topographically complex areas where fire compartments were smaller and where lighting ignitions were infrequent (Frost 1998). Also debated is whether anthropogenic burning should be considered part of the native or natural fire regime (Arno 1985; Kilgore 1985). Fires set by Indians were often of different seasonality, frequency, and landscape pattern than those started by lightning (Frost 1998; Kay 1995). Indian and lightning-caused fire existed for thousands of years, a short evolutionary period but a long time for plant communities to adjust to fire disturbance. This long period of fire on the landscape argues strongly for accepting both sources of ignition in considerations of Euro-American presettlement fire history used to guide management of ecosystems. Efforts to suppress fires were modest at first relying on wet blankets and buckets around dwellings and campsites (Pyne 1982)." (page 192)

"Historically, fires were more frequent in Eastern than in Western grasslands. High productivity of biomass was maintained in the tallgrass prairie by frequently occurring fire that recycled accumulated thatch. A diverse composition was probably favored by variable frequency and seasonality of fires (Abrams and Gibson 1991; Bragg 1991). Western grasslands appear to have generally experienced fire less frequently (Gruell 1985; Wright and Bailey 1982) but still frequently enough to hold back invasion of woody plants. Fire regimes have shifted to too much fire in the drier portions of the sagebrush-steppe ecosystem that occupies over 100 million acres in Western United States. Fire frequency has increased in many areas due to invasion of cheatgrass and medusahead, introduced annuals that cure early and remain flammable during a long fire season. Increased fire frequency exerts strong selective pressure against many native plants (Keane and others 1999)." (p 194-5)

fireecology - grasslands

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Grasslands
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Original: Grasslands burn more readily than forest and shrub ecosystems, with the fire moving through the stems and leaves of herbaceous plants and only lightly heating the underlying soil, even in cases of high intensity. In most grassland ecosystems, fire is the primary mode of decomposition, making it crucial in the recycling of nutrients.[DeBano1998] In some grassland systems, fire only became the primary mode of decomposition after the disappearance of large migratory herds of browsing or grazing megafauna driven by predator pressure. In the absence of functional communities of large migratory herds of herbivorous megafauna and attendant predators, overuse of fire to maintain grassland ecosystems may lead to excessive oxidation, loss of carbon, and desertification in susceptible climates.[Savory] Some grassland ecosystems respond poorly to fire. [fs.fed.us]


Grasslands burn more readily than forest and shrub ecosystems, with the fire moving through the stems and leaves of herbaceous plants and only lightly heating the underlying soil, even in cases of high intensity. In most grassland ecosystems, fire is the primary mode of decomposition, making it crucial in the recycling of nutrients.[19]

Grassland ecosystems can respond in undesirable ways to fire, with soil erosion, and long term loss in primary productivity. Over reliance on fire to manage accumulation of senescent vegetation can result in excessive losses of carbon to oxidation, replacement of perennial plant species with less desirable annual species, soil erosion, and desertification in susceptible climates.[20]

One hypothesis is that ancient prairie ecosystems would have been more reliant on megafauna grazers and attendant predators than fire. Grasslands highly adapted to a megafaunal ecology may be better suited to a grazing-dominant ecology than to a fire-dominant ecology.[21]

North American grasslands
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In North America fire-adapted invasive grasses such as Bromus tectorum contribute to increased fire frequency which exerts selective pressure against native species. This is a concern for grasslands in the Western United States.[20]

In the presettlement Great Plains, bison grazing[22] in concert with fire[23] resulted in exceptionally productive grassland ecosystems.[24] A signature effect of these pre-historic prairie fire ecologies was carbon sequestration, black soils[25] and enhanced soil fertility.[26][27][28] The tallgrass prairie ecosystem in the Flint Hills of eastern Kansas and Oklahoma is responding positively to the current use of fire in combination with cattle grazing.[29]

South African savanna
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In the savanna of South Africa, recently burned areas have new growth that provides palatable and nutritious forage compared to older, tougher grasses. This new forage attracts large herbivores from areas of unburned and grazed grassland that has been kept short by constant grazing. On these unburned "lawns", only those plant species adapted to heavy grazing are able to persist; but the distraction provided by the newly burned areas allows grazing-intolerant grasses to grow back into the lawns that have been temporarily abandoned, so allowing these species to persist within that ecosystem.[30]

riff off Chernozem talk to fire ecology

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Identification of Factors that Aid Carbon Sequestration in Illinois Agricultural Systems[31]

Wildland fire in ecosystems: effects of fire on flora [32]

xxxFire and Grazing in the Prairie[33]

xxxSplendor of the Grass: The Prairie's Grip is Unbroken in the Flint Hills of Kansas [34]

The effect of fire on soil organic matter-a review [35]


  1. ^ The ecology of natural disturbance and patch dynamics. Pickett, Steward T., 1950-, White, P. S. Orlando, Fla.: Academic Press. 1985. ISBN 978-0125545204. OCLC 11134082.{{cite book}}: CS1 maint: others (link)
  2. ^ https://www.mnn.com/your-home/organic-farming-gardening/stories/things-you-didnt-know-about-soil The effect of fire on soil organic matter—a review
  3. ^ http://www.fsl.orst.edu/ltep/Biscuit/Biscuit_files/Refs/Gonzales-Perez%20EI2004%20fire.pdf
  4. ^ Ponomarenko reference here
  5. ^ DeBano, L.F., D.G. Neary, P.F. Ffolliot. 1998. Fire’s Effects on Ecosystems. John Wiley & Sons, Inc., New York, New York, USA.
  6. ^ Savory, Allan; Butterfield, Jody (2016-11-10). Holistic management : a commonsense revolution to restore our environment (Third ed.). Washington. ISBN 9781610917438. OCLC 961894493.{{cite book}}: CS1 maint: location missing publisher (link)
  7. ^ Brockway, D.G.; Gatewood, R.G.; Paris, R.B. (2002). "Restoring fire as an ecological process in shortgrass prairie ecosystems: initial effects of prescribed burning during the dormant and growing seasons". Journal of Environmental Management. 65 (2): 135–152. doi:10.1006/jema.2002.0540
  8. ^ "Central Shortgrass Prairie // LandScope America". www.landscope.org. Retrieved 2016-11-16.
  9. ^ Samson, Fred B.; Knopf, Fritz L. (1996-08-01). Prairie Conservation: Preserving North America's Most Endangered Ecosystem. Island Press. ISBN 9781610913942.
  10. ^ Klinkenborg, Verlyn (April 2007). "Splendor of the Grass: The Prairie's Grip is Unbroken in the Flint Hills of Kansas". National Geographic. Archived from the original on 2018-02-26.
  11. ^ https://web.archive.org/web/20180226080618/http://ngm.nationalgeographic.com:80/2007/04/tallgrass-prairie/klinkenborg-text
  12. ^ NPS Fire and Grazing
  13. ^ OS short and tall grasses
  14. ^ a b c Brown, James K.; Smith, Jane Kapler (2000). "Wildland fire in ecosystems: effects of fire on flora". Gen. Tech. Rep. RMRS-GTR-42-vol. 2. Department of Agriculture, Forest Service, Rocky Mountain Research Station. pp. 56–68. Retrieved 2008-07-20. Native Americans used fire extensively to shape the vegetative mosaic [in Eastern US savanna for thousands of years ... ... prior to the Civil War, over 75 percent of the white population were pastoral herdsmen (Owsley 1945) who came from the British Isles, Spain, and France where fire was an integral part of their livelihood. They brought this practice with them, blended their knowledge with that of the Native Americans they displaced, and aggressively expanded the use and frequency of fire throughout the South. A circa 1731 North Carolina law required the annual burning of all pastures and rangelands every March (Carrier and Hardison 1976).
  15. ^ Earley, Lawrence S. (2006). Looking for Longleaf: The Fall And Rise of an American Forest. UNC Press. ISBN 0-8078-5699-1.
  16. ^ "Use of Fire by Native Americans". The Southern Forest Resource Assessment Summary Report. Southern Research Station, USDA Forest Service. Retrieved 2008-07-21. The role of fire was dramatically increased with the arrival of aboriginal man in America
  17. ^ Williams, Gerald W. (2003-06-12). "REFERENCES ON THE AMERICAN INDIAN USE OF FIRE IN ECOSYSTEMS" (PDF). Archived from the original (PDF) on 2008-07-06. Retrieved 2008-07-31. William Cronon, a prominent environmental historian, wrote that "the choice is not between two landscapes, one with and one without a human influence; it is between two ways of living, two ways of belonging to an ecosystem (Cronon 1983: 12)." These two ways are modification of ecosystems through fire or through through development, such as farming and grazing. Generally, the American Indians burned parts of the ecosystems in which they lived to promote a diversity of habitats, especially increasing the "edge effect," which gave the Indians greater security and stability to their lives. Their use of fire was different from white settlers who burned to create greater uniformity in ecosystems.
  18. ^ Certini, Giacomo (March 2014). "Fire as a Soil-Forming Factor". Ambio. 43 (2): 191–195. doi:10.1007/s13280-013-0418-2. PMC 3906481. PMID 23852880.
  19. ^ Cite error: The named reference DeBano1998 was invoked but never defined (see the help page).
  20. ^ a b Brown, James K.; Smith, Jane Kapler (2000). "Wildland fire in ecosystems: effects of fire on flora". Gen. Tech. Rep. RMRS-GTR-42-vol. 2. Department of Agriculture, Forest Service, Rocky Mountain Research Station. Retrieved 2019-01-04. pp 194-5: Fire frequency has increased in many areas due to invasion of cheatgrass and medusahead, introduced annuals that cure early and remain flammable during a long fire season. Increased fire frequency exerts strong selective pressure against many native plants (Keane and others 1999)
  21. ^ Savory, Allan; Butterfield, Jody (2016-11-10). Holistic management: a commonsense revolution to restore our environment (Third ed.). Washington. ISBN 9781610917438. OCLC 961894493.{{cite book}}: CS1 maint: location missing publisher (link)
  22. ^ Brown, James K.; Smith, Jane Kapler (2000). "Wildland fire in ecosystems: effects of fire on flora". Gen. Tech. Rep. RMRS-GTR-42-vol. 2. Department of Agriculture, Forest Service, Rocky Mountain Research Station. Retrieved 2019-01-04. (re: plant distribution) p. 87: Bison prefer burned to unburned grassland for grazing during the growing season and can contribute to the pattern of burning in prairie (Vinton and others 1993)
  23. ^ "Fire and Grazing in the Prairie". US National Park Service. 2000. Retrieved 2019-01-04. The Plains Indians started fires to attract game to new grasses. They sometimes referred to fire as the "Red Buffalo."
  24. ^ Krug, Edward C.; Hollinger, Steven E. (2003). "Identification of Factors that Aid Carbon Sequestration in Illinois Agricultural Systems" (Document). Champaign, Illinois: Illinois State Water Survey. p. 10. The literature further shows that prairie burning enhances productivity, root biomass levels, root turnover, and arthropods - the latter being especially active in incorporating surface BC throughout the soil profile (Lussenhop, 1976) {{cite document}}: Unknown parameter |access-date= ignored (help); Unknown parameter |archive-date= ignored (help); Unknown parameter |archive-url= ignored (help); Unknown parameter |url-status= ignored (help); Unknown parameter |url= ignored (help)
  25. ^ Krug, Edward C.; Hollinger, Steven E. (2003). "Identification of Factors that Aid Carbon Sequestration in Illinois Agricultural Systems" (Document). Champaign, Illinois: Illinois State Water Survey. p. 10. While humus (especially in organomineral form) helps give soils a black color (Duchaufour, 1978), the literature shows correlation between forest and grassland soil color to BC - the blacker the soil the higher its BC content (Schmidt and Noack, 2000) {{cite document}}: Unknown parameter |access-date= ignored (help); Unknown parameter |archive-date= ignored (help); Unknown parameter |archive-url= ignored (help); Unknown parameter |url-status= ignored (help); Unknown parameter |url= ignored (help)
  26. ^ Krug, Edward C.; Hollinger, Steven E. (2003). "Identification of Factors that Aid Carbon Sequestration in Illinois Agricultural Systems" (Document). Champaign, Illinois: Illinois State Water Survey. p. 10. Frequent presettlement fires in Illinois created a multi-level, positive-feedback system for sequestering SOC and enhancing soil fertility. {{cite document}}: Unknown parameter |access-date= ignored (help); Unknown parameter |archive-date= ignored (help); Unknown parameter |archive-url= ignored (help); Unknown parameter |url-status= ignored (help); Unknown parameter |url= ignored (help)
  27. ^ Gonzalez-Perez, Jose A.; Gonzalez-Vila, Francisco J.; Almendros, Gonzalo; Knicker, Heike (2004). "The effect of fire on soil organic matter-a review" (PDF). Environment International. 30 (6). Elsevier: 855–870. doi:10.1016/j.envint.2004.02.003. PMID 15120204. Retrieved 2019-01-04. re black carbon(BC): ...there is no generally accepted terminology for BC but, in recent literature this terms is preferred to alternative synonyms such as charcoal, soot, elemental carbon, pyrogenic carbon, etc. As a whole, BC represents between 1 and 6% of the total soil organic carbon. It can reach 35% like in Terra Preta Oxisols (Brazilian Amazonia) (Glaser et al., 1998, 2000) up to 45 % in some chernozemic soils from Germany (Schmidt et al., 1999) and up to 60% in a black Chernozem from Canada (Saskatchewan) (Ponomarenko and Anderson, 1999)
  28. ^ Brown, James K.; Smith, Jane Kapler (2000). "Wildland fire in ecosystems: effects of fire on flora". Gen. Tech. Rep. RMRS-GTR-42-vol. 2. Department of Agriculture, Forest Service, Rocky Mountain Research Station. Retrieved 2019-01-04. p86: Historically, Native Americans contributed to the creation and maintenance of the tallgrass prairie ecosystem by frequently burning these ecosystems, which controlled woody vegetation and maintained dominance by herbaceous plants. In the Eastern tallgrass prairie, Native Americans were probably a far more important source of ignition than lightning. With grasses remaining green through late summer and a low incidence of dry lightning storms, lightning caused fires were probably relatively infrequent. Few studies of the pre-Euro-American tallgrass prairie have been conducted.
  29. ^ Klinkenborg, Verlyn (April 2007). "Splendor of the Grass: The Prairie's Grip is Unbroken in the Flint Hills of Kansas". National Geographic. Archived from the original on 2018-02-26. Retrieved 2019-01-04. The tallgrass prairie biome depends on prairie fires, a form of wildfire, for its survival and renewal. ... [and] ...the prairie is the natural habitat of fire.
  30. ^ Archibald et al. 2005
  31. ^ Krug, Edward C.; Hollinger, Steven E. (2003). "Identification of Factors that Aid Carbon Sequestration in Illinois Agricultural Systems" (Document). Champaign, Illinois: Illinois State Water Survey. p. 10. Frequent presettlement fires in Illinois created a multi-level, positive-feedback system for sequestering SOC and enhancing soil fertility. {{cite document}}: Unknown parameter |access-date= ignored (help); Unknown parameter |archive-date= ignored (help); Unknown parameter |archive-url= ignored (help); Unknown parameter |url-status= ignored (help); Unknown parameter |url= ignored (help)
  32. ^ Brown, James K.; Smith, Jane Kapler (2000). "Wildland fire in ecosystems: effects of fire on flora". Gen. Tech. Rep. RMRS-GTR-42-vol. 2. Department of Agriculture, Forest Service, Rocky Mountain Research Station. Retrieved 2019-01-04. (re: plant distribution) p. 87: Bison prefer burned to unburned grassland for grazing during the growing season and can contribute to the pattern of burning in prairie (Vinton and others 1993)
  33. ^ "Fire and Grazing in the Prairie". US National Park Service. 2000. Retrieved 2019-01-04. The Plains Indians started fires to attract game to new grasses. They sometimes referred to fire as the "Red Buffalo."
  34. ^ Klinkenborg, Verlyn (April 2007). "Splendor of the Grass: The Prairie's Grip is Unbroken in the Flint Hills of Kansas". National Geographic. Archived from the original on 2018-02-26. Retrieved 2019-01-04. The tallgrass prairie biome depends on prairie fires, a form of wildfire, for its survival and renewal. ... [and] ...the prairie is the natural habitat of fire.
  35. ^ Gonzalez-Perez, Jose A.; Gonzalez-Vila, Francisco J.; Almendros, Gonzalo; Knicker, Heike (2004). "The effect of fire on soil organic matter-a review" (PDF). Environment International. 30 (6). Elsevier: 855–870. doi:10.1016/j.envint.2004.02.003. PMID 15120204. Retrieved 2019-01-04. As a whole, BC represents between 1 and 6% of the total soil organic carbon. It can reach 35% like in Terra Preta Oxisols (Brazilian Amazonia) (Glaser et al., 1998, 2000) up to 45 % in some chernozemic soils from Germany (Schmidt et al., 1999) and up to 60% in a black Chernozem from Canada (Saskatchewan) (Ponomarenko and Anderson, 1999)

Test2

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In X, Y means Z

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In X , Y means/describes/occurs/is/refers_to Z:

  1. On a glacier, the accumulation zone is
  2. On a glacier, the zone of ablation occurs
  3. In geography, aspect (geography) generally refers to
  4. In agriculture, a terrace (agriculture) is
  5. In rock climbing or ice climbing, a pitch is
  6. In the physical sciences, non-life is
  7. In biology a relict is ... In geology a relict is
  8. In biology the term type locality (biology) is used to refer to
  9. In some natural sciences, type locality (geology) is ... It is most commonly used in geology for ...
  10. In soil science, bulk soil is

Y, in X, means/describes/occurs/is/refers_to Z |is_a_term_used_in:

  1. Parent material, in soil science, is
  2. Confluence (geography), in geography, describes
  3. A reach in geography is
  4. A thalweg in geology is
  5. Respiration (dab) is a term used in both

Other:

  1. The Plasticity index (often abbreviated as PI) is a numerical measure of the plasticity of a soil.
  2. A topographical summit (topography) is.. Colloquially, a summit generally refers to ...

Wikipedia is not a bibliography

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WP:NOT >> Listcruft --- bibliography/reference bloat/spam/masquerade -- trivial

-- orgy of references -- A muddle of true sources and further reading -- Examples:

base condition or process of degradation

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soil and waste treatment

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Soil biota generally runs on oxygen. Not coincidentally, so do most waste treatment processes. A healthy soil can recycle most any waste material that passes by it. Soil biota, especially bacteria, feed on oxygen demanding constituents in the waste and consume organic matter of any kind. Clay particles in the soil act as electrostatic filters capable of adsorbing and detaining virus pathogens. The soil also chemically locks up chemicals like phospates.

Fallacies

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Pretty tables

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Prettytable example
Foo Bar Baz Quux
100 Cake Monster in the closet NO!
Wikipedia ^______^ Darth Vader 42
Moo 1.618033989 Pay your bills Bach

Soil profile info

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UALS copyrighted gif

CSU gif unspecified copyright

USDA pdf w soil profile graphic, horizons designated

soil profile lesson from NRCS

soil profile description

test area

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{{failed verification}} {{failed verification |reason=xxx |date=xxx }} = clarification needed

{{subst:unsigned|user name or ip|date}} —The preceding unsigned comment was added by user name or ip (talkcontribs) date.

Registered users can sign their posts by clicking the signature icon that appears on your editing toolbar.

& # 9742;

WP:TT--WP:UTM

OR THIS:
== Request for edit summary ==
Hi. Just a tip. It is good to use an edit summary (and a relevant one) when you contribute. For example the summary of this edit was a bit misleading, referring to a previous section. Just thought I would let you know. :) Thanks.

Professional engineer

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Licensing controversy

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Population

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  • Currently over 2 million practicing engineers in the USA [1] divided by 295,734,134 USA population [2] is over 0.68%
  • Current 1.45 million employed engineers [3] in the USA divided by 295,734,134 USA population is 0.49%
  • 1992 1.9 million total engineers in the USA divided by 240 million USA population is 0.79% [4]
  • Current 27,501 Professional Engineers licensed in New York State [5] divided by a population of 19,227,088 [6] is 0.14%

Note: For whatever reason the US Bureau of Labor statistics thinks there are far less than 2 million engineers. But the ratios of totals to apparent licensed to totals are still as wide as the New York stats infer.

VP actions

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Tool bar

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Article Tools

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Speedy Deletion

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Sort

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User tools

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Warn

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Edit hints

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DYK checklist

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General eligibility:

Policy compliance:

Hook eligibility:

  • Cited:  
  • Interesting:  

QPQ:  
Invalid status "Y" - use one of "y", "?", "maybe", "no" or "again"

New DYK Nom

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| article         = Friedrich Albert Fallou
|    article2     = 
| status          = moved
| ALT1            = ...that the founder of modern soil science, Friedrich Albert Fallou, was a lawyer and tax assessor who "studied soils as a hobby"?
| hook            = ...that the founder of modern soil science, Friedrich Albert Fallou, was a lawyer and tax assessor who studied soils as an independent scientist?
| author          = 
|    author2      = 
| image           = Friedrich_Albert_Fallou_1794_1877_German_Soil_Scientist.jpg
|    caption      = Fallou, Friedrich Albert. German. Founder of Modern Soil Science. Photo taken before his death in 1877
| comment         = 
  • This article was created in userspace from a translation of the German version.
  • It moved from draft article space to main space on February 16.
  • HOBBY: The phrase "...studied soils as a hobby" is verbatim in 2 sources, Asio 2005 originated it and the cited Alfred Hartemink source repeats it. That he "...studied soils as an independent scientist" is a better fit for the article.
| reviewed        =


Steppe Sandbox

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The opening sentence now reads:

In physical geography, a steppe (Russian: степь, IPA: [stʲepʲ]) is an ecoregion, in the montane grasslands and shrublands and temperate grasslands, savannas and shrublands biomes, characterized by grassland plains without trees apart from those near rivers and lakes.

Where is the ecoregion? It seems to be in any one of several biomes. How many types of biomes are there? Are there just two biomes—biomes whose components are montane grasslands and shrublands and temperate grasslands, and biomes whose components are savannas and shrublands? Or are there four—montane grassland biomes, shrubland biomes, temperate grassland biomes, and savanna biomes? Are all the biomes characterized by grassland plains?

The problem is that it isn't clear what in governs, because use of the plurals in grasslands, shrublands, grasslands, savannas, and shrublands makes them appear to be the objects of in, but once you read biomes, those plural nouns appear to be noun modifiers of biomes, in which case in ultimately governs biomes.

The best revision would be on in which grassland and shrubland appeared only once, and in which no noun phrase modifies biome. Wordwright (talk) 23:47, 1 December 2018 (UTC)

--- steppes are grassland communities with little or no trees. [7],[8]

A Steppe is a plain without trees (apart from near rivers and lakes), the same as a prairie. It may be semi-desert or covered with grass or shrubs, or both depending on the season.

In physical geography, a steppe (Russian: степь, IPA: [stʲepʲ]) is an ecoregion, in the montane grasslands and shrublands and temperate grasslands, savannas and shrublands biomes, characterized by grassland plains without trees apart from those near rivers and lakes. In South Africa, they are referred to as veld. The prairie of North America (especially the shortgrass and mixed prairie) is an example of a steppe, though it is not usually called such. A steppe may be semi-desert or covered with grass or shrubs or both, depending on the season and latitude. The term is also used to denote the climate encountered in regions too dry to support a forest but not dry enough to be a desert. The soil is typically of chernozem type.

The Eurasian steppe is the vast steppe ecoregion of Eurasia in the temperate grasslands, savannas, and shrublands biome. It stretches from...

> > In physical geography, a steppe (Russian: степь, romanized: flat grassy plain, IPA: [stʲepʲ] or Ukrainian: степ) is a plain with a significant grassland component. Steppe ecosystems produce distinctive grassland soils that are characterically dark deep and fertile. The term steppe is also used to denote the climate encountered in regions too dry to support a forest but not dry enough to be a desert. The prairie of North America is an example of a steppe, though it is not usually called such. There are many types of steppes. Over 50 steppe ecoregions have been identified. During the Last Glacial Maximum, the mammoth steppe was the Earth’s most extensive biome. < <


In South Africa, grasslands similar to steppe are referred to as veld. Grasslands with shrub and tree components are referred to shrub-steppe, sagebrush steppe, steppe-woodland and forest steppe. Tropical grasslands are are sometimes referred to as savanna.

https://sciencing.com/difference-between-grassland-savanna-8427391.html The Difference Between a Grassland and Savanna Copyright 2018 Leaf Group Ltd By Ethan Shaw; Updated April 16, 2018

https://sciencing.com/differences-between-steppes-savannas-8468978.html Differences Between Steppes & Savannas By Alan Osborne; Updated April 25, 2017


is an ecoregion, in the montane grasslands and shrublands and temperate grasslands, savannas and shrublands biomes, characterized by grassland plains without trees apart from those near rivers and lakes. A steppe may be semi-desert or covered with grass or shrubs or both, depending on the season and latitude.

List of Steppe Ecosystems

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A List of terrestrial ecoregions (WWF) indicates 39 steppe + 13 grassland ecoregions out of 867 total ecoregions

Nearctic - Deserts and xeric shrublands

Great Basin shrub steppe
Snake-Columbia shrub steppe
Wyoming Basin shrub steppe

Nearctic - Temperate grasslands, savannas, and shrublands

13 North American plains grassland ecosystems (WWF) referred to as steppe per
[:https://www.forestasyst.org/ecoregions/]

source: [:https://www.fs.fed.us/land/ecosysmgmt/colorimagemap/images/331.html] [:https://www.forestasyst.org/ecoregions/331.cfm] From: Bailey R.G. 1995. Description of the ecoregions of the United States. US Department of Agriculture Forest Service Publication 1391. Washington DC, USA. [:http://www.fs.fed.us/land/ecosysmgmt/ecoreg1_home.html] Source: R.G. Bailey [Ecoregions of the United States, USDA Forest Service (scale 1:7,500,000, revised 1994)] [:https://www.fs.fed.us/land/pubs/ecoregions/index.html] Ecological Subregions of the United States WO-WSA-5 Compiled by W. Henry McNab and Peter E. Avers Prepared in cooperation with Regional Compilers and the ECOMAP Team of the Forest Service July 1994



Neotropic - Temperate grasslands, savannas, and shrublands

Patagonian steppe

Neotropic - Montane grasslands and shrublands

Southern Andean steppe

Palearctic - Temperate broadleaf and mixed forests

East European forest steppe
Tarim Basin deciduous forests and steppe
Zagros Mountains forest steppe

Palearctic - Temperate coniferous forests

Altai montane forest and forest steppe
Elburz Range forest steppe

Palearctic - Temperate grasslands, savannas, and shrublands

Alai-Western Tian Shan steppe
Altai steppe and semi-desert
Central Anatolian steppe
Daurian forest steppe
Eastern Anatolian montane steppe
Emin Valley steppe
Kazakh forest steppe
Kazakh steppe
Mongolian-Manchurian steppe
Middle East steppe
Pontic steppe
Sayan Intermontane steppe
Selenge-Orkhon forest steppe
South Siberian forest steppe
Tian Shan foothill arid steppe

Palearctic - Flooded grasslands and savannas

Amur meadow steppe

Palearctic - Montane grasslands and shrublands

Central Tibetan Plateau alpine steppe
Karakoram-West Tibetan Plateau alpine steppe
Kopet Dag woodlands and forest steppe
Mediterranean High Atlas juniper steppe
Ordos Plateau steppe
Tian Shan montane steppe and meadows
Yarlung Zambo arid steppe

Palearctic - Mediterranean forests, woodlands, and shrub

Mediterranean dry woodlands and steppe

Palearctic - Deserts and xeric shrublands

Azerbaijan shrub desert and steppe
Eastern Gobi desert steppe
Gobi Lakes Valley desert steppe
North Saharan steppe and woodlands
South Saharan steppe and woodlands