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Weeds growing in the cracks of a concrete staircase (Epilobium roseum, Chelidonium majus, Oxalis corniculata, Plantago major)

A weed is a plant considered undesirable in a particular situation, growing where it conflicts with human preferences, needs, or goals.[1][2][3][4] Plants with characteristics that make them hazardous, aesthetically unappealing, difficult to control in managed environments, or otherwise unwanted in farm land, orchards, gardens, lawns, parks, recreational spaces, residential and industrial areas, may all be considered weeds.[4][2][5] The concept of weeds is particularly significant in agriculture, where the presence of weeds in fields used to grow crops may cause major losses in yields.[6] Invasive species, plants introduced to an environment where their presence negatively impacts the overall functioning and biodiversity of the ecosystem, may also sometimes be considered weeds.[7][8]

Taxonomically, the term "weed" has no botanical significance, because a plant that is a weed in one context, is not a weed when growing in a situation where it is wanted. Some plants that are widely regarded as weeds are intentionally grown in gardens and other cultivated settings. For this reason, some plants are sometimes called beneficial weeds. Similarly, volunteer plants from a previous crop are regarded as weeds when growing in a subsequent crop. Thus, alternative nomenclature for the same plants might be hardy pioneers, cosmopolitan species, volunteers, "spontaneous urban vegetation," etc.[9]

Although whether a plant is a weed depends on context, plants commonly defined as weeds broadly share biological characteristics that allow them to thrive in disturbed environments and to be particularly difficult to destroy or eradicate. In particular, weeds are adapted to thrive under human management in the same way as intentionally grown plants.[1] Since the origins of agriculture on Earth, agricultural weeds have co-evolved with human crops and agricultural systems, and some have been domesticated into crops themselves after their fitness in agricultural settings became apparent.[10]

More broadly, the term "weed" is occasionally applied pejoratively to species outside the plant kingdom, species that can survive in diverse environments and reproduce quickly; in this sense it has even been applied to humans.[11]

Weed control is important in agriculture and horticulture. Methods include hand cultivation with hoes, powered cultivation with cultivators, smothering with mulch or soil solarization, lethal wilting with high heat, burning, or chemical attack with herbicides and cultural methods such as crop rotation and fallowing land to reduce the weed population.[12]

History

It has long been assumed that weeds, in the sense of rapidly-evolving plants taking advantage of human-disturbed environments, evolved in response to the Neolithic agricultural revolution approximately 12,000 years ago. However, researchers have found evidence of "proto-weeds" behaving in similar ways at Ohalo II, a 23,000-year-old archeological site in Israel.[13]

The idea of "weeds" as a category of undesirable plant has not been universal throughout history. Before 1200 A.D., little evidence exists of concern with weed control or of agricultural practices solely intended to control weeds. A possible reason for this is that for much of human history, women and children were an abundant source of cheap labor to control weeds, and not directly acknowledged.[14] Weeds are assumed to have existed since the beginning of agriculture, and accepted as an "inevitable nuisance."[15]

Though the plants are not named using a specific term denoting a "weed" in the contemporary sense, plants that may be interpreted as "weeds" are referenced in the Bible:[8]

Cursed is the ground because of you; through painful toil you will eat of it all the days of your life. It will produce thorns and thistles for you, and you will eat the plants of the field. By the sweat of your brow you will eat your food until you return to the ground.[16]

Some early Roman writers referenced weeding activities in agricultural fields, but weed control in the pre-modern era was probably an incidental effect of plowing.[17] Ancient Egyptians, Assyrians, and Sumerians had no specific word for "weeds," seeing all plants as having some use. The English word "weed" can be traced back to the Old English weod, which refers to woad, rather than a category of plant as in the modern usage; in early medieval European herbals, each plant is regarded as having its own "virtues".[18]

By the sixteenth century, the concept of a "weed" was better defined as a "noxious" or undesirable type of plant, as referenced metaphorically in William Shakespeare's works.[18] An example of a Shakespearean reference to weeds is found in Sonnet 69:

To thy fair flower add the rank smell of weeds: / But why thy odour matcheth not thy show, / The soil is this, that thou dost common grow.[19]

In London during this period, poor women were paid low wages to weed gardens and courtyards.[20]

After the Reformation, Christian theology that emphasized the degradation of nature after the Fall of Man, and humankind's role and duty to dominate and subdue nature, became more developed and widespread. Various European writers designated certain plants as "vermin" and "filth," though many plants identified as such were valued by gardeners or by herbalists and apothecaries, and some questioned the idea that any plant could be without purpose or value.[18] Laws mandating the control of weeds emerged as early as the seventeenth century; in 1691 a law in New York required the removal of "poysonous and Stincking Weeds" in front of houses.[21]

In the nineteenth century, manual labor was used to control weeds in European towns and cities, and chemical methods of weed control emerged. For example, a French journal in 1831 documented a mixture of sulfur, lime and water boiled in an iron cauldron as an effective herbicide to prevent grass from growing among cobblestones.[20]

The cultural association between weeds and moral or spiritual degradation persisted into the last nineteenth century in American cities. Urban expansion and development created ideal habitats for weeds in nineteenth-century America.[21] Reformers consequently saw weeds as a part of the larger problem of filth, disease, and moral corruption that plagued the urban environments, and weeds were seen as refuge for "tramps" and other criminal or undesirable people. The St. Louis Post-Dispatch credited weeds as causing diphtheria, scarlet fever, and typhoid.[21] In St. Louis between the years of 1905-1910, weeds became viewed as a major public health hazard, believed to cause typhoid and malaria, and legal precedents were set in order to control weeds that would help facilitate the adoption of weed control laws throughout the country.[21]

Ecological significance

A dandelion is a common plant all over the world, especially in Europe, Asia, and the Americas. It is considered a weed in some contexts (such as lawns) but not others (such as when it is grown as a vegetable or herbal medicine).

"Weed" as a category of plant overlaps with the closely related concepts of ruderal and pioneer species.[22] Pioneer species are specifically adapted to disturbed environments, where the existing plant and soil community has been disrupted or damaged in some way. Adaptation to disturbance can give weeds advantages over desirable crops, pastures, or ornamental plants. The nature of the habitat and its disturbances will affect or even determine which types of weed communities become dominant.[23] In weed ecology some authorities speak of the relationship between "the three Ps": plant, place, perception. These have been very variously defined, but the weed traits listed by H.G. Baker are widely cited.[24][25]

Examples of such ruderal or pioneer species include plants that are adapted to naturally-occurring disturbed environments such as dunes and other windswept areas with shifting soils, alluvial flood plains, river banks and deltas, and areas that are burned repeatedly.[26] Since human agricultural and horticultural practices often mimic these natural disturbances that weedy species have adapted for, some weeds are effectively preadapted to grow and proliferate in human-disturbed areas such as agricultural fields, lawns, gardens, roadsides, and construction sites. As agricultural practices continue and develop, weeds evolve further, with humans exerting evolutionary pressure upon weeds through manipulating their habitat and attempting to control weed populations.[10]

Due to their ability to survive and thrive in conditions challenging or hostile to other plants, weeds have been considered extremophiles.[27]

Adaptability

Due to their evolutionary heritage as disturbance-adapted pioneers, most weeds exhibit incredibly high phenotype plasticity, meaning that individual plants hold the potential to adapt their morphology, growth, and appearance in response to their conditions.[22] The potential within a single individual to adapt to a wide variety of conditions is sometimes referred to as an "all-purpose genotype."[28] Disturbance-adapted plants typically grow rapidly and reproduce quickly, with some annual weeds having multiple generations in a single growing season. They commonly have seeds that persist in the soil seed bank for many years. Perennial weeds often have underground stems that spread under the soil surface or, like ground ivy (Glechoma hederacea), have creeping stems that root and spread out over the ground.[29] These traits make many disturbance-adapted plants highly successful as weeds.[22]

On top of the ability of individual plants to adapt to their conditions, weed populations also evolve much more quickly than older models of evolution account for.[28] Once established in an agricultural setting, weeds have been observed to undergo evolutionary changes to adapt to selective pressures imposed by human management. Some examples include changes in seed dormancy, changes in seasonal life cycles, changes in plant morphology, and the evolution of resistance to herbicides.[10] Rapid life cycles, large populations, and ability to spread large numbers of seeds long distances also allow weed species with these general characteristics to evolve quickly.[30]

Dispersal

The concept of weeds also overlaps with the concept of invasive species, both in the sense that human activities tend to introduce weeds outside their native range, and that an introduced species may be considered a weed. Many weed species have moved out of their natural geographic ranges and spread around the world in tandem with human migrations and commerce. Weed seeds are often collected and transported with crops after the harvesting of grains, so humans are a vector of transport as well as a producer of the disturbed environments to which weed species are well adapted, resulting in many weeds having a close association with human activities.[31][32]

Some plants become dominant when introduced into new environments because the animals and plants in their original environment that compete with them or feed on them are absent; in what is sometimes called the "natural enemies hypothesis", plants freed from these specialist consumers may become dominant. An example is Klamath weed, which threatened millions of hectares of prime grain and grazing land in North America after it was accidentally introduced. The Klamathweed Beetle, a species that specializes in consuming the plant, was imported during World War II. Within several years Klamath weed was reduced to a rare roadside weed.[33][34] In locations where predation and mutually competitive relationships are absent, weeds have increased resources available for growth and reproduction. The weediness of some species that are introduced into new environments may be caused by their production of allelopathic chemicals which indigenous plants are not yet adapted to, a scenario sometimes called the "novel weapons hypothesis". These chemicals may limit the growth of established plants or the germination and growth of seeds and seedlings.[35][36] Weed growth can also inhibit the growth of later-successional species in ecological succession.[37]

Introduced species have been observed to undergo rapid evolutionary change to adapt to their new environments, with changes in plant height, size, leaf shape, dispersal ability, reproductive output, vegetative reproduction ability, level of dependence on the mycorrhizal network, and level of phenotype plasticity appearing on timescales of decades to centuries.[38] Invasive species can be more adaptable in their new environments than in their native environments, occupying broader ranges in areas where they are invasive than in areas where they are native. Hybridization between similar species can produce novel invasive plants that are better adapted to their surroundings. Polyploidy is also observed to be strongly selected for among some invasive populations, such as Solidago canadensis in China. Many weed species are now found almost worldwide, with novel adaptations that suit regional populations to their environments.[28]

Negative impacts

Invasive Canada Goldenrod as a roadside weed in Poland
Australia, 1907: Cattlemen survey 700 carcasses of cattle that were killed overnight by a poisonous plant.[39]

Some negative impacts of weeds are functional: they interfere with food and fiber production in agriculture, wherein they must be controlled to prevent lost or diminished crop yields. In other settings, they interfere with other cosmetic, decorative, or recreational goals, such as in lawns, landscape architecture, playing fields, and golf courses. In the case of invasive species, they can be of concern for environmental reasons, when introduced species outcompete native plants and cause broader damage to ecosystem health and functioning.[40] Some weed species have been classified as noxious weeds by government authorities because, if left unchecked, they often compete with native or crop plants or cause harm to livestock.[41] They are often foreign species accidentally or imprudently imported into a region where there are few natural controls to limit their population and spread.[42]

In a range of contexts, weeds can have negative impacts by:

  • competing with the desired plants for the resources that a plant typically needs, namely, direct sunlight, soil nutrients, water, and (to a lesser extent) space for growth,
  • providing hosts and vectors for plant pathogens, giving them greater opportunity to infect and degrade the quality of the desired plants;
  • providing food or shelter for animal pests such as seed-eating birds and Tephritid fruit flies that otherwise could hardly survive seasonal shortages;[43]
  • offering irritation to the skin or digestive tracts of people or animals, either physical irritation via thorns, prickles, or burs, or chemical irritation via natural poisons or irritants in the weed (for example, the poisons found in Nerium species);[44]
  • causing root damage to engineering works such as drains, road surfaces, and foundations,[45]
  • in the case of aquatic plants, obstructing or clogging streams and waterways, which interferes with boating, irrigation systems, fishing, and hydroelectric power.[46][47]

Positive impacts

"What would the world be, once bereft,
of wet and wildness? Let them be left.
O let them be left; wildness and wet;
Long live the weeds and the wilderness yet."

— Gerard Manley Hopkins' poem Inversnaid

While the term "weed" generally has a negative connotation, many plants known as weeds can have beneficial properties. A number of weeds, such as the dandelion (Taraxacum) and lamb's quarter, are edible, and their leaves or roots may be used for food or herbal medicine. Burdock is common over much of the world, and is sometimes used to make soup and medicine in East Asia.[48] Some weeds attract beneficial insects, which in turn can protect crops from harmful pests. Weeds can also prevent pest insects from finding a crop, because their presence disrupts the incidence of positive cues which pests use to locate their food. Weeds may also act as a "living mulch", providing ground cover that reduces moisture loss and prevents erosion. Weeds may also improve soil fertility; dandelions, for example, bring up nutrients like calcium and nitrogen from deep in the soil with their tap root, and clover hosts nitrogen-fixing bacteria in its roots, fertilizing the soil directly. The dandelion is also one of several species which break up hardpan in overly-cultivated fields, helping crops grow deeper root systems. Some garden flowers originated as weeds in cultivated fields and have been selectively bred for their garden-worthy flowers or foliage. An example of a crop weed that is grown in gardens is the corncockle, (Agrostemma githago), which was a common weed in European wheat fields, but is now sometimes grown as a garden plant.[49]

Ecological role

As pioneer species, weeds begin the process of ecological succession after a disturbance event. The rapid, aggressive growth of weeds rapidly prevents erosion in newly exposed bare soil, and has substantially slowed topsoil loss due to anthropogenic disturbances.[50]

In climate change adaptation

It has been suggested that weeds, with their aggressive ability to adapt, could provide humans with vital tools and knowledge for climate change adaptation. Some researchers argue that researching weed species could offer valuable insights for crop breeding, or that weeds themselves hold potential as hardy, climate-change-resistant crops. Adaptable weeds could also be a source of transgenic genes which could confer useful traits upon crops.[22]

Weed species have been used in the restoration of land in Australia using a method called natural sequence farming. This method allows non-native weeds to stabilize and restore degraded areas where native species are not yet capable of regenerating themselves.[51]

Weeds as adaptable species

"We've got to be one of the most bomb-proof species on the planet."

— Paleontologist David Jablonsky[11]

An alternate definition often used by biologists is any species, not just plants, that can quickly adapt to any environment.[11] Some traits of weedy species are the ability to reproduce quickly, disperse widely, live in a variety of habitats, establish a population in strange places, succeed in disturbed ecosystems and resist eradication once established. Such species often do well in human-dominated environments as other species are not able to adapt. Common examples include the common pigeon, brown rat and the raccoon. Other weedy species have been able to expand their range without actually living in human environments, as human activity has damaged the ecosystems of other species. These include the coyote, the white-tailed deer and the brown headed cowbird.[11]

In response to the idea that humans may face extinction due to environmental degradation, paleontologist David Jablonsky counters by arguing that humans are a weed species. Like other weedy species, humans are widely dispersed in a wide variety of environments, and are highly unlikely to go extinct no matter how much damage the environment faces.[11]

Plants often considered to be weeds

White clover

White clover is considered by some to be a weed in lawns, but in many other situations is a desirable source of fodder, honey and soil nitrogen.[52][53]

A short list of some plants that often are considered to be weeds follows:

Many invasive weeds were introduced deliberately in the first place, and may have not been considered nuisances at the time, but rather beneficial.

Weed control

A field of beets being weeded in Colorado, United States, in 1972

Weed control encompasses a range of methods used by humans to stop, reduce or prevent the growth and reproduction of weeds within agricultural or other managed environments. Some weed control is preventative, implementing protocols to stop weeds from invading new areas. Cultural weed control involves shaping the managed environment to make it less favorable for weeds.[56][57] Once weeds are present in an area, a wide variety of means to destroy the weeds and their seeds can be employed. Since weeds are highly adaptable, relying on a single method to control weeds soon results in the invasion or adaptation of weeds that are not susceptible. Integrated pest management as it applies to weeds refers to a plan of controlling weeds that integrates multiple methods of weed control and prevention.[58]

Methods of preventative weed control include cleaning equipment, stopping existing weeds in nearby areas from producing seed, and avoiding seed or manure that could be contaminated with weeds.[59] A wide variety of cultural weed control methods are used, including cover cropping, crop rotation, selecting the most competitive cultivars of crops, mulching, planting with optimal density, and intercropping.[60]

Mechanical methods of weed control involve physically cutting, uprooting, or otherwise destroying weeds. On small farms, hand weeding is the dominant means of weed control, but as larger farms dominate agriculture, this method becomes less feasible.[6] On many operations, however, some hand-weeding may be an unavoidable component of weed control.[57] Tillage, mowing, and burning are common examples of mechanical weed control on larger scales. New technology increases the range of mechanical weed control options. One newly emerging form of mechanical weed control uses electricity to kill weeds.[61]

Mechanical weed control has been increasingly replaced by the use of herbicides.[62] The reliance on herbicides has resulted in the rapid evolution of herbicide resistance in weeds, making previously effective herbicide treatments useless for the control of weeds.[63] In particular, glyphosate, which was once considered a revolutionary breakthrough in weed control, was relied upon heavily when it was first introduced to agriculture, resulting in rapid emergence of resistance.[64] As of 2023, 58 weed species have developed resistance to glyphosate.[65]

Herbicide resistance in weeds has rapidly developed into new, increasingly challenging forms as the plants continually evolve. Non-target site resistance, or NTSR, is particularly difficult to counteract, since it may confer resistance to multiple herbicides at once, including herbicides the plants' ancestors were never exposed to.[66] Various methods of adjusting herbicide application to avoid resistance, such as rotating herbicides used and tank mixing herbicides, have all been questioned in terms of their efficacy for preventing resistance from arising.[67]

Understanding the habit of weeds is important for non-chemical methods of weed control, such as plowing, surface scuffling, promotion of more beneficial cover crops, and prevention of seed accumulation in fields. For example, amaranth is an edible plant that is considered a weed by mainstream modern agriculture. It produces copious seeds (up to 1 million per plant) that last many years, and is an early-emergent fast grower. Those seeking to control amaranth quote the mantra "This year’s seeds become next year’s weeds!".[68] However, another view of amaranth values the plant as a resilient food source.[69]

Some people have appreciated weeds for their tenacity, their wildness and even the work and connection to nature they provide. As Christopher Lloyd wrote in The Well-Tempered Garden:

Many gardeners will agree that hand-weeding is not the terrible drudgery that it is often made out to be. Some people find in it a kind of soothing monotony. It leaves their minds free to develop the plot for their next novel or to perfect the brilliant repartee with which they should have encountered a relative's latest example of unreasonableness.[70]

Under climate change

As anthropogenic climate change increases temperatures and atmospheric carbon dioxide, many weeds are expected to become harder to control and to expand their ranges, at the expense of less "weedy" species. For example, kudzu, the infamous invasive vine found throughout the Southeastern United States, is expected to spread northward due to climate change. Increased competitive strength of agricultural weeds in future climate conditions threaten future ability to grow crops. Existing weed management practices will likely fail under future changes in climate conditions, meaning new agricultural techniques will be needed for global food security. Suggested techniques are holistic, transitioning away from reliance on herbicide, and include aggressive adaptation of agroforestry and use of allelopathic crop residues to suppress weeds.[71]

See also

References

  1. ^ a b Bridges, David C. (1994). "Impact of Weeds on Human Endeavors". Weed Technology. 8 (2): 392–395. doi:10.1017/S0890037X00038987. JSTOR 3988124. S2CID 90116503.
  2. ^ a b Harlan, J. R., & deWet, J. M. (1965). Some thoughts about weeds. Economic botany, 19(1), 16-24.
  3. ^ "Define the term weed". forages.oregonstate.edu. Oregon State University Forage Information System. June 2009.
  4. ^ a b "What is a Weed". Snohomish County Extension Office.
  5. ^ Holzner, W., & Numata, M. (Eds.). (2013). Biology and ecology of weeds (Vol. 2). Springer Science & Business Media.[page needed]
  6. ^ a b Chauhan, BS (2020). "Grand Challenges in Weed Management". Front. Agron. 1 (3). doi:10.3389/fagro.2019.00003.
  7. ^ Nakano, Michelle (13 February 2020). "21: Characteristics of weedy species". Red Seal Landscape Horticulturist Identify Plants and Plant Requirements. Kwantlen Polytechnic University.
  8. ^ a b Janick, Jules (1979). Horticultural Science (3rd ed.). San Francisco: W.H. Freeman. p. 308. ISBN 0-7167-1031-5.
  9. ^ Stromberg, Juliet C. (2023). Bringing Home the Wild: A Riparian Garden in a Southwest City. Tucson: University of Arizona Press. p. 29. ISBN 978-0-8165-5028-9.
  10. ^ a b c Guglielmini, A.C.; Ghersa, C.M.; Satorre, Emilio Horacio (2007). "Co-evolution of domesticated crops and associated weeds". Ecologia Austral. 17 (1).
  11. ^ a b c d e David Quammen (October 1998), "Planet of Weeds" (PDF), Harper's Magazine, retrieved November 15, 2012
  12. ^ Blackshaw, R. E., Anderson, R. L., & Lemerle, D. E. I. R. D. R. E. (2007). Cultural weed management. Non-Chemical Weed Management: Principles, Concepts and Technology, Wallingford, UK: CAB International, 35-48.
  13. ^ Ainit Snir; et al. (22 July 2015). "The Origin of Cultivation and Proto-Weeds, Long Before Neolithic Farming". PLOS ONE. 10 (7): e0131422. Bibcode:2015PLoSO..1031422S. doi:10.1371/journal.pone.0131422. PMC 4511808. PMID 26200895.
  14. ^ Bell, Carl E. "A Historical View of Weed Control Technology". UC Weed Science.
  15. ^ Holm, LeRoy G.; Plucknett, Donald L.; Pancho, Juan V.; Herberger, James P. (1977). The World's Worst Weeds: distribution and biology. Honolulu: University Press of Hawaii. p. ix. ISBN 0-8248-0295-0.
  16. ^ Genesis 3:17-19 New International Version
  17. ^ Timmons, F.L. (2005). "A History of Weed Control in the United States and Canada". Weed Science. 53 (6): 748–761. doi:10.1614/0043-1745(2005)053[0748:AHOWCI]2.0.CO;2. JSTOR 4046973. S2CID 86059980.
  18. ^ a b c Clayton, Neil (2003). "Weeds, People, and Contested Places" (PDF). Environment and History. 9 (3): 304, 306, 308-309. doi:10.3197/096734003129342863. JSTOR 20723295.
  19. ^ Pooler, C[harles] Knox, ed. (1918). The Works of Shakespeare: Sonnets. The Arden Shakespeare [1st series]. London: Methuen & Company. OCLC 4770201.
  20. ^ a b "A history of weeding". More than Weeds. 24 April 2020.
  21. ^ a b c d Falck, Zachary J.S. (2002). "Controlling the Weed Nuisance in Turn-of-the-Century American Cities". Environmental History. 7 (4): 613, 616, 621. doi:10.2307/3986059. JSTOR 3986059.
  22. ^ a b c d Clements, David R.; Jones, Vanessa L. (2021). "Ten Ways That Weed Evolution Defies Human Management Efforts Amidst a Changing Climate". Agronomy. 11 (2): 284. doi:10.3390/agronomy11020284.
  23. ^ Bell, Graham (2005). The Permaculture Garden. Chelsea Green Publishing. pp. 63–64. ISBN 9781856230278.
  24. ^ Baker, Herbert G. (November 1974). "The Evolution of Weeds". Annual Review of Ecology and Systematics. 5 (1): 1–24. doi:10.1146/annurev.es.05.110174.000245. ISSN 0066-4162.
  25. ^ Baker H. G. "Characteristics and modes of origin of weeds". In The Genetics of Colonizing Species. H. G. Baker, G. L. Stebbins. eds. New York, Academic Press, 1965, pp. 147-172
  26. ^ Hans Lambers; F Stuart Chapin III; Thijs L. Pons (8 October 2008). Plant Physiological Ecology. Springer. pp. 507–. ISBN 978-0-387-78341-3.
  27. ^ Sharma, Gourav; Barney, Jacob N.; Westwood, James H.; Haak, David C. (2021). "Into the weeds: new insights in plant stress". Trends in Plant Science. 26 (10): 1050–1060. Bibcode:2021TPS....26.1050S. doi:10.1016/j.tplants.2021.06.003. PMID 34238685.
  28. ^ a b c Clements, David R.; Jones, Vanessa (2021). "Rapid Evolution of Invasive Weeds Under Climate Change: Present Evidence and Future Research Needs". Frontiers in Agronomy. 3. doi:10.3389/fagro.2021.664034.
  29. ^ Saupe, Stephen G. "Plant Foraging: Two Case Studies" (PDF). Retrieved February 15, 2009.
  30. ^ Ziska, Lewis H.; Blumenthal, Dana M.; Franks, Steven J. (2019). "Understanding the nexus of rising CO2, climate change, and evolution in weed biology". Invasive Plant Science and Management. 12 (2): 79–88. doi:10.1017/inp.2019.12. S2CID 199632010.
  31. ^ Rashid M. Hassan; Robert Scholes; Neville Ash (14 December 2005). Ecosystems and Human Well-Being: Current State and Trends: Findings of the Condition and Trends Working Group. Island Press. pp. 570–. ISBN 978-1-55963-228-7.
  32. ^ National Geographic (2011). National Geographic Answer Book: 10,001 Fast Facts about Our World. National Geographic Society. pp. 175–. ISBN 978-1-4262-0892-8.
  33. ^ "Biological Control of Klamath Weed < Hypericum perforatum". faculty.ucr.edu.
  34. ^ "Chrysolina quadrigemina". biocontrol.entomology.cornell.edu. College of Agriculture and Life Sciences. Retrieved 25 July 2023.
  35. ^ Willis, Rick J. (2007). The History of Allelopathy. Springer. p. 8. ISBN 978-1-4020-4092-4. Retrieved 2009-08-17.
  36. ^ "Callaway.qxd" (PDF). Archived from the original (PDF) on September 10, 2006. Retrieved 2010-03-20.
  37. ^ Van der Putten, W. H.; Mortimer, S. R.; Hedlund, K.; Van Dijk, C.; Brown, V. K.; Lepä, J.; Rodriguez-Barrueco, C.; Roy, J.; Diaz Len, T. A.; Gormsen, D.; Korthals, G. W.; Lavorel, S.; Regina, I. Santa; Smilauer, P. (2000-07-01). "Plant species diversity as a driver of early succession in abandoned fields: a multi-site approach". Oecologia. 124 (1): 91–99. Bibcode:2000Oecol.124...91V. doi:10.1007/s004420050028. ISSN 1432-1939. PMID 28308417. S2CID 38703575.
  38. ^ Buswell, Joanna; Moles, Angela; Hartley, Stephen (2010). "Is rapid evolution common in introduced plant species?". Journal of Ecology. 99 (1).
  39. ^ Coupe, Sheena, ed. (1989). Frontier country: Australia's outback heritage. Vol. 1. Willougby: Weldon Russell. p. 298.
  40. ^ Muhammad Ashraf; Münir Öztürk; Muhammad Sajid Aqeel Ahmad; Ahmet Aksoy (2 June 2012). Crop Production for Agricultural Improvement. Springer. pp. 525–. ISBN 978-94-007-4116-4.
  41. ^ United States. Bureau of Land Management. Oregon State Office (1985). Northwest area noxious weed control program: environmental impact statement : final. U.S. Dept. of the Interior, Bureau of Land Management, Oregon State Office. pp. 2–.
  42. ^ House (U S ) Office of the Law Revision (25 April 2008). United States Code, 2006, V. 3, Title 7, Sections 701-End. Government Printing Office. pp. 1230–. ISBN 978-0-16-079998-3.
  43. ^ Annecke, D. R.; Moran, V. C. (1982). Insects and mites of cultivated plants in South Africa. London: Butterworths. ISBN 0-409-08398-4.
  44. ^ Watt, John Mitchell; Breyer-Brandwijk, Maria Gerdina (1962). The Medicinal and Poisonous Plants of Southern and Eastern Africa (2nd ed.). E & S Livingstone.
  45. ^ Roberts, John; Jackson, Nick; Smith, Mark (2006). Tree Roots in the Built Environment. The Stationery Office. ISBN 978-0117536203.
  46. ^ "Black Willow". Weeds Australia. Archived from the original on 2015-07-11.
  47. ^ Holm, LeRoy G.; Plucknett, Donald L.; Pancho, Juan V.; Herberger, James P. (1977). The World's Worst Weeds: distribution and biology. Honolulu: University Press of Hawaii. p. xi. ISBN 0-8248-0295-0.
  48. ^ "Burdock Root". Chinese Soup Pot. Retrieved 29 May 2015.
  49. ^ Preston, Pearman & Dines. (2002). New Atlas of the British Flora. Oxford University Press.
  50. ^ Schonbeck, Mark. "An Ecological Understanding of Weeds". eOrganic.
  51. ^ Kenyon, Georgina. "How weeds help fight climate change". bbc.com. BBC Future.
  52. ^ Voisin, Andre (1988). Grass Productivity. Island Press. ISBN 978-0933280649.
  53. ^ Woodfield, Derek R. White clover, New Zealand's competitive edge. Symposium NZ Agronomy Society and Grassland Association at Lincoln University, New Zealand, November, 1995
  54. ^ Nations, Food and Agriculture Organization of the United (1982). Agrochemicals, Fate in Food and the Environment: Proceedings of an International Symposium on Agrochemicals: Fate in Food and the Environment Using Isotope Techniques. International Atomic Energy Agency. ISBN 978-92-0-010382-7.
  55. ^ "Weed Risk Assessment for Imperata cylindrica (L.) P. Beauv. (Poaceae) – Cogongrass" (PDF). Animal and Plant Health Inspection Service U.S. Department of Agriculture.
  56. ^ "Describe the five general categories of weed control methods". forages.oregonstate.edu. Oregon State University. June 2009.
  57. ^ a b "General Methods of Weed Management". ipm.ucanr.edu. University of California Agriculture and Natural Resources.
  58. ^ Pittman, Kara; Flessner, Michael; Rubione, Claudio; Ackroyd, Victoria; Mirsky, Steven. "What Is Integrated Weed Management?". growiwm.org.
  59. ^ "Weed prevention". Alberta.ca. 24 April 2024.
  60. ^ Mohler, Charles L.; Teasdale, John R.; DiTommaso, Antonio. "Ch 3. Cultural Weed Management". sare.org. Sustainable Agriculture Research and Education.
  61. ^ Claver, Hugo (12 September 2022). "Electric weeding with high frequency electricity gives better weed control with lower energy use". futurefarming.com.
  62. ^ Gianessi, Leonard P (2013). "The increasing importance of herbicides in worldwide crop production". Pest Manag. Sci. 69 (10): 1099–1105. doi:10.1002/ps.3598. PMID 23794176.
  63. ^ Forouzesh, Abed; Zand, Eskandar; Soufizadeh, Saeid; Samadi Foroushani, Sadegh (2015). "Classification of herbicides according to chemical family for weed resistance management strategies–an update". Weed Research. 55 (4): 334–358. Bibcode:2015WeedR..55..334F. doi:10.1111/wre.12153.
  64. ^ Service, R. F. (2013). "What Happens when Weed Killers Stop Killing?". Science. 341 (6152): 1329. doi:10.1126/science.341.6152.1329. PMID 24052282.
  65. ^ "Number of Resistant Species to Individual Active Herbicides". weedscience.org.
  66. ^ Brown, H. Claire (18 August 2021). "Attack of the Superweeds". The New York Times.
  67. ^ Quinn, Lauren. "Tank mixing herbicides may not be enough to avoid herbicide resistance". farmers advance.com.
  68. ^ "The Biology and Ecology of Palmer Amaranth: Implications for Control". UGA extension. Archived from the original on 27 April 2015. Retrieved 29 May 2015.
  69. ^ "Rethinking a Weed: the Truth about Amaranth". Our World. United Nations University.
  70. ^ Christopher Lloyd, The Well-Tempered Garden, 1973
  71. ^ Anwar, Parvez; Islam, A.K.M. Mominul; Yeasmin, Sabina; Rashid, Harun; Juraimi, Abdul Shukor; Ahmed, Sharif; Shrestha, Anil (2021). "Weeds and Their Responses to Management Efforts in A Changing Climate". Agronomy. 11 (10): 1921. doi:10.3390/agronomy11101921.