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===Conservation tillage===
===Conservation tillage===
Conservation tillage<ref group="note" name="Systems" /> leaves at least 30% of crop residue on the soil surface, or at least 1,000&nbsp;lb/ac (1,100&nbsp;kg/ha) of small grain residue on the surface during the critical [[soil erosion]] period. This slows water movement, which reduces the amount of [[soil erosion]]. Conservation tillage also benefits farmers by reducing fuel consumption and soil compaction. By reducing the number of times the farmer travels over the field, farmers realize significant savings in fuel and labor. In most years since 1997, conservation tillage was used in US cropland more than intensive or reduced tillage.<ref name=CRM />
Conservation tillage<ref group="note" name="Systems" /> leaves at least 30% of crop residue on the soil surface, or at least 1,000&nbsp;lb/ac (1,100&nbsp;kg/ha) of small grain residue on the surface during the critical [[soil erosion]] period. This slows water movement, which reduces the amount of [[soil erosion]]. Conservation tillage also benefits farmers by reducing fuel consumption and soil compaction. By reducing the number of times the farmer travels over the field, farmers realize significant savings in fuel and labor. In most years since 1997, conservation tillage was used in US cropland more than intensive or reduced tillage.<ref name=CRM />this tillage is efficient in increasing infiltration


However, conservation tillage delays warming of the soil due to the reduction of dark earth exposure to the warmth of the spring sun, thus delaying the planting of the next year's spring crop of corn.<ref>{{cite web|url=http://www.ag.ndsu.edu/pubs/ageng/machine/AE-1370/ae1370.htm |title=Strip Till for Field Crop Production |publisher=Ag.ndsu.edu |date=2012-11-14 |accessdate=2012-12-20}}</ref>
However, conservation tillage delays warming of the soil due to the reduction of dark earth exposure to the warmth of the spring sun, thus delaying the planting of the next year's spring crop of corn.<ref>{{cite web|url=http://www.ag.ndsu.edu/pubs/ageng/machine/AE-1370/ae1370.htm |title=Strip Till for Field Crop Production |publisher=Ag.ndsu.edu |date=2012-11-14 |accessdate=2012-12-20}}</ref>

Revision as of 14:32, 5 May 2016

Cultivating after an early rain

Tillage is the agricultural preparation of soil by mechanical agitation of various types, such as digging, stirring, and overturning. Examples of human-powered tilling methods using hand tools include shovelling, picking, mattock work, hoeing, and raking. Examples of draft-animal-powered or mechanized work include ploughing (overturning with moldboards or chiseling with chisel shanks), rototilling, rolling with cultipackers or other rollers, harrowing, and cultivating with cultivator shanks (teeth). Small-scale gardening and farming, for household food production or small business production, tends to use the smaller-scale methods above, whereas medium- to large-scale farming tends to use the larger-scale methods. There is a fluid continuum, however. Any type of gardening or farming, but especially larger-scale commercial types, may also use low-till or no-till methods as well.

Tillage is often classified into two types, primary and secondary. There is no strict boundary between them so much as a loose distinction between tillage that is deeper and more thorough (primary) and tillage that is shallower and sometimes more selective of location (secondary). Primary tillage such as ploughing tends to produce a rough surface finish, whereas secondary tillage tends to produce a smoother surface finish, such as that required to make a good seedbed for many crops. Harrowing and rototilling often combine primary and secondary tillage into one operation.

"Tillage" can also mean the land that is tilled. The word "cultivation" has several senses that overlap substantially with those of "tillage". In a general context, both can refer to agriculture. Within agriculture, both can refer to any of the kinds of soil agitation described above. Additionally, "cultivation" or "cultivating" may refer to an even narrower sense of shallow, selective secondary tillage of row crop fields that kills weeds while sparing the crop plants.

Tillage systems

Reduced tillage

File:Ploughtilling the field.jpg
Plough tilling the field

Reduced tillage[note 1] leaves between 15 and 30% residue cover on the soil or 500 to 1000 pounds per acre (560 to 1100 kg/ha) of small grain residue during the critical erosion period. This may involve the use of a chisel plow, field cultivators, or other implements. See the general comments below to see how they can affect the amount of residue.

Intensive tillage

Intensive tillage[note 1] leaves less than 15% crop residue cover or less than 500 pounds per acre (560 kg/ha) of small grain residue. This type of tillage is often referred to as conventional tillage but as conservational tillage is now more widely used than intensive tillage (in the United States),[1][2] it is often not appropriate to refer to this type of tillage as conventional. Intensive tillage often involves multiple operations with implements such as a mold board, disk, and/or chisel plow. Then a finisher with a harrow, rolling basket, and cutter can be used to prepare the seed bed. There are many variations.

Conservation tillage

Conservation tillage[note 1] leaves at least 30% of crop residue on the soil surface, or at least 1,000 lb/ac (1,100 kg/ha) of small grain residue on the surface during the critical soil erosion period. This slows water movement, which reduces the amount of soil erosion. Conservation tillage also benefits farmers by reducing fuel consumption and soil compaction. By reducing the number of times the farmer travels over the field, farmers realize significant savings in fuel and labor. In most years since 1997, conservation tillage was used in US cropland more than intensive or reduced tillage.[2]this tillage is efficient in increasing infiltration

However, conservation tillage delays warming of the soil due to the reduction of dark earth exposure to the warmth of the spring sun, thus delaying the planting of the next year's spring crop of corn.[3]

  • No-till - Never use a plow, disk, etc. ever again. Aims for 100% ground cover.
  • Strip-Till - Narrow strips are tilled where seeds will be planted, leaving the soil in between the rows untilled.[4]
  • Mulch-till
  • Rotational Tillage - Tilling the soil every two years or less often (every other year, or every third year, etc.).[4]
  • Ridge-Till
  • Zone tillage - This form of conservation tillage is further explained below.

Zone tillage

Zone tillage is a form of modified deep tillage in which only narrow strips are tilled, leaving soil in between the rows untilled. This type of tillage agitates the soil to help reduce soil compaction problems and to improve internal soil drainage.[5]


Purpose

Zone tillage is designed to only disrupt the soil in a narrow strip directly below the crop row. In comparison to no-till, which relies on the previous year’s plant residue to protect the soil and aides in postponement of the warming of the soil and crop growth in Northern climates, zone tillage creates approximately a 5-inch-wide strip that simultaneously breaks up plow pans, assists in warming the soil and helps to prepare a seedbed.[6] When combined with cover crops, zone tillage helps replace lost organic matter, slows the deterioration of the soil, improves soil drainage, increases soil water and nutrient holding capacity, and allows necessary soil organisms to survive.

Usage

It has been successfully used on farms in the mid-west and west for over 40 years and is currently used on more than 36% of the U.S. farmland.[7] Some specific states where zone tillage is currently in practice are Pennsylvania, Connecticut, Minnesota, Indiana, Wisconsin, and Illinois.

Unfortunately, there aren't consistent yield results in the Northern Cornbelt states however; there is still interest in deep tillage within the agriculture industry.[8] In areas that are not well-drained, deep tillage may be used as an alternative to installing more expensive tile drainage.[9]

Effects of tillage

Positive

Plowing:

  • Loosens and aerates the top layer of soil, which facilitates planting the crop[10]
  • Helps mix harvest residue, organic matter (humus), and nutrients evenly into the soil[10]
  • Mechanically destroys weeds[10]
  • Dries the soil before seeding (in wetter climates tillage aids in keeping the soil drier)[10]
  • When done in autumn, helps exposed soil crumble over winter through frosting and defrosting, which helps prepare a smooth surface for spring planting[10]

Negative

  • Dries the soil before seeding[10]
  • Soil loses a lot of nutrients, like nitrogen and fertilizer, and its ability to store water[10][note 2]
  • Decreases the water infiltration rate of soil. (Results in more runoff and erosion[10][11] since the soil absorbs water slower than before)[note 3]
  • Tilling the soil results in dislodging the cohesiveness of the soil particles thereby inducing erosion.
  • Chemical runoff[10][note 3]
  • Reduces organic matter in the soil[10][note 4]
  • Reduces microbes, earthworms, ants, etc.[12]
  • Destroys soil aggregates[10][12]
  • Compaction of the soil, also known as a tillage pan[10][12][note 2][note 3]
  • Eutrophication (nutrient runoff into a body of water)[note 3]
  • Can attract slugs, cut worms, army worms, and harmful insects to the left over residues.[13]
  • Crop diseases can be harbored in surface residues[13]

General comments

  • The type of implement makes the most difference, although other factors can have an effect.[14]
  • Tilling in absolute darkness (night tillage) might reduce the number of weeds that sprout following the tilling operation by half. Light is necessary to break the dormancy of some weed species' seed, so if fewer seeds are exposed to light during the tilling process, fewer will sprout. This may help reduce the amount of herbicides needed for weed control.[15]
  • Greater speeds, when using certain tillage implements (disks and chisel plows), lead to more intensive tillage (i.e., less residue is on the soil surface).
  • Increasing the angle of disks causes residues to be buried more deeply. Increasing their concavity makes them more aggressive.
  • Chisel plows can have spikes or sweeps. Spikes are more aggressive.
  • Percentage residue is used to compare tillage systems because the amount of crop residue affects the soil loss due to erosion.[14][16]
  • See Soybean management practices to see what types of tillage are currently recommended for Soybean Production.

Definitions

Primary tillage loosens the soil and mixes in fertilizer and/or plant material, resulting in soil with a rough texture.

Secondary tillage produces finer soil and sometimes shapes the rows, preparing the seed bed. It also provides weed control throughout the growing season during the maturation of the crop plants, unless such weed control is instead achieved with low-till or no-till methods involving herbicides.

  • The seed bed preparation can be done with harrows (of which there are many types and subtypes), dibbles, hoes, shovels, rotary tillers, subsoilers, ridge- or bed-forming tillers, rollers, or cultivators.
  • The weed control, to the extent that it is done via tillage, is usually achieved with cultivators or hoes, which disturb the top few centimeters of soil around the crop plants but with minimal disturbance of the crop plants themselves. The tillage kills the weeds via 2 mechanisms: uprooting them, burying their leaves (cutting off their photosynthesis), or a combination of both. Weed control both prevents the crop plants from being outcompeted by the weeds (for water and sunlight) and prevents the weeds from reaching their seed stage, thus reducing future weed population aggressiveness.

History of tilling

Tilling with Hungarian Grey cattles

Tilling was first performed via human labor, sometimes involving slaves. Hoofed animals could also be used to till soil via trampling. The wooden plow was then invented. It could be pulled by mule, ox, elephant, water buffalo, or similar sturdy animal. Horses are generally unsuitable, though breeds such as the scyne could work. The steel plow allowed farming in the American Midwest, where tough prairie grasses and rocks caused trouble. Soon after 1900, the farm tractor was introduced, which eventually made modern large-scale agriculture possible.

Alternatives to tilling

Modern agricultural science has greatly reduced the use of tillage. Crops can be grown for several years without any tillage through the use of herbicides to control weeds, crop varieties that tolerate packed soil, and equipment that can plant seeds or fumigate the soil without really digging it up. This practice, called no-till farming, reduces costs and environmental change by reducing soil erosion and diesel fuel usage. Researchers are investigating farming in polyculture that would eliminate the need for both tillage and pesticides, such as no-dig gardening.

See also

Notes

  1. ^ a b c Since each type of tillage type has more than one type of equipment that may be used, the tillage types may be referred to in the plural by adding the term "systems" ie: Reduced tillage systems, intensive tillage systems, conservation tillage systems.
  2. ^ a b However, see zone tillage
  3. ^ a b c d However, see conservation tillage
  4. ^ However, see cover crops

References

  1. ^ "CONSERVATION TILLAGE IN THE UNITED STATES: AN OVERVIEW". okstate.edu. Institute of Agriculture and Natural Resources, University of Nebraska – Lincoln U.S.A. p. Figure 2. Retrieved 8 July 2013.
  2. ^ a b "National Crop Residue Management (CRM) Survey Summary (various years)". ctic.purdue.edu. Conservation Technology Information Center.
  3. ^ "Strip Till for Field Crop Production". Ag.ndsu.edu. 14 November 2012. Retrieved 20 December 2012.
  4. ^ a b "Best Management Practices for Conservation/Reduced Tillage" (PDF). Texas Cooperative Extension, The Texas A&M University System.
  5. ^ [1], UMassAmherst. Vegetable Program. "Deep Zone Tillage", 2012.
  6. ^ [2] Pennsylvania State University. "Evaluation of Zone Tillage for Corn Production", 2002.
  7. ^ [3], Boucher,J. University of Connecticut. "Soil Health and Deep-Zone Tillage", 2008.
  8. ^ [4], "Fall Zone Tillage Conserves Soil, Yields Well", 1999.
  9. ^ [5], DeJong-Hughes, J. Johnson, J. Plant Management Network. 2009.
  10. ^ a b c d e f g h i j k l Ray Hilborn. "Soils in Agriculture" (PPT--available as non-PPT by searching the path through a search engine). University of Washington. Retrieved 28 August 2013.
  11. ^ Gebhardt_et_al. 1985
  12. ^ a b c "Soil Compaction and Conservation Tillage". Conservation Tillage Series. PennState- College of Agricultural Sciences - Cooperative Extension. Retrieved 26 March 2011.
  13. ^ a b http://www.tbars.net/alternativetil.pdf
  14. ^ a b Conservation Tillage and Residue Management to Reduce Soil Erosion University of Missouri: Extension
  15. ^ "Nightmare in Tilling Fields - a Horror for Weed Pests". Ars.usda.gov. Retrieved 5 July 2012.
  16. ^ Mahdi Al-Kaisi, Mark Hanna, Michael Tidman (13 May 2002). "Methods for measuring crop residue". Iowa State University. Retrieved 28 December 2012.{{cite web}}: CS1 maint: multiple names: authors list (link)

Bibliography

Further reading

  • Brady, Nyle C.; R.R. Weil (2002). The nature and property of soils, 13th edition. New Jersey: Prentice Hall. ISBN 0-13-016763-0.