No-till farming

Young soybean plants thrive in and are protected by the residue of a wheat crop. This form of no till farming provides good protection for the soil from erosion and helps retain moisture for the new crop.

No-till farming (also called zero tillage or direct drilling) is a way of growing crops or pasture from year to year without disturbing the soil through tillage. No-till is an agricultural technique which increases the amount of water that infiltrates into the soil and increases organic matter retention and cycling of nutrients in the soil. In many agricultural regions it can reduce or eliminate soil erosion. It increases the amount and variety of life in and on the soil, including disease-causing organisms and disease suppression organisms. The most powerful benefit of no-tillage is improvement in soil biological fertility, making soils more resilient. Farm operations are made much more efficient, particularly improved time of sowing and better trafficability of farm operations.

Background

Tilling is the process of removing plants or plant debris, usually for the purposes of planting more desirable species. This tilling can result in a flat seed bed or one that has formed areas, such as rows or raised beds, to enhance the growth of desired plants. It is an ancient technique with clear evidence of its use since at least 3000 B.C.[1]

The effects of tillage can include soil compaction; loss of organic matter; degradation of soil aggregates; death or disruption of soil microbes and other organisms including mycorrhizae, arthropods, and earthworms;[2] and soil erosion where topsoil is washed or blown away.

Origin of No-till for modern farms

The idea of modern no-till farming started in the 1940s with Edward H. Faulkner, author of Plowman's Folly,[3] but it wasn't until the development of several chemicals after WWII that various researchers and farmers started to try out the idea. The first adopters of no-till include Klingman (North Carolina), Edward Faulkner, L.A. Porter (New Zealand), Harry and Lawrence Young (Herndon, Kentucky), the Instituto de Pesquisas Agropecuarias Meridional (1971 in Brazil) with Herbert Bartz.[4]

Adoption rate in the United States

No-till farming is widely used in the United States and the number of acres managed in this way continues to grow. This growth is supported by a decrease in costs related to tillage; no-till management results in fewer passes with equipment for approximately equal harvests, and the crop residue prevents evaporation of rainfall and increases water infiltration into the soil.[5]

Issues

Profit, economics, yield

Studies have found that no-till farming can be more profitable[6][7] if performed correctly.[8]

Less tillage of the soil reduces labour,[9] fuel,[10] irrigation[11] and machinery costs.[7] No-till can increase yield because of higher water infiltration and storage capacity, and less erosion.[8] Another benefit of no-till is that because of the higher water content, instead of leaving a field fallow it can make economic sense to plant another crop instead.[12]

As sustainable agriculture becomes more popular, monetary grants and awards are becoming readily available to farmers who practice conservation tillage. Some large energy corporations which are among the greatest generators of fossil-fuel-related pollution may purchase carbon credits, which can encourage farmers to engage in conservation tillage.[13][14] Under such schemes, the farmers' land is legally redefined as a carbon sink for the power generators' emissions. This helps the farmer in several ways , and it helps the energy companies meet regulatory demands for reduction of pollution, specifically carbon emissions.

No-till farming can increase organic (carbon based)[8] matter in the soil, which is a form of carbon sequestration. However, there is debate over whether this increased sequestration detected in scientific studies of no-till agriculture is actually occurring, or is due to flawed testing methods or other factors.[15] Regardless of this debate, a case can still be made for no-till, in the form of reduction in fossil fuel use, less erosion and better soil quality.

Environmental

Carbon (air and soil) and other greenhouse gases

No-till farming has carbon sequestration potential through storage of soil organic matter in the soil of crop fields.[16] Whereas, when soil is tilled by machinery, the soil layers invert, air mixes in, and soil microbial activity dramatically increases over baseline levels. Tilling results in soil organic matter being broken down much more rapidly, and carbon is lost from the soil into the atmosphere. In addition to the effect on soil from tilling, emissions from the farm tractors increases carbon dioxide levels in the atmosphere.

Cropland soils are ideal for use as a carbon sink, since they have been depleted of carbon in most areas. It is estimated that 78 billion metric tonnes of carbon that was trapped in the soil has been released[17] because of tillage. Conventional farming practices that rely on tillage have removed carbon from the soil ecosystem by removing crop residues such as left over corn stalks, and through the addition of chemical fertilizers which have the above-mentioned effects on soil microbes. By eliminating tillage, crop residues decompose where they lie, and by growing winter cover crops, carbon loss can be slowed and eventually reversed.

Nonetheless, a growing body of research is showing that no-till systems lose carbon stocks over time. Regarding a 2014 study of which he was principal investigator, University of Illinois soil scientist Ken Olson said this differing result occurs in part because tested soil samples need to include the full depth of rooting; 1–2 meters deep. He said, “That no-till subsurface layer is often losing more soil organic carbon stock over time than is gained in the surface layer.” Also, there has not been a uniform definition of soil organic carbon sequestration among researchers.[18] The study concludes, "Additional investments in SOC research is needed to better understand the agricultural management practices that are most likely to sequester SOC or at least retain more net SOC stocks."[19]

In addition to keeping carbon in the soil, no-till farming reduces nitrous oxide (N2O) emissions by 40-70%, depending on rotation.[20][21] Nitrous oxide is a potent greenhouse gas, 300 times stronger than CO2, and stays in the atmosphere for 120 years.[22] Fertilizing farmlands with (excessive) nitrogen increases the release of nitrous oxide.

Soil and water

No-till farming improves soil quality (soil function), carbon, organic matter, aggregates,[23] protecting the soil from erosion,[24] evaporation of water,[11] and structural breakdown. A reduction in tillage passes helps prevent the compaction of soil.

Recently, researchers at the Agricultural Research Service of the United States Department of Agriculture found that no-till farming makes soil much more stable than plowed soil. Their conclusions draw from over 19 years of collaborated tillage studies. No-till stores more carbon in the soil and carbon in the form of organic matter is a key factor in holding soil particles together. The first inch of no-till soil is two to seven times less vulnerable than that of plowed soil. The practice of no-till farming is especially beneficial to Great Plains farmers because of its avoidance of erosion.[25]

Crop residues left intact help both natural precipitation and irrigation water infiltrate the soil where it can be used. The crop residue left on the soil surface also limits evaporation, conserving water for plant growth. Soil compaction and no tillage-pan, soil absorbs more water and plants are able to grow their roots deeper into the soil and suck up more water.

Tilling a field reduces the amount of water, via evaporation, around 1/3 to 3/4 inches (0.85 to 1.9 cm) per pass.[11] By no-tilling, this water stays in the soil, available to the plants.

Soil biota, wildlife, etc.

In no-till farming the soil is left intact and crop residue is left on the field. Therefore, soil layers, and in turn soil biota, are conserved in their natural state. No-tilled fields often have more beneficial insects and annelids,[26] a higher microbial content, and a greater amount of soil organic material. Since there is no ploughing there is less airborne dust.

No-till farming increases the amount and variety of wildlife.[27] This is the result of improved cover, reduced traffic and the reduced chance of destroying ground nesting birds and animals (plowing destroys all of them).

Albedo

Tillage lowers the albedo of croplands. The potential for global cooling as a result of increased Albedo in no till croplands is similar in magnitude to the biogeochemical (carbon sequestration) potential.[28]

Historical artifacts

Tilling regularly damages ancient structures under the soil such as long barrows. In the UK, half of the long barrows in Gloucestershire and almost all the burial mounds in Essex have been damaged. According to English Heritage modern tillage techniques have done as much damage in the last six decades as traditional tilling did in the previous six centuries. By using no-till methods these structures can be preserved and can be properly investigated instead of being destroyed.[29]

Cost

Equipment

No-till farming requires specialized seeding equipment designed to plant seeds into undisturbed crop residues and soil. If the farmer has equipment designed for tillage farming, purchasing new equipment (seed drills for example) would be expensive and while the cost could be offset by selling off plows, etc. doing so is not usually done until the farmer decides to switch completely over (after trying it out for a few years). This would result in more money being invested into equipment in the short term (until old equipment is sold off).[30]

Drainage

If a soil has poor drainage, it may need drainage tiles or other devices in order to help with the removal of excess water under no-till. Farmers should remember that water infiltration will improve after several years of a field being in no-till farming, so they may want to wait until 5–8 years have passed to see if the problems persists before deciding to invest in such an expensive system.

Gullies

Gullies can be a problem in the long-term. While much less soil is displaced by using no-till farming, any drainage gulleys that do form will get deeper each year since they aren't being smoothed out by plowing.[31] This may necessitate either sod drainways, waterways, permanent drainways, cover crops, etc. Gully formation can be avoided entirely with proper water management practices, including the creation of swales on contour.

Increased chemical use

One of the purposes of tilling is to remove weeds. No-till farming does change weed composition drastically. Faster growing weeds may no longer be a problem in the face of increased competition, but shrubs and trees may begin to grow eventually.

Some farmers attack this problem with a “burn-down” herbicide such as glyphosate in lieu of tillage for seedbed preparation and because of this, no-till is often associated with increased chemical use in comparison to traditional tillage based methods of crop production. However, there are many agroecological alternatives to increased chemical use, such as winter cover crops and the mulch cover they provide, soil solarization or burning.

Management

No-till farming requires some different skills to achieve success. As with any production system, if no-till isn't done correctly, yields can drop. A combination of technique, equipment, pesticides, crop rotation, fertilization, and irrigation have to be used for local conditions.

Cover crops

Cover crops are used occasionally in no-till farming to help control weeds and increase nutrients in the soil (by using legumes)[32] or by using plants with long roots to pull mobile nutrients back up to the surface from lower layers of the soil. Farmers experimenting with organic no-till use cover crops instead of tillage for controlling weeds, and are developing various methods to kill the cover crops (rollers, crimper, choppers, etc.)[33] so that the newly planted crops can get enough light, water, nutrients, etc.[34][35]

Disease, pathogens, insects and the use of crop rotations

With no-till farming, residue from the previous years crops lie on the surface of the field, cooling it and increasing the moisture. This can cause increased or decreased or variations of diseases that occur,[36] but not necessarily at a higher or lower rate than conventional tillage.[37] In order to help eliminate weed, pest and disease problems, crop rotations are used. By rotating the crops on a multi-year cycle, pests and diseases will decrease since the pests will no longer have a food supply to support their numbers.

Organic no-till technique: The cardboard method

Some farmers who prefer to pursue a chemical-free management practice often rely on the use of normal, non-dyed corrugated cardboard for use on seed-beds and vegetable areas. Used correctly, cardboard placed on a specific area can

  1. keep important fungal hyphae and microorganisms in the soil intact
  2. prevent recurring weeds from popping up
  3. increase residual nitrogen and plant nutrients by top-composting plant residues and
  4. create valuable topsoil that is well suited for next years seeds or transplants.

The plant residues (left over plant matter originating from cover crops, grass clippings, original plant life etc.) will rot while underneath the cardboard so long as it remains sufficiently moist. This rotting attracts worms and other beneficial microorganisms to the site of decomposition, and over a series of a few seasons (usually Spring-->Fall or Fall-->Spring) and up to a few years, will create a layer of rich topsoil. Plants can then be direct seeded into the soil come spring, or holes can be cut into the cardboard to allow for transplantation. Using this method in conjunction with other sustainable practices such as composting/vermicompost, cover crops and rotations are often considered beneficial to both land and those who take from it.

Water issues

No-till farming dramatically reduces the amount of erosion in a field. While much less soil is displaced, any gullies that do form will get deeper each year instead of being smoothed out by regular plowing. This may necessitate either sod drainways, waterways, permanent drainways, cover crops, etc.[38]

A problem that occurs in some fields is water saturation in soils. Switching to no-till farming will correct the drainage the because of the qualities of soil under continuous no-till include a higher water infiltration rate.[39]

Equipment

It is very important to have planting equipment that can properly penetrate through the residue, into the soil and prepare a good seedbed.[40] Switching to no-till reduces the maximum amount of power needed from farm tractors, which means that a farmer can farm under no-till with a smaller tractor than under tilling.[41] Using a smaller, lighter tractor has the added benefit of reducing compaction.

Soil temperature

Another problem that growers face is that in the spring the soil will take longer to warm and dry, which may delay planting to a less ideal future date. One reason why the soil is slower to warm is that the field absorbs less solar energy as the residue covering the soil is a much lighter color than the black soil which would be exposed in conventional tillage. This can be managed by using row cleaners on a planter.[42] Since the soil can be cooler, harvest can occur a few days later than a conventionally tilled field. Note: A cooler soil is also a benefit because water doesn't evaporate as fast.

Residue

On some crops, like continuous no-till corn, the thickness of the residue on the surface of the field can become a problem without proper preparation and/or equipment.

Fertilizer

One of the most common yield reducers is nitrogen being immobilized in the crop residue, which can take a few months to several years to decompose, depending on the crop's C to N ratio and the local environment.[43] Fertilizer needs to be applied at a higher rate during the transition period while the soil rebuilds its organic matter. The nutrients in the organic matter will be eventually released back into the soil, so this is only a concern during the transition time frame (4–5 years for Kansas, USA). An innovative solution to this problem is to integrate animal husbandry in various ways to aid in the decomposition cycle.[44]

Misconceptions

Need to fluff the soil

Although no-till farming often causes a slight increase in soil bulk density, periodic tilling is not needed to “fluff” the soil back up. No-till farming mimics the natural conditions under which most soils formed more closely than any other method of farming, in that the soil is left undisturbed except to place seeds in a position to germinate.

Similar terms

No-till farming is not equivalent to conservation tillage or strip tillage. Conservation tillage is a group of practices that reduce the amount of tillage needed. No-till and strip tillage are both forms of conservation tillage. No-till is the practice of never tilling a field. Tilling every other year is called rotational tillage.

See also

References

  1. name=history of tillage
  2. Preston Sullivan (2004). "Sustainable Soil Management". Attra.ncat.org. Retrieved 2010-05-09.
  3. P "Edward Faulkner’s Plowman’s Folly Still a Masterpiece on Soil Quality "
  4. Derpsch, Rolf. "A short History of No-till". NO- TILLAGE. Retrieved 26 March 2011.
  5. name=no till farming on the rise
  6. D.L. Beck, J.L. Miller, and M.P. Hagny "Successful No-Till on the Central and Northern Plains"
  7. 1 2 Derpsch, Rolf. "Economics of No-till farming. Experiences from Latin America." (PDF). Retrieved 2010-05-09.
  8. 1 2 3 "Better Management Practices: No-Till/Conservation Tillage". WWF. Retrieved 4 April 2011.
  9. Time savings from no-till are the result of fewer passes over a field being needed and less time for each pass (its faster to pull a sprayer over a field than a plow through it).
  10. http://ecat.sc.egov.usda.gov/Fuel.aspx
  11. 1 2 3 http://cropwatch.unl.edu/input$/notill_irrigation.htm. Retrieved April 17, 2009. Missing or empty |title= (help)
  12. "Yield & Economic Comparisons: University Research Trials" (PDF). p. 1. Archived from the original (PDF) on 19 May 2005.
  13. "How to Utilize Carbon Credits" (PDF). extension.umn.edu. 7 August 2010. Retrieved 1 March 2015.
  14. "Carbon Credit Program". National Farmers Union. Retrieved 2010-05-09.
  15. Baker et al. (2007) Tillage and soil carbon sequestration—What do we really know?. Journal of Agriculture, Ecosystems & Environment. Volume 118, Issues 1–4
  16. Carbon sequestration in two Brazilian Cerrado soils under no-till Bayer, C | Martin-Neto, L | Mielniczuk, J | Pavinato, A | Dieckow, J Soil and Tillage Research [Soil Tillageyhjs.]. Vol. 86, no. 2, p.237-245. Apr 2006.
  17. Lal, Rattan. "No-Till Farming Offers A Quick Fix To Help Ward Off Host Of Global Problems". Researchnews.osu.edu. Retrieved 2010-05-09.
  18. "No-till soil organic carbon sequestration rates published". Science Daily. Retrieved 2012-04-21. April 18, 2014.
  19. Olson K.R., Al-Kaisi M.M., Lal R., Lowery B. (2014). Experimental Consideration, Treatments, and Methods in Determining Soil Organic Carbon Sequestration Rates. Soil Sci. Soc. Am. J. 78:2:pp.348-360. (Open access).
  20. Omonode, R. A.; Smith, D. R.; Gál, A.; Vyn, T. J. (2011). "Soil Nitrous Oxide Emissions in Corn following Three Decades of Tillage and Rotation Treatments". Soil Science Society of America Journal. 75: 152. doi:10.2136/sssaj2009.0147.
  21. Study: No-till farming reduces greenhouse gas San-Francisco Chronicle
  22. Wallheimer, Brian. "No-till, rotation can limit greenhouse gas emissions from farm fields". physorg.com. Retrieved 26 March 2011.
  23. "Soil Management - The Soil Scientist". Extension.umn.edu. Retrieved 2010-05-09.
  24. "Conservation Tillage". Monsanto.com. Archived from the original on June 20, 2008. Retrieved 2010-05-09.
  25. Blanco-Canqui, H.; Mikha, M. M.; Benjamin, J. G.; Stone, L. R.; Schlegel, A. J.; Lyon, D. J.; Vigil, M. F.; Stahlman, P. W. (2009). "Regional Study of No-Till Impacts on Near-Surface Aggregate Properties that Influence Soil Erodibility". Soil Science Society of America Journal. 73 (4): 1361. doi:10.2136/sssaj2008.0401.
  26. Chan, K.Y. "An overview of some tillage impacts on earthworm population abundance and diversity — implications for functioning in soils". Soil and Tillage Research. 57 (4): 179–191. doi:10.1016/S0167-1987(00)00173-2.
  27. D. B. Warburton and W. D. Klimstra; D. B. Warburton; W. D. Klimstra (1984-09-01). "Wildlife use of no-till and conventionally tilled corn fields". 39 (5). Journal of Soil and Water Conservation. Retrieved 2010-05-09.
  28. D. B. Lobell, G. Bala and P. B. Duffy; D. B. Lobell; G. Bala; P. B. Duffy (2006-03-23). "Biogeophysical impacts of cropland management changes on climate" (PDF). 33. GEOPHYSICAL RESEARCH LETTERS. Retrieved 2012-07-02.
  29. "Ripping Up History" July 2003 English Heritage
  30. "Kansas No-till handbook"
  31. Elton Robinson (Aug 1, 2008). "Tilling ephemeral gullies can cost you soil". Deltafarmpress.com. Retrieved 2010-05-09.
  32. "TIPS FOR NO-TILL PLANTING INTO COVER CROPS" Penn. State University
  33. "Crimping Cover Crops". Conservation Currents. Northern Virginia Soil and Water Conservation District. Retrieved 26 March 2011.
  34. "No-Till Revolution". Rodale Institute. Retrieved 2010-05-09.
  35. George Kuepper (June 2001). "Pursuing Conservation Tillage Systems for Organic Crop Production". Attra.ncat.org. Archived from the original on June 12, 2008. Retrieved 2010-05-09.
  36. Daryl D. Buchholz (October 1993). "No-Till Planting Systems". University of Missouri Extension. Retrieved 2010-05-09.
  37. "Tillage has less effect on crop diseases than other factors". Top Crop Manager. Retrieved 2011-12-04.
  38. Elton Robinson "Tilling ephemeral gullies can cost you soil"
  39. Kindig, Wendy. "No till/Cover Crops Articles". York County Conservation District. Retrieved 2 April 2011.
  40. "Soybeans: No-Till and Minimum Till Guidelines"
  41. Casady, William W. "G1236 Farming With One Tractor"
  42. "Converting To Continuous No-Till"
  43. Hartman, Murray. "Direct Seeding: Estimating the Value of Crop Residues". Government of Alberta: Agriculture and Rural Development. Retrieved 22 March 2011.
  44. Tallman, Susan. "No-Till Case Study, Richter Farm: Cover Crop Cocktails in a Forage-Based System". National Sustainable Agriculture Information Service. NCAT-ATTRA. Retrieved 8 April 2013.
  45. Macrobiotic agriculture
  46. Handboek ecologisch tuinieren by Herman Van Boxem

Further reading

This article is issued from Wikipedia - version of the 11/10/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.