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i like cows they are hot i want to lick there poop
i like cows they are hot i want to lick there poop


the moon is round
==Biodiversity==

{{See also|Genetic erosion|Agricultural biodiversity}}

[[Genetic erosion]] in [[crop]]s and [[livestock]] biodiversity is propelled by several major factors such as variety replacement, land clearing, overexploitation of species, population pressure, environmental degradation, [[overgrazing]], policy and changing agricultural systems. {{Fact|date=November 2007}}

The main factor, however, is the replacement of local varieties of domestic plants and animals by high yielding or exotic varieties or species. A large number of varieties can also often be dramatically reduced when commercial varieties (including [[Genetically Modified Organism|GMO]]s) are introduced into traditional farming systems. Many researchers believe that the main problem related to agro-ecosystem management is the general tendency towards genetic and ecological uniformity imposed by the development of modern agriculture. {{Who|date=November 2007}}

In agriculture and [[animal husbandry]], the [[green revolution]] popularized the use of conventional [[hybrid (biology)|hybridization]] to increase yield many folds by creating "[[high-yielding varieties]]". Often the handful of breeds of plants and animals hybridized originated in developed countries and were further hybridized with local varieties in the rest of the developing world to create high yield strains resistant to local climate and diseases. Hybridization of local breeds to improve performance may lead to the loss of the local breed over time and consequently the loss of specific genetic material due to dilution. When viewed across the world as a whole, the consequent loss in genetic diversity and biodiversity could place agriculture in a situation unable to adapt to sudden changes in the future.

A [[Genetically Modified Organism]] (GMO) is an [[organism]] whose [[gene]]tic material has been [[genetic engineering|altered]] using the [[genetic engineering]] techniques generally known as [[recombinant DNA technology]]. Genetic engineering has vastly expanded the repertoire of genes available to breeders to create the desired properties in future germlines. However, it is hypothesised that these new strains will replace the wild-type species beyond their original fields, and that these genes may be transferred to other plant species that were not intended.


==Lunar Farming==
==Lunar Farming==

Revision as of 19:12, 2 October 2008

Agriculture refers to the production of goods through the growing of plants and the raising of domesticated animals. The study of agriculture is known as agricultural science. The related practice of gardening is studied in horticulture.

Agriculture encompasses a wide variety of specialties. Cultivation of crops on arable land and the pastoral herding of livestock on rangeland remain at the foundation of agriculture. In the past century a distinction has been made between sustainable agriculture and intensive farming. Modern agronomy, plant breeding, pesticides and fertilizers, and technological improvements have sharply increased yields from cultivation. Selective breeding and modern practices in animal husbandry such as intensive pig farming (and similar practices applied to the chicken) have similarly increased the output of meat. The more exotic varieties of agriculture include aquaculture and tree farming.

The major agricultural products can be broadly grouped into foods, fibers, fuels, raw materials, pharmaceuticals and illegal drugs, and an assortment of ornamental or otherwise exotic products. In recent years plants have been used to grow biofuels, biopharmaceuticals, bioplastics,[1] and pharmaceuticals.[2] Specific foods include cereals, vegetables, fruits, and meat. Fibers include cotton, wool, hemp, silk and flax. Raw materials include lumber and bamboo. Drugs include tobacco, marijuana, opium, cocaine, digitalis, curare, eugenol, reserpine, pyrethrins, taxol) and other useful materials such as resins. Biofuels include methane from biomass, ethanol, and biodiesel. Cut flowers, nursery plants, tropical fish and birds for the pet trade are some of the ornamental products.

The history of agriculture has played a major role in human history, as agricultural progress has been a crucial factor in worldwide socio-economic change. Wealth-building and militaristic specializations rarely seen in hunter-gatherer cultures are commonplace in societies which practice agriculture. So, too, are arts such as epic literature and monumental architecture, as well as codified legal systems. When farmers became capable of producing food beyond the needs of their own families, others in their society were freed to devote themselves to projects other than food acquisition. Historians and anthropologists have long argued that the development of agriculture made civilization possible.

In 2007, an estimated 35 percent of the world's workers were employed in agriculture (from 42% in 1996). However, the relative significance of farming has dropped steadily since the beginning of industrialization, and in 2003 – for the first time in history – the services sector overtook agriculture as the economic sector employing the most people worldwide.[3] Despite the fact that agriculture employs over one-third of the world's population, agricultural production accounts for less than five percent of the gross world product (an aggregate of all gross domestic products).[4]

Overview

The amount of workforce dedicated to agriculture tends to decrease.

Agriculture has played a key role in the development of human civilization—it is widely believed that the domestication of plants and animals allowed humans to settle and give up their previous hunter-gatherer lifestyle during the Neolithic Revolution. Until the Industrial Revolution, the vast majority of the human population labored in agriculture. Development of agricultural techniques has steadily increased agricultural productivity, and the widespread diffusion of these techniques during a time period is often called an agricultural revolution. A remarkable shift in agricultural practices has occurred over the past century in response to new technologies. In particular, the Haber-Bosch method for synthesizing ammonium nitrate made the traditional practice of recycling nutrients with crop rotation and animal manure less necessary. Synthetic nitrogen, along with mined rock phosphate, pesticides and mechanization, have greatly increased crop yields in the early 20th century. Increased supply of grains has led to cheaper livestock as well. Further, global yield increases were experienced later in the 20th century when high-yield varieties of common staple grains such as rice, wheat, and corn (maize) were introduced as a part of the Green Revolution. The Green Revolution exported the technologies (including pesticides and synthetic nitrogen) of the developed world out to the developing world. Thomas Malthus famously predicted that the Earth would not be able to support its growing population, but technologies such as the Green Revolution have allowed the world to produce a surplus of food.[5]

Agricultural output in 2005.

Many governments have subsidized agriculture to ensure an adequate food supply. These agricultural subsidies are often linked to the production of certain commodities such as wheat, corn (maize), rice, soybeans, and milk. These subsidies, especially when done by developed countries have been noted as protectionist, inefficient, and environmentally damaging.[6] In the past century agriculture has been characterized by enhanced productivity, the use of synthetic fertilizers and pesticides, selective breeding, mechanization, water contamination, and farm subsidies. Proponents of organic farming such as Sir Albert Howard argued in the early 1900s that the overuse of pesticides and synthetic fertilizers damages the long-term fertility of the soil. While this feeling lay dormant for decades, as environmental awareness has increased recently there has been a movement towards sustainable agriculture by some farmers, consumers, and policymakers. In recent years there has been a backlash against perceived external environmental effects of mainstream agriculture, particularly regarding water pollution[7], resulting in the organic movement. One of the major forces behind this movement has been the European Union, which first certified organic food in 1991 and began reform of its Common Agricultural Policy (CAP) in 2005 to phase out commodity-linked farm subsidies[8], also known as decoupling. The growth of organic farming has renewed research in alternative technologies such as integrated pest management and selective breeding. Recent mainstream technological developments include genetically modified food.

As of late 2007, several factors have pushed up the price of grain used to feed poultry and dairy cows and other cattle, causing higher prices of wheat (up 58%), soybean (up 32%), and maize (up 11%) over the year.[9][10] Food riots have recently taken place in many countries across the world.[11][12][13] An epidemic of stem rust on wheat caused by race UG99 is currently spreading across Africa and into Asia and is causing major concern.[14][15][16] Approximately 40% of the world's agricultural land is seriously degraded.[17] In Africa, if current trends of soil degradation continue, the continent might be able to feed just 25% of its population by 2025, according to UNU's Ghana-based Institute for Natural Resources in Africa.[18]

Practices

File:FarmersIndia.jpg
Farmers work inside a rice field in Andhra Pradesh, India.

Agricultural practices lie on a spectrum dependent upon the intensity and technology of the methods. At the one end lies the subsistence farmer who farms a small area with limited inputs and produces only enough food to meet the needs of his or her family. At the other end lies intensive agriculture which includes traditional labor intensive farming (e.g. South-East Asia rice paddies), and modern agriculture which includes industrial agriculture, organic farming and sustainable farming. Industrial agriculture involves large fields and/or numbers of animals, high resource inputs (pesticides, fertilizers, etc.), and a high level of mechanization. These operations achieve economies of scale and require large amounts of capital in the form of land and machinery.

The twentieth century saw changes in agricultural practice, particularly in agricultural chemistry and in mechanization. Agricultural chemistry includes the application of chemical fertilizer, chemical insecticides (see pest control), and chemical fungicides, analysis of soil makeup and nutritional needs of farm animals.

Mechanization has increased farm efficiency and productivity in most regions of the world, due especially to the tractor and various "gins" (short for "engine") such as the cotton gin, semi-automatic balers and threshers and, above all, the combine (see agricultural machinery). According to the National Academy of Engineering in the United States, agricultural mechanization is one of the 20 greatest engineering achievements of the 20th century. Early in the century, it took one American farmer to produce food for 2.5 people. By 1999, due to advances in agricultural technology, a single farmer could feed over 130 people.[19]

Other recent changes in agriculture include hydroponics, plant breeding, hybridization, gene manipulation, better management of soil nutrients, and improved weed control. Genetic engineering has yielded crops which have capabilities beyond those of naturally occurring plants, such as higher yields and disease resistance. Modified seeds germinate faster, and thus can be grown on an accelerated schedule. Genetic engineering of plants has proven controversial, particularly in the case of herbicide-resistant plants.

It has been suggested that genetic engineers may some day develop transgenic plants which would allow for irrigation, drainage, conservation, sanitary engineering, and maintaining or increasing yields while requiring fewer fossil fuel derived inputs than conventional crops.[20] Such developments would be particularly important in areas which are normally arid and rely upon constant irrigation, and on large scale farms. These possibilities are questioned by ecologists and economists concerned with unsustainable GMO practices such as terminator seeds,[21][22] and a January 2008 report shows that GMO practices have failed to address sustainability issues.[23] While there has been some research on sustainability using GMO crops, at least one hyped and promonant multi-year attempt by Monsanto has been unsuccessful, though during the same period traditional breeding techniques yielded a more sustainable variety of the same crop.[24] Additionally, a survey by the bio-tech industry of subsistence farmers in Africa to discover what GMO research would most benefit sustainable agriculture only identified non-transgenic issues as areas needing to be addressed.[25]

The processing, packing and marketing of agricultural products are closely related activities also influenced by science. Methods of quick-freezing and dehydration have increased the markets for many farm products (see food preservation and meat packing industry).

Animals, including horses, mules, oxen, camels, llamas, alpacas, and dogs, are often used to help cultivate fields, harvest crops, wrangle other animals, and transport farm products to buyers. Animal husbandry not only refers to the breeding and raising of animals for meat or to harvest animal products (like milk, eggs, or wool) on a continual basis, but also to the breeding and care of species for work and companionship.

Airplanes, helicopters, trucks, tractors, and combines are used in Western (and, increasingly, Eastern) agriculture for seeding, spraying operations for insect and disease control, harvesting, aerial topdressing and transporting perishable products. Radio and television disseminate vital weather reports and other information such as market reports that concern farmers. Computers have become an essential tool for farm management.

Ploughing rice paddies with water buffalo, in Indonesia.

In recent years, some aspects of intensive industrial agriculture have been the subject of increasing debate. The widening sphere of influence held by large seed and chemical companies, meat packers and food processors has been a source of concern both within the farming community and for the general public. Another issue is the type of feed given to some animals that can cause bovine spongiform encephalopathy in cattle. There has also been concern over the effect of intensive agriculture on the environment.

A field of ripening barley.

The patent protection given to companies that develop new types of seed using genetic engineering has allowed seed to be licensed to farmers in much the same way that computer software is licensed to users. This has changed the balance of power in favor of the seed companies, allowing them to dictate terms and conditions previously unheard of. The Indian activist and scientist Vandana Shiva argues that these companies are guilty of biopiracy.

Soil conservation and nutrient management have been important concerns since the 1950s, with the most advanced farmers taking a stewardship role with the land they use. However, increasing contamination of waterways and wetlands by nutrients like nitrogen and phosphorus are concerns that can only be addressed by "enlightenment" of farmers and/or far stricter law enforcement in many countries.

Increasing consumer awareness of agricultural issues has led to the rise of community-supported agriculture, local food movement, "Slow Food", and commercial organic farming.

Etymology

The word agriculture is the English adaptation of Latin agricultūra, from ager, "a field",[26] and cultūra, "cultivation" in the strict sense of "tillage of the soil".[27] Thus, a literal reading of the word yields "tillage of a field / of fields".

History

Sumerian Harvester's sickle, 3000 BCE. Baked clay. Field Museum.

Agriculture was developed at least 10,000 years ago, and it has undergone significant developments since the time of the earliest cultivation. Evidence points to the Fertile Crescent of the Middle East as the site of the earliest planned sowing and harvesting of plants that had previously been gathered in the wild. Independent development of agriculture occurred in northern and southern China, Africa's Sahel, New Guinea and several regions of the Americas. Agricultural practices such as irrigation, crop rotation, fertilizers, and pesticides were developed long ago but have made great strides in the past century. The Haber-Bosch method for synthesizing ammonium nitrate represented a major breakthrough and allowed crop yields to overcome previous constraints. In the past century agriculture has been characterized by enhanced productivity, the substitution of labor for synthetic fertilizers and pesticides, selective breeding, mechanization, water pollution, and farm subsidies. In recent years there has been a backlash against the external environmental effects of conventional agriculture, resulting in the organic movement.

Ancient origins

File:Ancient egyptian farmer.gif
Ancient Egyptian farmer, copied from archaeologically preserved specimen by a modern artist guessing at original colors.
Source: http://www.kingtutone.com

Developed independently by geographically distant populations, systematic agriculture first appeared in Southwest Asia with the bulk of domesticated neolthic crops and livestock now being traced to Turkey via DNA studies. The first grains of domesticated Turkish emmer wheat are found at Abu Hurerya dated to 13,500 BP. The only exceptions to this are barley, domesticated in two sites; in Levant, and East of the Zagros mountains in Iran. The eight so-called founder crops of agriculture appear: first emmer and einkorn wheat, then hulled barley, peas, lentils, bitter vetch, chick peas and flax.Bitter vetch and lentils along with almonds and pistachios appear in Franchthi Cave Greece simultaneously, about 9,000 BC. Neither are native to Greece, and they appear 2,000 years prior to domesticated wheat in the same location. This suggests that the cultivation of legumes and nuts preceded that of grain.

By 7000 BCE, small-scale agriculture reached Egypt. From at least 7000 BCE the Indian subcontinent saw farming of wheat and barley, as attested by archaeological excavation at Mehrgarh in Balochistan. By 6000 BCE, mid-scale farming was entrenched on the banks of the Nile. About this time, agriculture was developed independently in the Far East, with rice, rather than wheat, as the primary crop. Chinese and Indonesian farmers went on to domesticate mung, soy, azuki and taro. To complement these new sources of carbohydrates, highly organized net fishing of rivers, lakes and ocean shores in these areas brought in great volumes of essential protein. Collectively, these new methods of farming and fishing inaugurated a human population boom dwarfing all previous expansions, and is one that continues today.

By 5000 BCE, the Sumerians had developed core agricultural techniques including large scale intensive cultivation of land, mono-cropping, organized irrigation, and use of a specialized labour force, particularly along the waterway now known as the Shatt al-Arab, from its Persian Gulf delta to the confluence of the Tigris and Euphrates. Domestication of wild aurochs and mouflon into cattle and sheep, respectively, ushered in the large-scale use of animals for food/fiber and as beasts of burden. The shepherd joined the farmer as an essential provider for sedentary and semi-nomadic societies.

Maize, manioc, and arrowroot were first domesticated in the Americas as far back as 5200 BCE. [28] The potato, tomato, pepper, squash, several varieties of bean, Canna, tobacco and several other plants were also developed in the New World, as was extensive terracing of steep hillsides in much of Andean South America.

In later years, the Greeks and Romans built on techniques pioneered by the Sumerians but made few fundamentally new advances. Southern Greeks struggled with very poor soils, yet managed to become a dominant society for years. The Romans were noted for an emphasis on the cultivation of crops for trade.

File:Al-jazari pump.png
A valve-operated reciprocating suction piston pump water-raising machine with a crankshaft-connecting rod mechanism invented by al-Jazari.

Middle Ages

During the Middle Ages, Muslim farmers in North Africa and the Near East developed and disseminated agricultural technologies including irrigation systems based on hydraulic and hydrostatic principles, the use of machines such as norias, and the use of water raising machines, dams, and reservoirs. They also wrote location-specific farming manuals, and were instrumental in the wider adoption of crops including sugar cane, rice, citrus fruit, apricots, cotton, artichokes, aubergines, and saffron. Muslims also brought lemons, oranges, cotton, almonds, figs and sub-tropical crops such as bananas to Spain.

The invention of a three field system of crop rotation during the Middle Ages, and the importation of the Chinese-invented moldboard plow, vastly improved agricultural efficiency.

Another important development towards the end of this period was the discovery and subsequent cultivation of fodder crops which allowed over-wintering of livestock.[citation needed]

Modern era

A tractor ploughing an alfalfa field.

After 1492, a global exchange of previously local crops and livestock breeds occurred. Key crops involved in this exchange included the tomato, maize, potato, cocoa and tobacco going from the New World to the Old, and several varieties of wheat, spices, coffee, and sugar cane going from the Old World to the New. The most important animal exportations from the Old World to the New were those of the horse and dog (dogs were already present in the pre-Columbian Americas but not in the numbers and breeds suited to farm work). Although not usually food animals, the horse (including donkeys and ponies) and dog quickly filled essential production roles on western hemisphere farms.

By the early 1800s, agricultural techniques, implements, seed stocks and cultivars had so improved that yield per land unit was many times that seen in the Middle Ages. With the rapid rise of mechanization in the late 19th and 20th centuries, particularly in the form of the tractor, farming tasks could be done with a speed and on a scale previously impossible. These advances have led to efficiencies enabling certain modern farms in the United States, Argentina, Israel, Germany, and a few other nations to output volumes of high quality produce per land unit at what may be the practical limit.

In 2005, the agricultural output of China was the largest in the world, accounting for almost one-sixth world share followed by the EU, India and the USA, according to the International Monetary Fund. Economists measure the total factor productivity of agriculture and by this measure agriculture in the United States is roughly 2.6 times more productive than it was in 1948.[29]

Crops

Crop statistics

Specific crops are cultivated in distinct growing regions throughout the world. In millions of metric tons, based on FAO estimates.

Top agricultural products, by crop types
(million metric tons) 2004 data
Cereals 2,263
Vegetables and melons 866
Roots and Tubers 715
Milk 619
Fruit 503
Meat 259
Oilcrops 133
Fish (2001 estimate) 130
Eggs 63
Pulses 60
Vegetable Fiber 30
Source:
Food and Agriculture Organization (FAO)
[30]
Top agricultural products, by individual crops
(million metric tons) 2004 data
Sugar Cane 1,324
Maize 721
Wheat 627
Rice 605
Potatoes 328
Sugar Beet 249
Soybean 204
Oil Palm Fruit 162
Barley 154
Tomato 120
Source:
Food and Agriculture Organization (FAO)
[30]


Crop alteration

Tractor and chaser bin.
An agricultural scientist records corn (maize) growth.
Netting protecting wine grapes from birds.

Domestication of plants has, over the centuries increased yield, improved disease resistance and drought tolerance, eased harvest and improved the taste and nutritional value of crop plants. Careful selection and breeding have had enormous effects on the characteristics of crop plants. Plant breeders use greenhouses (known as glasshouses or hothouses in some areas) and other techniques to get as many as three generations of plants per year towards the continued effort of improvement. Plant selection and breeding in the 1920s and 1930s improved pasture (grasses and clover) in New Zealand. Extensive X-ray an ultraviolet induced mutagenesis efforts (i.e. primitive genetic engineering) during the 1950s produced the modern commercial varieties of grains such as wheat, corn (maize) and barley.[31][32]

For example, average yields of corn (maize) in the USA have increased from around 2.5 tons per hectare (t/ha) (40 bushels per acre) in 1900 to about 9.4 t/ha (150 bushels per acre) in 2001. Similarly, worldwide average wheat yields have increased from less than 1 t/ha in 1900 to more than 2.5 t/ha in 1990. South American average wheat yields are around 2 t/ha, African under 1 t/ha, Egypt and Arabia up to 3.5 to 4 t/ha with irrigation. In contrast, the average wheat yield in countries such as France is over 8 t/ha. Variation in yields are due mainly to variation in climate, genetics, and the level of intensive farming techniques (use of fertilizers, chemical pest control, growth control to avoid lodging).[33][34][35]

After mechanical tomato-harvesters were developed in the early 1960s, agricultural scientists bred tomatoes that were more resistant to mechanical handling. These varieties have been criticized as being harder and having poor texture[citation needed]. More recently, genetic engineering has begun to be employed in large parts of the world to speed up the selection and breeding process. One widely used modification is a herbicide resistance gene that allows plants to tolerate exposure to glyphosate, a non-systemic (i.e kills all plants) chemical used to control weeds in a crop such as oilseed rape. Normally, expensive systemic herbicides would have to be applied to kill the weeds without harming the crop. Relatively cheap and safe glyphosate may be applied to the modified crops, efficiently killing weeds without harming the resistant crop. Another modification causes the plant to produce a toxin to reduce damage from insects (c.f. Starlink). This, in contrast, requires fewer insecticides to be applied to the crop.

Aquaculture, the farming of fish, shrimp, and algae, is closely associated with agriculture.

Apiculture, the culture of bees, traditionally for honey—increasingly for crop pollination.

See also : cultigen, botany, List of domesticated plants, List of vegetables, List of herbs, List of fruit

Livestock

The farming practices of livestock vary dramatically worldwide and between different types of animals. Livestock are generally kept in an enclosure, are fed by human-provided food and are intentionally bred, but some livestock are not enclosed, or are fed by access to natural foods, or are allowed to breed freely, or all three. Approximately 68% of all agricultural land is used in the production of livestock as permanent pastures.[36]

i like cows they are hot i want to lick there poop

the moon is round

Lunar Farming

[citation needed]

Lunar farming is the practice of observing the moon phases to assist in taking decisions on when to plant various crops. Root crops are believed to be best planted during the waining phase of the moon (when the moon in decreasing in size) while above ground crops are said to be best planted during the waxing moon (when the moon is growing in size). The reasoning behind this is that as the gravitational force of the moon affects waters of oceans and seas on the earth causing the phenomenon of ebb and tide it also affects on a more subtle scale the water content of the soil and plants themselves. Therefore, plant life is believed to be affected by the phases of the moon.

Besides observing the phases of the moon to make farming decisions, the zodiac through which the moon is passing is also observed to make further timing decisions for various farming operations. For instance, when the moon is in Cancer it is the best time to sow seeds and start planing. While Aires is a barren sign and planting should be avoided during that time.

Policy

Agricultural policy focuses on the goals and methods of agricultural production. At the policy level, common goals of agriculture include:

  • Food safety: Ensuring that the food supply is free of contamination.
  • Food security: Ensuring that the food supply meets the population's needs.Cite error: The <ref> tag has too many names (see the help page).[37][38][39][40]) will inflict major damage on the modern industrial agriculture system, and could cause large food shortages.[41]

Oil shortages are one of several factors making organic agriculture and other sustainable farming methods necessary. This conversion is now occurring[citation needed], but the reconditioning of soil to restore nutrients lost during the use of monoculture agriculture techniques made possible by petroleum-based technology will take time. Some farmers using modern organic-farming methods have reported yields as high as those available from conventional farming (but without the use of fossil-fuel-intensive artificial fertilizers or pesticides).[42][43][44][45]

Farmers have also begun raising crops such as corn (maize) for non-food use in an effort to help mitigate peak oil. This has contributed to a 60% rise in wheat prices recently, and has been indicated as a possible precursor to "serious social unrest in developing countries."[46] Such situations would be exacerbated in the event of future rises in food and fuel costs, factors which have already impacted the ability of charitable donors to send food aid to starving populations.[47]

One example of the chain reactions which could possibly be caused by peak oil issues involves the problems caused by farmers raising crops such as corn (maize) for non-food use in an effort to help mitigate peak oil. This has already lowered food production.[48] This food vs fuel issue will be exacerbated as demand for ethanol fuel rises. Rising food and fuel costs has already limited the abilities of some charitable donors to send food aid to starving populations.[49] In the UN, some warn that the recent 60% rise in wheat prices could cause "serious social unrest in developing countries."[48][50] In 2007, higher incentives for farmers to grow non-food biofuel crops[51] combined with other factors (such as over-development of former farm lands, rising transportation costs, climate change, growing consumer demand in China and India, and population growth)[52] to cause food shortages in Asia, the Middle East, Africa, and Mexico, as well as rising food prices around the globe.[53][54] As of December 2007, 37 countries faced food crises, and 20 had imposed some sort of food-price controls. Some of these shortages resulted in food riots and even deadly stampedes.[55][56][57]

Another major petroleum issue in agriculture is the effect of petroleum supplies will have on fertilizer production. By far the biggest fossil fuel input to agriculture is the use of natural gas as a hydrogen source for the Haber-Bosch fertilizer-creation process.[58] Natural gas is used because it is the cheapest currently available source of hydrogen.[59][60] When oil production becomes so scarce that natural gas is used as a partial stopgap replacement, and hydrogen use in transportation increases, natural gas will become much more expensive. If other sources of hydrogen are not available to replace the Haber process, in amounts sufficient to supply transportation and agricultural needs, this major source of fertilizer would either become extremely expensive or unavailable. This would either cause food shortages or dramatic rises in food prices.

Mitigation of effects of petroleum shortages

One effect oil shortages could have on agriculture is a full return to organic agriculture. In light of peak oil concerns, organic methods are much more sustainable than contemporary practices because they use no petroleum-based pesticides, herbicides, or fertilizers. Some farmers using modern organic-farming methods have reported yields as high as those available from conventional farming.[61][62][63][64] Organic farming may however be more labor-intensive and would require a shift of work force from urban to rural areas.[65]

It has been suggested that rural communities might obtain fuel from the biochar and synfuel process, which uses agricultural waste to provide charcoal fertilizer, some fuel and food, instead of the normal food vs fuel debate. As the synfuel would be used on site, the process would be more efficient and may just provide enough fuel for a new organic-agriculture fusion.[66][67]

It has been suggested that some transgenic plants may some day be developed which would allow for maintaining or increasing yields while requiring fewer fossil fuel derived inputs than conventional crops.[68] The possibility of success of these programs is questioned by ecologists and economists concerned with unsustainable GMO practices such as terminator seeds,[69][70] and a January 2008 report shows that GMO practices "fail to deliver environmental, social and economic benefits."[71] While there has been some research on sustainability using GMO crops, at least one hyped and prominent multi-year attempt by Monsanto has been unsuccessful, though during the same period traditional breeding techniques yielded a more sustainable variety of the same crop.[72] Additionally, a survey by the bio-tech industry of subsistence farmers in Africa to discover what GMO research would most benefit sustainable agriculture only identified non-transgenic issues as areas needing to be addressed.[73] Nonetheless, some governments in Africa continue to view investments in new transgenic technologies as an essential component of efforts to improve sustainability.[74]

Agriculture safety and health

Satellite image of circular crop fields characteristic of center pivot irrigation in Haskell County, Kansas in late June 2001. Healthy, growing crops are green. Maize is growing leafy stalks, but Sorghum, which resembles maize, grows more slowly and is much smaller and therefore paler. Wheat is a brilliant gold as harvest occurs in June. Brown fields have been recently harvested and plowed under or lie fallow for the year.

United States

Agriculture ranks among the most hazardous industries.[75] Farmers are at high risk for fatal and nonfatal injuries, work-related lung diseases, noise-induced hearing loss, skin diseases, and certain cancers associated with chemical use and prolonged sun exposure. Farming is one of the few industries in which the families (who often share the work and live on the premises) are also at risk for injuries, illness, and death.

  • In an average year, 516 workers die doing farm work in the U.S. (1992-2005). Of these deaths, 101 are caused by tractor overturns.
  • Every day, about 243 agricultural workers suffer lost-work-time injuries, and about 5% of these result in permanent impairment.[76]

Young workers

Agriculture is the most dangerous industry for young workers, accounting for 42% of all work-related fatalities of young workers in the U.S. between 1992 and 2000. Unlike other industries, half the young victims in agriculture were under age 15. [77]

For young agricultural workers aged 15–17, the risk of fatal injury is four times the risk for young workers in other workplaces [78] Agricultural work exposes young workers to safety hazards such as machinery, confined spaces, work at elevations, and work around livestock.

  • An estimated 1.26 million children and adolescents under 20 years of age resided on farms in 2004, with about 699,000 of these youth performing work on the farms. In addition to the youth who live on farms, an additional 337,000 children and adolescents were hired to work on U.S. farms in 2004.
  • On average, 103 children are killed annually on farms (1990-1996). Approximately 40 percent of these deaths were work-related.
  • In 2004, an estimated 27,600 children and adolescents were injured on farms; 8,100 of these injuries were due to farm work.[76]

Additional information

See also

Main lists: List of basic agriculture topics and List of agriculture topics

Notes

  1. ^ Marketwatch (2007) Plastics are Green in More Ways Than One.
  2. ^ BIO (n.d.) Growing Plants for Pharmaceutical Production vs. for Food and Feed Crops.
  3. ^ International Labour Organization Key Indicators of the Labour Market 2008, p.11-12
  4. ^ "https://www.cia.gov/library/publications/the-world-factbook/geos/xx.html#Econ". {{cite web}}: External link in |title= (help)
  5. ^ New York Times (2005) Sometimes a Bumper Crop is Too Much Of a Good Thing
  6. ^ New York Times (1986) Science Academy Recommends Resumption of Natural Farming
  7. ^ The World Bank (1995) Overcoming Agricultural Water Pollution in the European Union
  8. ^ European Commission (2003) CAP Reform
  9. ^ New York Times (2007 September) At Tyson and Kraft, Grain Costs Limit Profit
  10. ^ Forget oil, the new global crisis is food
  11. ^ Riots and hunger feared as demand for grain sends food costs soaring
  12. ^ Already we have riots, hoarding, panic: the sign of things to come?
  13. ^ Feed the world? We are fighting a losing battle, UN admits
  14. ^ Millions face famine as crop disease rages
  15. ^ "Billions at risk from wheat super-blight". New Scientist Magazine (issue 2598): 6–7. 2007-04-03. Retrieved 2007-04-19. {{cite journal}}: |issue= has extra text (help)CS1 maint: year (link)
  16. ^ Leonard, K.J. Black stem rust biology and threat to wheat growers, USDA ARS
  17. ^ Global food crisis looms as climate change and population growth strip fertile land
  18. ^ Africa may be able to feed only 25% of its population by 2025
  19. ^ "http://www.greatachievements.org/greatachievements/ga_7_2.html". {{cite web}}: External link in |title= (help)
  20. ^ Srinivas; et al. (June, 2008). "Reviewing The Methodologies For Sustainable Living". 7. The Electronic Journal of Environmental, Agricultural and Food Chemistry: 2993–3014. {{cite journal}}: Check date values in: |date= (help); Cite journal requires |journal= (help); Explicit use of et al. in: |author= (help)
  21. ^ Conway, G. (2000). "Genetically modified crops: risks and promise". 4(1): 2. Conservation Ecology. {{cite journal}}: Cite journal requires |journal= (help)
  22. ^ . R. Pillarisetti and Kylie Radel (June 2004). "Economic and Environmental Issues in International Trade and Production of Genetically Modified Foods and Crops and the WTO". Volume 19, Number 2. Journal of Economic Integration: 332–352. {{cite journal}}: |volume= has extra text (help); Cite journal requires |journal= (help)
  23. ^ Juan Lopez Villar & Bill Freese (January 2008). "Who Benefits from GM Crops?" (pdf). Friends of the Earth International.
  24. ^ "Monsanto's showcase project in Africa fails". Vol 181 No. 2433. New Scientist. 7 February 2004. doi:10.1080/03056240601000945<br />. Retrieved 2008-04-18. {{cite journal}}: |volume= has extra text (help); Check |doi= value (help); Cite journal requires |journal= (help)
  25. ^ Devlin Kuyek (August 2002). "Genetically Modifi ed Crops in Africa: Implications for Small Farmers" (pdf). Genetic Resources Action International (GRAIN).
  26. ^ Latin Word Lookup
  27. ^ Latin Word Lookup
  28. ^ Farming older than thought | University of Calgary
  29. ^ USDA ERS. Agricultural Productivity in the United States
  30. ^ a b "FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS (FAOSTAT)". Retrieved 2007-10-11.
  31. ^ Stadler, L. J. (1936-10-15). "Genetic Effects of Ultra-Violet Radiation in Maize. I. Unfiltered Radiation" (PDF). Proceedings of the National Academy of Sciences of the United States of America. 22 (10). US Department of Agriculture and Missouri Agricultural Experiment Station: 572–578. Retrieved 2007-10-11. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  32. ^ Berg, Paul (2003-08-15). George Beadle: An Uncommon Farmer. The Emergence of Genetics in the 20th century. Cold Springs Harbor Laboratory Press. ISBN 0-87969-688-5. {{cite book}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  33. ^ Ruttan, Vernon W. (Winter 1999). "Biotechnology and Agriculture: A Skeptical Perspective". AgBioForum. 2 (1): 54–60. Retrieved 2007-10-11.
  34. ^ Cassman, K. (1998-12-05). "Ecological intensification of cereal production systems: The Challenge of increasing crop yield potential and precision agriculture". Proceedings of a National Academy of Sciences Colloquium, Irvine, California. University of Nebraska. Retrieved 2007-10-11. {{cite journal}}: Cite has empty unknown parameter: |coauthors= (help)
  35. ^ Conversion note: 1 bushel of wheat = 60 pounds (lb) ≈ 27.215 kg. 1 bushel of maize = 56 pounds ≈ 25.401 kg
  36. ^ FAO Database, 2003
  37. ^ Ryan McGreal (2007-10-22). "Yes, We're in Peak Oil Today". Raise the Hammer.
  38. ^ Dr. Werner Zittel, Jorg Schindler (2007-10). "Crude Oil: The Supply Outlook" (PDF). Energy Watch Group. {{cite web}}: Check date values in: |date= (help)
  39. ^ Dave Cohen (2007-10-31). "The Perfect Storm". ASPO-USA.
  40. ^ Rembrandt H.E.M. Koppelaar (2006-09). "World Production and Peaking Outlook" (PDF). Peak Oil Netherlands. {{cite web}}: Check date values in: |date= (help)
  41. ^ (a list of over 20 published articles and books supporting this thesis can be found here in the section: "Food, Land, Water, and Population")
  42. ^ Realities of organic farming
  43. ^ http://extension.agron.iastate.edu/organicag/researchreports/nk01ltar.pdf
  44. ^ Organic Farming can Feed The World!
  45. ^ Organic Farms Use Less Energy And Water
  46. ^ Cite error: The named reference ijpwyz was invoked but never defined (see the help page).
  47. ^ Cite error: The named reference nnxnwc was invoked but never defined (see the help page).
  48. ^ a b Record rise in wheat price prompts UN official to warn that surge in food prices may trigger social unrest in developing countries
  49. ^ Rising food prices curb aid to global poor
  50. ^ Keith Bradsher (January 19, 2008). "A New, Global Oil Quandary: Costly Fuel Means Costly Calories". New York Times. {{cite web}}: Check date values in: |date= (help)
  51. ^ 2008: The year of global food crisis
  52. ^ The global grain bubble
  53. ^ The cost of food: Facts and figures
  54. ^ The World's Growing Food-Price Crisis
  55. ^ Already we have riots, hoarding, panic: the sign of things to come?
  56. ^ Riots and hunger feared as demand for grain sends food costs soaring
  57. ^ Feed the world? We are fighting a losing battle, UN admits
  58. ^ Raw Material Reserves - International Fertilizer Industry Association [1]
  59. ^ Integrated Crop Management-Iowa State University January 29, 2001 [2]
  60. ^ The Hydrogen Economy-Physics Today Magazine, December 2004 [3]
  61. ^ Realities of organic farming
  62. ^ http://extension.agron.iastate.edu/organicag/researchreports/nk01ltar.pdf
  63. ^ Organic Farming can Feed The World!
  64. ^ Organic Farms Use Less Energy And Water
  65. ^ Strochlic, R.; Sierra, L. (2007). Conventional, Mixed, and “Deregistered” Organic Farmers: Entry Barriers and Reasons for Exiting Organic Production in California. California Institute for Rural Studies.
  66. ^ "Carbon cycle management with increased photo-synthesis and long-term sinks" (2007) Royal Society of New Zealand
  67. ^ Greene, Nathanael How biofuels can help end America's energy dependenc e December 2004.
  68. ^ Srinivas; et al. (June, 2008). "Reviewing The Methodologies For Sustainable Living". 7. The Electronic Journal of Environmental, Agricultural and Food Chemistry: 2993–3014. {{cite journal}}: Check date values in: |date= (help); Cite journal requires |journal= (help); Explicit use of et al. in: |author= (help)
  69. ^ Conway, G. (2000). "Genetically modified crops: risks and promise". 4(1): 2. Conservation Ecology. {{cite journal}}: Cite journal requires |journal= (help)
  70. ^ . R. Pillarisetti and Kylie Radel (June 2004). "Economic and Environmental Issues in International Trade and Production of Genetically Modified Foods and Crops and the WTO". Volume 19, Number 2. Journal of Economic Integration: 332–352. {{cite journal}}: |volume= has extra text (help); Cite journal requires |journal= (help)
  71. ^ Juan Lopez Villar & Bill Freese (January 2008). "Who Benefits from GM Crops?" (pdf). Friends of the Earth International.
  72. ^ "Monsanto's showcase project in Africa fails". Vol 181 No. 2433. New Scientist. 7 February 2004. Retrieved 2008-04-18. {{cite journal}}: |volume= has extra text (help); Check date values in: |date= (help); Cite journal requires |journal= (help)
  73. ^ Devlin Kuyek (August 2002). "Genetically Modified Crops in Africa: Implications for Small Farmers" (pdf). Genetic Resources Action International (GRAIN).
  74. ^ Jeremy Cooke (30 May 2008). "Genetically Modified Crops in Africa: Implications for Small Farmers". BBC. Retrieved 2008-06-06. {{cite web}}: Check date values in: |date= (help)
  75. ^ "NIOSH- Agriculture". United States National Institute for Occupational Safety and Health. Retrieved 2007-10-10.
  76. ^ a b "NIOSH- Agriculture Injury". United States National Institute for Occupational Safety and Health. Retrieved 2007-10-10.
  77. ^ NIOSH [2003]. Unpublished analyses of the 1992–2000 Census of Fatal Occupational Injuries Special Research Files provided to NIOSH by the Bureau of Labor Statistics (includes more detailed data than the research file, but excludes data from New York City). Morgantown, WV: U.S. Department of Health and Human Services, Public Health Service, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health, Division of Safety Research, Surveillance and Field Investigations Branch, Special Studies Section. Unpublished database.
  78. ^ BLS [2000]. Report on the youth labor force. Washington, DC: U.S. Department of Labor, Bureau of Labor Statistics, pp. 58–67.

References

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Coffee Plantation in São João do Manhuaçu City - Minas Gerais State - Brazil.

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