Agriculture is the production of food, feed, fiber and other goods by the systematic raising of domesticated plants and animals. In modern usage, the word agriculture covers all activities essential to food/feed/fiber production, including all techniques for raising and "processing" livestock. Agriculture is also short for the study of the practice of agriculture — more formally known as agricultural science.
The history of agriculture is a central element of 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 agricultural and agro-industrial societies—when farmers became capable of producing food beyond the needs of their own families, others in the tribe/nation/empire were freed to devote themselves to projects other than food acquisition.
As of 2006, an estimated 36 percent of the world's workers are employed in agriculture[1] (down from 42% in 1996), making it by far the most common occupation. However, the relative significance of farming has dropped steadily since the beginning of industrialization, and in 2006 – for the first time in history – the services sector overtook agriculture as the economic sector employing the most people worldwide. Also, agricultural production accounts for less than five percent of the gross world product (an aggregate of all gross domestic products).[2]
At one end of the spectrum is the subsistence farmer, who farms a small area with limited resource inputs, and produces only enough food to meet the needs of his or her family. At the other end is commercial intensive agriculture, including industrial agriculture. Such farming involves large fields and/or numbers of animals, large resource inputs (pesticides, fertilizers, etc.), and a high level of mechanization. These operations generally attempt to maximize financial income from grain, produce, or livestock.
The twentieth century saw massive 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.
Up to and including the 1970s, surface runoff of fertilizer and pesticides was a growing, uncontrolled problem. Starting roughly in 1980, many Western nations, prodded by dozens of environmental action groups, began to implement effective controls on farming-related pollution, and this green revolution spread many of the benefits of agricultural chemistry to farms throughout the world, without the extreme pollution that originally accompanied them. Between 1950 and 1984, as the green revolution transformed agriculture around the globe, world grain production increased by 250%.[3] Mechanization has also enormously increased farm efficiency and productivity in most regions of the world, due especially to the tractor and various "gins" (short for "engine") like the cotton gin, semi-automatic balers and threshers and, above all, the combine (see agricultural machinery).
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.
Engineers may develop plants for irrigation, drainage, conservation and sanitary engineering, particularly important in normally arid areas which rely upon constant irrigation, and on large scale farms.
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.
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.[4]
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.
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.
Soilconservation 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.
The word agriculture is the English adaptation of Latin agricultūra, from ager, "a field", and cultūra, "cultivation" in the strict sense of "tillage of the soil". Thus, a literal reading of the word yields "tillage of a field / of fields".
According to the United Nations, the livestock sector (primarily cows, chickens, and pigs) emerges as one of the top two or three most significant contributors to our most serious environmental problems, at every scale from local to global. Livestock production occupies 70% of all land used for agriculture, or 30% of the land surface of the planet.[12]It is one of the largest sources of greenhouse gases—responsible for 18% of the world’s greenhouse gas emissions as measured in CO2 equivalents. By comparison, all transportation emits 13.5% of the CO2. It produces 65% of human-related nitrous oxide (which has 296 times the global warming potential of CO2) and 37% of all human-induced methane (which is 23 times as warming as CO2). It also generates 64% of the ammonia, which contributes to acid rain and acidification of ecosystems.[13]
Genetic erosion in crop and livestock biodiversity
Genetic erosion in crop and livestock biodiversity is the loss of genetic diversity, including the loss of individual genes, and the loss of particular combinants of genes (or gene complexes) such as those manifested in locally adapted landraces of domesticated animals or plants adapted to the natural environment in which they originated. The term genetic erosion is sometimes used in a narrow sense, such as for the loss of alleles or genes, as well as more broadly, referring to the loss of varieties or even species. The major driving forces behind genetic erosion in crops are: variety replacement, land clearing, overexploitation of species, population pressure, environmental degradation, overgrazing, policy and changing agricultural systems. [citation needed]
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 GMOs) 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. [attribution needed]
In agriculture and animal husbandry, the green revolution popularized the use of conventional 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 the genetic material that adapted that breed specifically to the local conditions. When viewed across the world as a whole, the consequent loss in genetic diversity and biodiversity could be placing the food supply in jeopardy, as a highly specialized breed may not contain sufficient genetic material to adapt to new diseases or environments even with an intensive breeding program.[14]
A Genetically Modified Organism (GMO) is an organism whose genetic material has been altered using the genetic engineering techniques generally known as recombinant DNA technology. Genetic Engineering today has become another serious and alarming cause of genetic pollution because artificially created and genetically engineered plants and animals in laboratories, which could never have evolved in nature even with conventional hybridization, can live and breed on their own and what is even more alarming interbreed with naturally evolved wild varieties. Genetically Modified (GM) crops today have become a common source for genetic pollution, not only of wild varieties but also of other domesticated varieties derived from relatively natural hybridization.[15][16][17][18][19]
Policy
Food safety: Ensuring that the food supply is free of contamination.
Food quality: Ensuring that the food supply is of a consistent and known quality.
Poverty Reduction
Conservation
Environmental impact
Economic stability
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. Corn is growing leafy stalks, but Sorghum, which resembles corn, 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. [22] 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.[23]
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. [24]
For young agricultural workers aged 15–17, the risk of fatal injury is four times the risk for young workers in other workplaces [25] 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.[23]
^ Berg, Paul; Maxine Singer (2003-08-15). George Beadle: An Uncommon Farmer. The Emergence of Genetics in the 20th Century. Cold Springs Harbor Laboratory Press. .
^“Genetic Pollution: The Great Genetic Scandal”; Devinder Sharma can be contacted at: 7 Triveni Apartments, A-6 Paschim Vihar, New Delhi-110 063, India. Email: dsharma@ndf.vsnl.net.in. CENTRE FOR ALTERNATIVE AGRICULTURAL MEDIA (CAAM)., [1]
^Dangerous Liaisons? When Cultivated Plants Mate with Their Wild Relatives by Norman C. Ellstrand; The Johns Hopkins University Press, 2003; 268 pp. hardcover , $ 65; . Book Reviewed in: Hybrids abounding; Nature Biotechnology 22, 29 - 30 (2004) doi:10.1038/nbt0104-29; Reviewed by: Steven H Strauss & Stephen P DiFazio.
^“Genetic pollution: Living organisms can also be defined as pollutants, when a non-indigenous species (plant or animal) enters a habitat and modifies the existing equilibrium among the organisms of the affected ecosystem (sea, lake, river). Non-indigenous, including transgenic species (GMOs), may bring about a particular version of pollution in the vegetal kingdom: so-called genetic pollution. This term refers to the uncontrolled diffusion of genes (or transgenes) into genomes of plants of the same type or even unrelated species where such genes are not present in nature. For example, a grass modified to resist herbicides could pollinate conventional grass many miles away, creating weeds immune to the most widely used weed-killer, with obvious consequences for crops. Genetic pollution is at the basis of the debate on the use of GMOs in agriculture.” The many facets of pollution; Bologna University web site for Science Communication. The Webweavers: Last modified Tue, 20 Jul 2005
^ 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.
^ BLS [2000]. Report on the youth labor force. Washington, DC: U.S. Department of Labor, Bureau of Labor Statistics, pp. 58–67.
Artz, F. B, (1980), ‘The Mind of the Middle Ages’; Third edition revised; The University of Chicago Press,
Bolens, L. (1997), `Agriculture’ in Encyclopedia of the history of Science, technology, and Medicine in Non Western Cultures, Editor: Helaine Selin; Kluwer Academic Publishers. Dordrecht/Boston/London, pp 20-2
Collinson, M. (editor): A History of Farming Systems Research. CABI Publishing, 2000.
Crosby, Alfred W.: The Columbian Exchange : Biological and Cultural Consequences of 1492. Praeger Publishers, 2003 (30th Anniversary Edition).
Davis, Donald R., and Hugh D. Riordan (2004) Changes in USDA Food Composition Data for 43 Garden Crops, 1950 to 1999. Journal of the American College of Nutrition, Vol. 23, No. 6, 669-682.
Friedland, William H. and Amy Barton (1975) Destalking the Wily Tomato: A Case Study of Social Consequences in California Agricultural Research. Univ. California at Sta. Cruz, Research Monograph 15.
Watson, A.M (1974), ‘The Arab agricultural revolution and its diffusion’, in The Journal of Economic History, 34,
Watson, A.M (1983), ‘ Agricultural Innovation in the Early Islamic World’, Cambridge University Press
Wells, Spencer: The Journey of Man : A Genetic Odyssey. Princeton University Press, 2003.
Wickens, G.M.(1976), ‘What the West borrowed from the Middle east’, in Introduction to Islamic Civilization, edited by R.M. Savory, Cambridge University Press, Cambridge
Coffee Plantation in São João do Manhuaçu City - Minas Gerais State - Brazil.
External links
UKAgriculture.com - Advance the education of the public in all aspects of agriculture, the countryside and the rural economy
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