History of agriculture

"Agricultural history" redirects here. For the journal, see Agricultural History (journal).
Ploughing with a yoke of horned cattle in Ancient Egypt. Painting from the burial chamber of Sennedjem, c. 1200 BC

The history of agriculture records the domestication of plants and animals and the development and dissemination of techniques for raising them productively. Agriculture began independently in different parts of the globe, and included a diverse range of taxa. At least 11 separate regions of the Old and New World were involved as independent centers of origin.

Wild grains were collected and eaten from at least 20,000 BC. From around 9500 BC, the eight Neolithic founder crops, emmer and einkorn wheat, hulled barley, peas, lentils, bitter vetch, chick peas and flax were cultivated in the Levant. Rice was domesticated in China between 11,500 and 6,200 BC, followed by mung, soy and azuki beans. Pigs were domesticated in Mesopotamia around 13,000 BC, followed by sheep between 11,000 and 9,000 BC. Cattle were domesticated from the wild aurochs in the areas of modern Turkey and Pakistan around 8,500 BC. Sugarcane and some root vegetables were domesticated in New Guinea around 7,000 BC. Sorghum was domesticated in the Sahel region of Africa by 5000 BC. In the Andes of South America, the potato was domesticated between 8,000 and 5,000 BC, along with beans, coca, llamas, alpacas, and guinea pigs. Cotton was domesticated in Peru by 3,600 BC. In Mesoamerica, wild teosinte was domesticated to maize by 4,000 BC. Camels were domesticated late, perhaps around 3000 BC.

In the Middle Ages, both in the Islamic world and in Europe, agriculture was transformed with improved techniques and the diffusion of crop plants, including the introduction of sugar, rice, cotton and fruit trees such as the orange to Europe by way of Al-Andalus. After 1492, the Columbian exchange brought New World crops such as maize, potatoes, sweet potatoes and manioc to Europe, and Old World crops such as wheat, barley, rice and turnips, and livestock including horses, cattle, sheep and goats to the Americas. Irrigation, crop rotation, and fertilizers were introduced soon after the Neolithic Revolution and developed much further in the past 200 years, starting with the British Agricultural Revolution.

Since 1900, agriculture in the developed nations, and to a lesser extent in the developing world, has seen large rises in productivity as human labour has been replaced by mechanization, and assisted by synthetic fertilizers, pesticides, and selective breeding. The Haber-Bosch process allowed the synthesis of ammonium nitrate fertilizer on an industrial scale, greatly increasing crop yields. Modern agriculture has raised social, political, and environmental issues including water pollution, biofuels, genetically modified organisms, tariffs and farm subsidies.


Main article: Neolithic Revolution

Origin hypotheses

A traditional hunter-gatherer society in Wyoming, 1870

Scholars have developed a number of hypotheses to explain the historical origins of agriculture. Studies of the transition from hunter-gatherer to agricultural societies indicate an antecedent period of intensification and increasing sedentism; examples are the Natufian culture in southwest Asia, and the Early Chinese Neolithic in China. Current models indicate that wild stands that had been harvested previously started to be planted, but were not domesticated.[1][2]

Localised climate change is the favoured explanation for the origins of agriculture in the Levant.[3] When major climate change took place after the last ice age (c. 11,000 BC), much of the earth became subject to long dry seasons.[4] These conditions favoured annual plants which die off in the long dry season, leaving a dormant seed or tuber. An abundance of readily storable wild grains and pulses enabled hunter-gatherers in some areas to form the first settled villages at this time.[5]

Early development

Further information: List of food origins
Sumerian harvester's sickle, 3000 BC, made from baked clay

Early people began altering communities of flora and fauna for their own benefit through other means such as fire-stick farming and forest gardening very early.[6][7][8][9] Exact dates are hard to determine, as people collected and ate seeds before domesticating them, and plant characteristics may have changed during this period without human selection. An example is the semi-tough rachis and larger seeds of cereals from just after the Younger Dryas (about 9500 BC) in the early Holocene in the Levant region of the Fertile Crescent. Monophyletic characteristics were attained without any human intervention, implying that apparent domestication of the cereal rachis could have occurred quite naturally.[10]

An Indian farmer with a rock-weighted scratch plough pulled by two oxen. Similar ploughs were used throughout antiquity.

Agriculture began independently in different parts of the globe, and included a diverse range of taxa. At least 11 separate regions of the Old and New World were involved as independent centers of origin.[11] Some of the earliest known domestications were of animals. Pigs were domesticated in Mesopotamia around 13,000 BC.[12] Sheep were domesticated in Mesopotamia between 11,000 and 9,000 BC.[13] Cattle were domesticated from the wild aurochs in the areas of modern Turkey and Pakistan around 8,500 BC.[14] Camels were domesticated late, perhaps around 3000 BC.[15]

Centres of origin identified by Nikolai Vavilov in the 1930s. Papua New Guinea (not shaded) was identified more recently.[16]

It was not until after 9500 BC that 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. These eight crops occur more or less simultaneously on Pre-Pottery Neolithic B (PPNB) sites in the Levant, although wheat was the first to be grown and harvested on a significant scale. At around the same time (9400 BC), parthenocarpic fig trees were domesticated.[17][18]

By 7000 BC, sowing and harvesting reached the fertile soil of Mesopotamia, where Sumerians systematized it and scaled it up. By 8000 BC, farming was entrenched on the banks of the River Nile. About this time, agriculture was developed independently in the Far East, probably in China, with rice rather than wheat as the primary crop. Maize was domesticated from the wild grass teosinte in West Mexico by 6700 BC.[19] The potato (8,000 BC), tomato,[20] pepper (4,000 BC), squash (8,000 BC) and several varieties of bean (8,000 BC onwards) were domesticated in the New World.[21] Agriculture was independently developed on the island of New Guinea.[22] In Greece from c.11,000 BC lentils, vetch, pistachios, and almonds were cultivated, while wild oats and wild barley appear in quantity from c.7000 BC alongside einkorn wheat, barley, sheep, goats and pigs,[23][24] while emmer was used on Cyprus between 9100 and 8600 BC.[25][26] Archaeological evidence from various sites on the Iberian peninsula suggest the domestication of plants and animals between 6000 and 4500 BC.[26] Céide Fields in Ireland, consisting of extensive tracts of land enclosed by stone walls, date to 3500 BC and are the oldest known field systems in the world.[27][28] The horse was domesticated in the Pontic steppe around 4000 BC.[29] In Siberia, Cannabis was in use in China in Neolithic times and may have been domesticated there; it was in use both as a fibre for ropemaking and as a medicine in Ancient Egypt by about 2350 BC.[30]

Clay and wood model of a bull cart carrying farm produce in large pots, Mohenjo-daro. The site was abandoned in the 19th century BC.

In China, rice and millet were domesticated by 8000 BC, followed by mung, soy and azuki beans. In the Sahel region of Africa, local rice and sorghum were domesticated by 5000 BC. Kola nut and coffee were domesticated in Africa.[31] In New Guinea, ancient Papuan peoples began practicing agriculture around 7000 BC, domesticating sugarcane and taro.[32] In the Indus Valley from the eighth millennium BC onwards at Mehrgarh, 2-row and 6-row barley were cultivated, along with einkorn, emmer, and durum wheats, and dates. In the earliest levels of Merhgarh, wild game such as gazelle, swamp deer, blackbuck, chital, wild ass, wild goat, wild sheep, boar, and nilgai were all hunted for food. These are successively replaced by domesticated sheep, goats, and humped zebu cattle by the fifth millennium BC, indicating the gradual transition from hunting and gathering to agriculture.[33] Maize and squash were domesticated in Central America; potato in South America, and sunflower in the Eastern Woodlands of North America.[34]



Domesticated animals on a Sumerian cylinder seal. 2500 BC

Sumerian farmers grew the cereals barley and wheat, starting to live in villages from about 8,000 BC. Given the low rainfall of the region, agriculture relied on the Tigris and Euphrates rivers. Irrigation canals leading from the rivers permitted the growth of cereals in large enough quantities to support cities. The first ploughs appear in pictographs from Uruk around 3,000 BC; seed-ploughs that funneled seed into the ploughed furrow appear on seals around 2300 BC. Vegetable crops included chickpeas, lentils, peas, beans, onions, garlic, lettuce, leeks and mustard. They grew fruits including dates, grapes, apples, melons, and figs. Alongside their farming, Sumerians also caught fish and hunted fowl and gazelle. The meat of sheep, goats, cows and poultry was eaten, mainly by the elite. Fish was preserved by drying, salting and smoking.[35][36]

Ancient Egypt

Agricultural scenes of threshing, a grain store, harvesting with sickles, digging, tree-cutting and ploughing from Ancient Egypt. Tomb of Nakht, 15th century BC

The civilization of Ancient Egypt was indebted to the Nile River and its dependable seasonal flooding. The river's predictability and the fertile soil allowed the Egyptians to build an empire on the basis of great agricultural wealth. Egyptians were among the first peoples to practice agriculture on a large scale , made possible with the development of basin irrigation.[37] Their staple food crops were grains such as wheat and barley, alongside industrial crops such as flax and papyrus.[38]

Indus valley

Main article: Agriculture in India

Cotton was cultivated by the 5th-4th millennium BC.[39]

Wheat, barley, and jujube were domesticated in the Indian subcontinent by 9000 BC; Domestication of sheep and goat soon followed.[40] Barley and wheat cultivation—along with the domestication of cattle, primarily sheep and goat—continued in Mehrgarh culture by 8000–6000 BC.[41][42] This period also saw the first domestication of the elephant.[40] Agro pastoralism in India included threshing, planting crops in rows—either of two or of six—and storing grain in granaries.[42][43] By the 5th millennium BC, agricultural communities became widespread in Kashmir.[42] Irrigation was developed in the Indus Valley Civilization by around 4500 BC.[44] The size and prosperity of the Indus civilization grew as a result of this innovation, which eventually led to more planned settlements making use of drainage and sewers.[44] Archeological evidence of an animal-drawn plough dates back to 2500 BC in the Indus Valley Civilization.[45]

Ancient China

Han Dynasty tomb mural depicting ploughing by Shennong, the legendary "Divine Husbandsman"

Records from the Warring States, Qin Dynasty, and Han Dynasty provide a picture of early Chinese agriculture from the 5th century BC to 2nd century AD which included a nationwide granary system and widespread use of sericulture. An important early Chinese book on agriculture is the Chimin Yaoshu of AD 535, written by Jia Sixia.[46] Jia's writing style was straightforward and lucid relative to the elaborate and allusive writing typical of the time. Jia's book was also very long, with over one hundred thousand written Chinese characters, and it quoted many other Chinese books that were written previously, but no longer survive.[47] The contents of Jia's 6th century book include sections on land preparation, seeding, cultivation, orchard management, forestry, and animal husbandry. The book also includes peripherally related content covering trade and culinary uses for crops.[48] The work and the style in which it was written proved influential on later Chinese agronomists, such as Wang Zhen and his groundbreaking Nong Shu of AD 1313.[47]

For agricultural purposes, the Chinese had innovated the hydraulic-powered trip hammer by the 1st century BC.[49] Although it found other purposes, its main function to pound, decorticate, and polish grain that otherwise would have been done manually. The Chinese also began using the square-pallet chain pump by the 1st century AD, powered by a waterwheel or oxen pulling an on a system of mechanical wheels.[50] Although the chain pump found use in public works of providing water for urban and palatial pipe systems,[51] it was used largely to lift water from a lower to higher elevation in filling irrigation canals and channels for farmland.[52] By the end of the Han dynasty in the late 2nd century, heavy ploughs had been developed with iron ploughshares and mouldboards.[53][54] These would slowly spread west, revolutionizing farming in Northern Europe by the 10th century. (Glick, however, argues for a development of the Chinese plough as late as the 9th century, implying its spread east from similar designs known in Italy by the 7th century.)[55]

Asian rice was domesticated 8,200–13,500 years ago in China, with a single genetic origin from the wild rice Oryza rufipogon,[56] in the Pearl River valley region of China. Rice cultivation then spread to South and Southeast Asia.[57]

Roman Empire

Roman harvesting machine, Trier

In classical antiquity, Roman agriculture built from techniques pioneered by the Sumerians, transmitted to them by subsequent cultures, with a specific emphasis on the cultivation of crops for trade and export. Romans laid the groundwork for the manorial economic system, involving serfdom, which flourished in the Middle Ages. The farm sizes in Rome can be divided into three categories. Small farms were from 18-88 iugera (one iugerum is equal to about 0.65 acre). Medium-sized farms were from 80-500 iugera (singular iugerum). Large estates (called latifundia) were over 500 iugera.[58]

The Romans had four systems of farm management: direct work by owner and his family; slaves doing work under supervision of slave managers; tenant farming or sharecropping in which the owner and a tenant divide up a farm’s produce; and situations in which a farm was leased to a tenant.[58] There was a great deal of commerce between the provinces of the empire, all the regions of the empire became interdependent with one another, some provinces specialized in the production of grain, others in wine and others in olive oil, depending on the soil type.


In Mesoamerica, wild teosinte was transformed through human selection into the ancestor of modern maize, more than 6,000 years ago. It gradually spread across North America and was the major crop of Native Americans at the time of European exploration.[59] Other Mesoamerican crops include hundreds of varieties of locally domesticated squash and beans, while cocoa, also domesticated in the region, was a major crop.[32] The turkey, one of the most important meat birds, was probably domesticated in Mexico or the U.S. Southwest.[60]

In Mesoamerica, the Aztecs were active farmers and had an agriculturally focused economy. The land around Lake Texcoco was fertile, but not large enough to produce the amount of food needed for the population of their expanding empire. The Aztecs developed irrigation systems, formed terraced hillsides, fertilized their soil, and developed chinampas or artificial islands, also known as "floating gardens". The Mayas between 400 BC to 900 AD used extensive canal and raised field systems to farm swampland on the Yucatán Peninsula.[61][62]

South America

Inca farmers using a chaki taklla, a human-powered foot plough

In the Andes region of South America, with civilizations including the Inca, the major crop was the potato, domesticated approximately 7,000–10,000 years ago.[63][64][65] Coca, still a major crop to this day, was domesticated in the Andes, as were the peanut, tomato, tobacco, and pineapple.[32] Cotton was domesticated in Peru by 3,600 BC.[66] Animals were also domesticated, including llamas, alpacas, and guinea pigs.[67]

North America

The indigenous people of the Eastern U.S. appear to have domesticated numerous crops. Sunflowers, tobacco,[68] varieties of squash and Chenopodium, as well as crops no longer grown, including marsh elder and little barley, were domesticated.[69][70] Wild foods including wild rice and maple sugar were harvested.[71] The most common varieties of strawberry were domesticated from Eastern North America.[72] Two major crops, pecans and Concord grapes, were utilized extensively in prehistoric times but do not appear to have been domesticated until the 19th century.[73][74]

The natives in what is now California and the Pacific Northwest practiced various forms of forest gardening and fire-stick farming in the forests, grasslands, mixed woodlands, and wetlands, ensuring that desired food and medicine plants continued to be available. The natives controlled fire on a regional scale to create a low-intensity fire ecology which prevented larger, catastrophic fires and sustained a low-density agriculture in loose rotation; a sort of "wild" permaculture.[75][76][77][78]


From the time British colonization of Australia began in 1788, Indigenous Australians were characterised as being nomadic hunter-gatherers who did not engage in agriculture or other forms of food production, despite some evidence to the contrary. Rhys Jones, however, proposed in 1969 that Indigenous Australians engaged in systematic burning as a way of enhancing natural productivity, what has been termed fire-stick farming.[79] In the 1970s and 1980s archaeological research in south west Victoria established that the Gunditjmara and other groups had developed sophisticated eel farming and fish trapping systems over a period of nearly 5,000 years.[80] Professor Harry Lourandos suggested in the 1980s that there was evidence of 'intensification' in progress across Australia,[81] a process that appeared to have continued through the preceding 5,000 years. These concepts have led Bill Gammage to argue that in effect the whole continent was a managed landscape.[7]

In two regions of Australia, the central west coast and eastern central Australia, forms of early agriculture may have been practiced. People living in permanent settlements of over 200 residents sowed or planted on a large scale and stored the harvested food. The Nhanda and Amangu of the central west coast grew yams (Dioscorea hastifolia), while various groups in eastern central Australia (the Corners Region) planted and harvested bush onions (yaua - Cyperus bulbosus), native millet (cooly, tindil - Panicum decompositum) and a sporocarp, ngardu (Marsillea drumondii).[7]:281–304[82]

Middle Ages and Early Modern

From 100 BC to 1600 AD, world population continued to grow along with land use, as evidenced by the rapid increase in methane emissions from cattle and the cultivation of rice.[83]

Arab world

Noria wheels to lift water for irrigation and household use were among the technologies introduced to Europe via Al-Andalus in the medieval Islamic world.

From the 8th century, the medieval Islamic world underwent a transformation in agricultural practice, described by the historian Andrew Watson as the Arab Agricultural Revolution.[84] This transformation was driven by a number of factors including the diffusion of many crops and plants along Muslim trade routes, the spread of more advanced farming techniques, and an agricultural-economic system which promoted increased yields and efficiency. The shift in agricultural practice changed the economy, population distribution, vegetation cover, agricultural production, population levels, urban growth, the distribution of the labour force, cooking, diet, and clothing across the Islamic world. Muslim traders covered much of the Old World, and trade enabled the diffusion of many crops, plants and farming techniques across the region, as well as the adaptation of crops, plants and techniques from beyond the Islamic world.[84] This diffusion introduced major crops to Europe by way of Al-Andalus, along with the techniques for their cultivation and cuisine. Sugar cane, rice, and cotton were among the major crops transferred, along with citrus and other fruit trees, nut trees, vegetables such as aubergine, spinach and chard, and the use of spices such as cumin, coriander, nutmeg and cinnamon. Intensive irrigation, crop rotation, and agricultural manuals were widely adopted. Irrigation, partly based on Roman technology, made use of noria water wheels, water mills, dams and reservoirs.[84][85][86]


The Middle Ages saw further improvements in agriculture. Monasteries spread throughout Europe and became important centers for the collection of knowledge related to agriculture and forestry. The manorial system allowed large landowners to control their land and its laborers, in the form of peasants or serfs.[87] During the medieval period, the Arab world was critical in the exchange of crops and technology between the European, Asia and African continents. Besides transporting numerous crops, they introduced the concept of summer irrigation to Europe and developed the beginnings of the plantation system of sugarcane growing through the use of slaves for intensive cultivation.[88]

Agricultural calendar from a manuscript of Pietro de Crescenzi

By AD 900, developments in iron smelting allowed for increased production in Europe, leading to developments in the production of agricultural implements such as ploughs, hand tools and horse shoes. The carruca plough improved on the earlier scratch plough, with the adoption of the Chinese mouldboard plough to turn over the heavy, wet soils of northern Europe. This led to the clearing of northern European forests and an increase in agricultural production, which in turn led to an increase in population.[89] At the same time, farmers in Europe moved from a two field crop rotation to a three field crop rotation in which one field of three was left fallow every year. This resulted in increased productivity and nutrition, as the change in rotations permitted nitrogen-fixing legumes such as peas, lentils and beans. Improved horse harnesses and the whippletree further improved cultivation.[89] Watermills were introduced by the Romans, but were improved throughout the Middle Ages, along with windmills, and used to grind grains into flour, to cut wood and to process flax and wool.[90]

Crops included wheat, rye, barley and oats. Peas, beans, and vetches became common from the 13th century onward as a fodder crop for animals and also for their nitrogen-fixation fertilizing properties. Crop yields peaked in the 13th century, and stayed more or less steady until the 18th century.[91] Though the limitations of medieval farming were once thought to have provided a ceiling for the population growth in the Middle Ages, recent studies[92][93] have shown that the technology of medieval agriculture was always sufficient for the needs of the people under normal circumstances, and that it was only during exceptionally harsh times, such as the terrible weather of 1315–17, that the needs of the population could not be met.[94][95]

Columbian exchange

Main article: Columbian exchange

After 1492, a global exchange of previously local crops and livestock breeds occurred. Maize, potatoes, sweet potatoes and manioc were the key crops that spread from the New World to the Old, while varieties of wheat, barley, rice and turnips traveled from the Old World to the New. There had been few livestock species in the New World, with horses, cattle, sheep and goats being completely unknown before their arrival with Old World settlers. Crops moving in both directions across the Atlantic Ocean caused population growth around the world and a lasting effect on many cultures.[96] Maize and cassava were introduced from Brazil into Africa by Portuguese traders in the 16th century,[97] becoming staple foods, replacing native African crops.[98]

After its introduction from South America to Spain in the late 1500s, the potato became a staple crop throughout Europe by the late 1700s. The potato allowed farmers to produce more food, and initially added variety to the European diet. The increased supply of food reduced disease, increased births and reduced mortality, causing a population boom throughout the British Empire, the US and Europe.[99] The introduction of the potato also brought about the first intensive use of fertilizer, in the form of guano imported to Europe from Peru, and the first artificial pesticide, in the form of an arsenic compound used to fight Colorado potato beetles. Before the adoption of the potato as a major crop, the dependence on grain had caused repetitive regional and national famines when the crops failed, including 17 major famines in England between 1523 and 1623. The resulting dependence on the potato however caused the European Potato Failure, a disastrous crop failure from disease that resulted in widespread famine and the death of over one million people in Ireland alone.[100]

Modern agriculture

British agricultural revolution

Charles 'Turnip' Townshend, agriculturalist who introduced four-field crop rotation and the cultivation of turnips

Between the 16th century and the mid-19th century, Britain saw a large increase in agricultural productivity and net output. New agricultural practices like enclosure, mechanization, four-field crop rotation to maintain soil nutrients, and selective breeding enabled an unprecedented population growth to 5.7 million in 1750, freeing up a significant percentage of the workforce, and thereby helped drive the Industrial Revolution. The productivity of wheat went up from about 19 bushels per acre in 1720 to around 30 bushels by 1840, marking a major turning point in history.[101]

Advice on more productive techniques for farming began to appear in England in the mid-17th century, from writers such as Samuel Hartlib, Walter Blith and others.[102] The main problem in sustaining agriculture in one place for a long time was the depletion of nutrients, most importantly nitrogen levels, in the soil. To allow the soil to regenerate, productive land was often let fallow and in some places crop rotation was used. The Dutch four-field rotation system was popularised by the British agriculturist Charles Townshend in the 18th century. The system (wheat, turnips, barley and clover), opened up a fodder crop and grazing crop allowing livestock to be bred year-round. The use of clover was especially important as the legume roots replenished soil nitrates.[103]

Shires selectively bred for size in the 18th century

The mechanisation and rationalisation of agriculture was another important factor. Robert Bakewell and Thomas Coke introduced selective breeding, and initiated a process of inbreeding to maximise desirable traits from the mid 18th century, such as the New Leicester sheep. Machines were invented to improve the efficiency of various agricultural operation, such as Jethro Tull's seed drill of 1701 that mechanised seeding at the correct depth and spacing and Andrew Meikle's threshing machine of 1784. Ploughs were steadily improved, from Joseph Foljambe's Rotherham iron plough in 1730[104] to James Small's improved "Scots Plough" metal in 1763. In 1789 Ransomes, Sims & Jefferies was producing 86 plough models for different soils.[105] Powered farm machinery began with Richard Trevithick's stationary steam engine, used to drive a threshing machine, in 1812.[106] Mechanisation spread to other farm uses through the 19th century. The first petrol-driven tractor was built in America by John Froelich in 1892.[107]

The scientific investigation of fertilization began at the Rothamsted Experimental Station in 1843 by John Bennet Lawes. He investigated the impact of inorganic and organic fertilizers on crop yield and founded one of the first artificial fertilizer manufacturing factories in 1842. Fertilizer, in the shape of sodium nitrate deposits in Chile, was imported to Britain by John Thomas North as well as guano (birds droppings). The first commercial process for fertilizer production was the obtaining of phosphate from the dissolution of coprolites in sulphuric acid.[108]

20th century

Early 20th century image of a tractor ploughing an alfalfa field

Dan Albone constructed the first commercially successful gasoline-powered general purpose tractor in 1901, and the 1923 International Harvester Farmall tractor marked a major point in the replacement of draft animals (particularly horses) with machines. Since that time, self-propelled mechanical harvesters (combines), planters, transplanters and other equipment have been developed, further revolutionizing agriculture.[109] These inventions allowed farming tasks to be done with a speed and on a scale previously impossible, leading modern farms to output much greater volumes of high-quality produce per land unit.[110]

The Haber-Bosch method for synthesizing ammonium nitrate represented a major breakthrough and allowed crop yields to overcome previous constraints. It was first patented by German chemist Fritz Haber. In 1910 Carl Bosch, while working for German chemical company BASF, successfully commercialized the process and secured further patents. In the years after World War II, the use of synthetic fertilizer increased rapidly, in sync with the increasing world population.[111]

In the past century agriculture has been characterized by increased productivity, the substitution of synthetic fertilizers and pesticides for labor, water pollution,[112] and farm subsidies.[113] Other applications of scientific research since 1950 in agriculture include gene manipulation,[114][115] Hydroponics,[116] and the development of economically viable biofuels such as Ethanol.[117]

In recent years there has been a backlash against the external environmental effects of conventional agriculture, resulting in the organic movement.[118] Famines continued to sweep the globe through the 20th century. Through the effects of climactic events, government policy, war and crop failure, millions of people died in each of at least ten famines between the 1920s and the 1990s.[119]

The historical processes that have allowed agricultural crops to be cultivated and eaten well beyond their centers of origin continues in the present through globalization. On average, 68.7% of a nation's food supplies and 69.3% of its agricultural production are of crops with foreign origins.[120]

Green Revolution

Main article: Green Revolution
Norman Borlaug, father of the Green Revolution, is often credited with saving over a billion people worldwide from starvation.

The Green Revolution refers to a series of research, development, and technology transfer initiatives, occurring between the 1940s and the late 1970s, that increased agriculture production around the world, beginning most markedly in the late 1960s. The initiatives, led by Norman Borlaug and credited with saving over a billion people from starvation, involved the development of high-yielding varieties of cereal grains, expansion of irrigation infrastructure, modernization of management techniques, distribution of hybridized seeds, synthetic fertilizers, and pesticides to farmers.[121]

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 were introduced as a part of the Green Revolution. The Green Revolution exported the technologies (including pesticides and synthetic nitrogen) of the developed world 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.[122]

Although the Green Revolution significantly increased rice yields in Asia, yield increases have not occurred in the past 15–20 years.[123] The genetic "yield potential" has increased for wheat, but the yield potential for rice has not increased since 1966, and the yield potential for maize has "barely increased in 35 years".[123] It takes only a decade or two for herbicide-resistant weeds to emerge, and insects become resistant to insecticides within about a decade, delayed somewhat by crop rotation.[123]

Organic agriculture

Main article: Organic farming

For most of its history, agriculture has been organic agriculture, that is farming without synthetic fertilisers and pesticides, as well as without GMOs. With the advent of chemical agriculture there has been the call for farming without synthetic chemicals. Rudolf Steiner was the first to call for such a differentiated agriculture and his Agriculture Course of 1924 laid the foundation for the development of biodynamic agriculture.[124] Lord Northbourne developed these ideas and presented his manifesto of organic farming in 1940 and they have since then been taken up as a worldwide movement and organic farming is now practiced in most countries.[125]

See also


  1. Hillman, G. C. (1996) "Late Pleistocene changes in wild plant-foods available to hunter-gatherers of the northern Fertile Crescent: Possible preludes to cereal cultivation". In D. R. Harris (ed.) The Origins and Spread of Agriculture and Pastoralism in Eurasia, UCL Books, London, pp.159-203; Sato, Y. (2003) "Origin of rice cultivation in the Yangtze River basin". In Y. Yasuda (ed.) The Origins of Pottery and Agriculture, Roli Books, New Delhi, p. 196
  2. Gerritsen, R. (2008). Australia and the Origins of Agriculture. Archaeopress. pp. 29–30.
  3. "The Development of Agriculture". National Geographic. 2016. Retrieved 15 June 2016.
  4. "Climate". National Climate Data Center. Retrieved 1 December 2013.
  5. "The Development of Agriculture". National Geographic. 2016. Retrieved 20 June 2016.
  6. Gammage, Bill (2005). "'…far more happier than we Europeans': Aborigines and farmers" (PDF). London Papers in Australian Studies (formerly Working Papers in Australian Studies). London: Menzies Centre for Australian Studies. King's College (12): 1–27. ISSN 1746-1774.
  7. 1 2 3 Gammage, Bill (October 2011). The Biggest Estate on Earth: How Aborigines made Australia. Crows Nest, N.S.W: Allen & Unwin. ISBN 9781742377483. Retrieved 12 Oct 2011.
  8. Douglas John McConnell (2003). The Forest Farms of Kandy: And Other Gardens of Complete Design. p. 1. ISBN 978-0-7546-0958-2.
  9. McConnell, Douglas John (1992). The forest-garden farms of Kandy, Sri Lanka. p. 1. ISBN 978-92-5-102898-8.
  10. Allaby, Robin G.; Fuller, Dorian Q.; Brown, Terence A. (2008). "The genetic expectations of a protracted model for the origins of domesticated crops". Proceedings of the National Academy of Sciences. 105 (37): 13982–13986. doi:10.1073/pnas.0803780105.
  11. Larson, G.; Piperno, D. R.; Allaby, R. G.; Purugganan, M. D.; Andersson, L.; Arroyo-Kalin, M.; Barton, L.; Climer Vigueira, C.; Denham, T.; Dobney, K.; Doust, A.N.; Gepts, P.; Gilbert, M. T. P.; Gremillion, K. J.; Lucas, L.; Lukens, L.; Marshall, F. B.; Olsen, K.M.; Pires, J.C.; Richerson, P.J.; Rubio De Casas, R.; Sanjur, O.I.; Thomas, M.G.; Fuller, D.Q. (2014). "Current perspectives and the future of domestication studies". Proceedings of the National Academy of Sciences. 111 (17): 6139. doi:10.1073/pnas.1323964111.
  12. Nelson, Sarah M. (1998). Ancestors for the Pigs. Pigs in prehistory. University of Pennsylvania Museum of Archaeology and Anthropology.
  13. Ensminger, M.E.; Parker, R.O. (1986). Sheep and Goat Science (Fifth ed.). Interstate Printers and Publishers. ISBN 0-8134-2464-X.
  14. McTavish, E.J., Decker, J.E., Schnabel, R.D., Taylor, J.F. and Hillis, D.M.year=2013. "New World cattle show ancestry from multiple independent domestication events". Proc. Natl. Acad. Sci. U.S.A. 110: E1398–406. doi:10.1073/pnas.1303367110. PMC 3625352Freely accessible. PMID 23530234.
  15. Sapir-Hen, Lidar; Erez Ben-Yosef (2013). "The Introduction of Domestic Camels to the Southern Levant: Evidence from the Aravah Valley" (PDF). Tel Aviv. 40: 277–285. doi:10.1179/033443513x13753505864089. Retrieved 16 February 2014.
  16. Ladizinsky, G. (1998). Plant Evolution under Domestication. The Netherlands: Kluwer Academic Publishers
  17. Mordechai E. Kislev, Anat Hartmann, and Ofer Bar-Yosef, "Early Domesticated Fig in the Jordan Valley," in Science Magazine (June 2, 2006). Vol. 312, No. 5778, pp. 1372-1374. doi:10.1126/science.1125910
  18. Science Magazine (Dec. 15, 2006). Vol. 314, No. 5806, p. 1683. Response to Comment on 'Early Domesticated Fig in the Jordan Valley' by Mordechai E. Kislev, Anat Hartmann and Ofer Bar-Yosef. doi:10.1126/science.1132636
  19. Dolores R. Piperno, Anthony J. Ranere, Irene Holst, Jose Iriarte and Ruth Dickau (2009). "Starch grain and phytolith evidence for early ninth millennium B.P. maize from the Central Balsas River Valley, Mexico". PNAS. 106 (13).
  20. Smith, A. F. (1994). The Tomato in America: Early History, Culture, and Cookery. Columbia SC, USA: University of South Carolina Press. p. 13. ISBN 1-57003-000-6.
  21. Hirst, K. Kris. "Plant Domestication - Table of Dates and Places". About.com. Retrieved 15 June 2016.
  22. Denham et al. (19 June 2003) "Origins of Agriculture at Kuk Swamp in the Highlands of New Guinea". Science 301(5630):189-193.
  23. http://www.dartmouth.edu/~prehistory/aegean/?page_id=107
  24. https://books.google.com/books?id=VfT6hZHpXPkC&pg=PA4&lpg=PA4
  25. Oldest farming village on Mediterranean islands
  26. 1 2 "Southern Europe, 8000–2000 B.C. Timeline of Art History". The Metropolitan Museum of Art. Retrieved 2011-07-16.
  27. "Ceide Fields Visitor Centre, Ballycastle, County Mayo, West of Ireland". Museumsofmayo.com. Retrieved 2011-07-16.
  28. "Ceide Fields - UNESCO World Heritage Centre". Whc.unesco.org. Retrieved 2011-07-16.
  29. Anthony, David W. (2007). The Horse, the Wheel, and Language: How Bronze-Age Riders from the Eurasian Steppes Shaped the Modern World. Princeton, NJ: Princeton University Press.
  30. Vergara, Daniela (2 December 2014). "Cannabis: Marijuana, hemp and its cultural history". Cannabis Genomics. Archived from the original on 9 April 2016. Retrieved 20 June 2016.
  31. Carney, Judith (2011). Food and the African Past. In the Shadow of Slavery: Africa’s Botanical Legacy in the Atlantic World. University of California Press. p. 24. ISBN 978-0-520-94953-9.
  32. 1 2 3 Murphy, Denis (2011). Plants, Biotechnology and Agriculture. CABI. pp. 153–. ISBN 978-1-84593-913-7.
  33. Barker, Graeme (2009). The Agricultural Revolution in Prehistory: Why Did Foragers Become Farmers?. Oxford University Press. pp. 159–161. ISBN 978-0-19-955995-4.
  34. Anderson, David; Goudie, Andrew; Parker, Adrian (2013). Global Environments Through the Quaternary: Exploring Evironmental Change. OUP Oxford. p. 283. ISBN 978-0-19-969726-7.
  35. "Farming". British Museum. Retrieved 15 June 2016.
  36. Tannahill, Reay (1968). The fine art of food. Folio Society.
  37. Kees, Herman (1961). Ancient Egypt: A Cultural Topography. University of Chicago Press.
  38. Janick, Jules. "Ancient Egyptian Agriculture and the Origins of Horticulture". Acta Hort. 583: 23–39.
  39. Stein, Burton (1998). A History of India. Blackwell Publishing. 47. ISBN 0-631-20546-2.
  40. 1 2 Gupta, Anil K. in Origin of agriculture and domestication of plants and animals linked to early Holocene climate amelioration, Current Science, Vol. 87, No. 1, 10 July 2004 59. Indian Academy of Sciences.
  41. Baber, Zaheer (1996). The Science of Empire: Scientific Knowledge, Civilization, and Colonial Rule in India. State University of New York Press. 19. ISBN 0-7914-2919-9.
  42. 1 2 3 Harris, David R. and Gosden, C. (1996). The Origins and Spread of Agriculture and Pastoralism in Eurasia: Crops, Fields, Flocks And Herds. Routledge. p.385. ISBN 1-85728-538-7.
  43. Possehl, Gregory L. (1996). Mehrgarh in Oxford Companion to Archaeology, edited by Brian Fagan. Oxford University Press.
  44. 1 2 Rodda & Ubertini (2004). The Basis of Civilization--water Science?. International Association of Hydrological Science. 279. ISBN 1-901502-57-0.
  45. Lal, R. (August 2001). "Thematic evolution of ISTRO: transition in scientific issues and research focus from 1955 to 2000". Soil and Tillage Research. 61 (1–2): 3–12 [3]. doi:10.1016/S0167-1987(01)00184-2.
  46. Needham, Joseph (1986). Science and Civilization in China: Volume 6, Part 2. Taipei: Caves Books Ltd. p55-56.
  47. 1 2 Needham, Volume 6, Part 2, 56.
  48. Needham, Volume 6, Part 2, 57.
  49. Needham, Joseph (1986). Science and Civilization in China: Volume 4, Physics and Physical Technology, Part 2, Mechanical Engineering. Taipei: Caves Books, Ltd. p184
  50. Needham, Volume 4, Part 2, 89, 110.
  51. Needham, Volume 4, Part 2, 33.
  52. Needham, Volume 4, Part 2, 110.
  53. Robert Greenberger, The Technology of Ancient China (New York: Rosen Publishing Group, Inc., 2006), pp. 11–12.
  54. Wang Zhongshu, trans. by K. C. Chang and Collaborators, Han Civilization (New Haven and London: Yale University Press, 1982).
  55. Glick, Thomas F. (2005). Medieval Science, Technology And Medicine: An Encyclopedia. Volume 11 of The Routledge Encyclopedias of the Middle Ages Series. Psychology Press. p. 270. ISBN 0415969301.
  56. Molina, J.; Sikora, M.; Garud, N.; Flowers, J. M.; Rubinstein, S.; Reynolds, A.; Huang, P.; Jackson, S.; Schaal, B. A.; Bustamante, C. D.; Boyko, A. R.; Purugganan, M. D. (2011). "Molecular evidence for a single evolutionary origin of domesticated rice". Proceedings of the National Academy of Sciences. 108 (20): 8351. doi:10.1073/pnas.1104686108.
  57. Huang, Xuehui; Kurata, Nori; Wei, Xinghua; Wang, Zi-Xuan; Wang, Ahong; Zhao, Qiang; Zhao, Yan; Liu, Kunyan; et al. (2012). "A map of rice genome variation reveals the origin of cultivated rice". Nature. 490 (7421): 497–501. Bibcode:2012Natur.490..497H. doi:10.1038/nature11532. PMID 23034647.
  58. 1 2 White, K. D. (1970), Roman Farming (Cornell University Press)
  59. Johannessen, S.; Hastorf, C. A. (eds.). Corn and Culture in the Prehistoric New World. Westview Press.
  60. Speller, Camilla F.; et al. (2010). "Ancient mitochondrial DNA analysis reveals complexity of indigenous North American turkey domestication". PNAS. 107 (7): 2807–2812. doi:10.1073/pnas.0909724107.
  61. Mascarelli, Amanda (5 November 2010). "Mayans converted wetlands to farmland". Nature. doi:10.1038/news.2010.587.
  62. Morgan, John (6 November 2013). "Invisible Artifacts: Uncovering Secrets of Ancient Maya Agriculture with Modern Soil Science". Soil Horizons. 53 (6): 3. doi:10.2136/sh2012-53-6-lf.
  63. Spooner, David M.; McLean, Karen; Ramsay, Gavin; Waugh, Robbie; Bryan, Glenn J. (2005). "A single domestication for potato based on multilocus amplified fragment length polymorphism genotyping". PNAS. 102 (41): 14694–99. doi:10.1073/pnas.0507400102. PMC 1253605Freely accessible. PMID 16203994.
  64. Office of International Affairs (1989). Lost Crops of the Incas: Little-Known Plants of the Andes with Promise for Worldwide Cultivation. nap.edu. p. 92. ISBN 030904264X.
  65. John Michael Francis (2005). Iberia and the Americas. ABC-CLIO. ISBN 1-85109-426-1.
  66. Broudy, Eric (1979). The Book of Looms: A History of the Handloom from Ancient Times to the Present. UPNE. p. 81. ISBN 978-0-87451-649-4.
  67. Rischkowsky, Barbara; Pilling, Dafydd (2007). The State of the World's Animal Genetic Resources for Food and Agriculture. Food & Agriculture Organization. p. 10. ISBN 978-92-5-105762-9.
  68. Heiser, Carl B., Jr. (1992) On possible sources of the tobacco of prehistoric Eastern North America. Current Anthropology 33:54-56.
  69. Prehistoric Food Production in North America, edited by Richard I. Ford. Museum of Anthropology, University of Michigan, Anthropological Papers 75.
  70. Adair, Mary J. (1988) Prehistoric Agriculture in the Central Plains. Publications in Anthropology 16. University of Kansas, Lawrence.
  71. Smith, Andre w (2013). The Oxford Encyclopedia of Food and Drink in America. OUP USA. pp. 1–. ISBN 978-0-19-973496-2.
  72. Paul E. Minnis (editor) (2003) People and Plants in Ancient Eastern North America. Smithsonian Institution Press, Washington, D.C.
  73. "Pecans at Texas A&M University". Pecankernel.tamu.edu. 2006-08-18. Retrieved 2010-06-03.
  74. The History of Concord Grapes, http://www.concordgrape.org/bodyhistory.html
  75. Neil G. Sugihara; Jan W. Van Wagtendonk; Kevin E. Shaffer; Joann Fites-Kaufman; Andrea E. Thode, eds. (2006). "17". Fire in California's Ecosystems. University of California Press. p. 417. ISBN 978-0-520-24605-8.
  76. Blackburn, Thomas C. and Kat Anderson, ed. (1993). Before the Wilderness: Environmental Management by Native Californians. Menlo Park, California: Ballena Press. ISBN 0879191260.
  77. Cunningham, Laura (2010). State of Change: Forgotten Landscapes of California. Berkeley, California: Heyday. pp. 135, 173–202. ISBN 1597141364.
  78. Anderson, M. Kat (2006). Tending the Wild: Native American Knowledge And the Management of California's Natural Resources. University of California Press. ISBN 0520248511.
  79. Jones, R. (1969) Fire-stick Farming. Australian Natural History, 16:224
  80. Williams, E. (1988) Complex Hunter-Gatherers: A Late Holocene Example from Temperate Australia. British Archaeological Reports, Oxford
  81. Lourandos, H. (1997) Continent of Hunter-Gatherers: New Perspectives in Australian Prehistory Cambridge, Cambridge University Press, Cambridge
  82. Gerritsen 2008
  83. Stromberg, Joseph (February 2013). "Classical gas". Smithsonian. 43 (10): 18. Retrieved 27 August 2013.
  84. 1 2 3 Watson, Andrew M. (1974). "The Arab Agricultural Revolution and Its Diffusion, 700-1100". The Journal of Economic History. 34 (1): 8–35. doi:10.1017/s0022050700079602.
  85. Watson, Andrew M. (1983). Agricultural Innovation in the Early Islamic World. Cambridge University Press. ISBN 0-521-24711-X.
  86. National Geographic (2015). Food Journeys of a Lifetime. National Geographic Society. pp. 126–. ISBN 978-1-4262-1609-1.
  87. Jourdan, Pablo. "Medieval Horticulture/Agriculture". Ohio State University. Retrieved 2013-04-24.
  88. Janick, Jules (2008). "Islamic Influences on Western Agriculture" (PDF). Purdue University. Retrieved 2013-05-23.
  89. 1 2 Backer, Patricia. "Part 1 – Medieval European history". History of Technology. San Jose State University. Retrieved 24 April 2013.
  90. Newman, Paul B. (2001). Daily Life in the Middle Ages. McFarland. pp. 88–89. ISBN 0786450525.
  91. Campbell, Bruce M. S.; M. Overton (1993). "A New Perspective on Medieval and Early Modern Agriculture: Six Centuries of Norfolk Farming, c.1250-c.1850". Past and Present. 141: 38–105. doi:10.1093/past/141.1.38.
  92. Campbell, Bruce M.S. (2000). English Seigniorial Agriculture, 1250–1450. Cambridge University Press. ISBN 0-521-30412-1.
  93. Stone, David (2005). Decision-Making in Medieval Agriculture. Oxford University Press. ISBN 0-19-924776-5.
  94. John Langdon (2010). Robert E. Bjork, ed. The Oxford Dictionary of the Middle Ages. Oxford, England: Oxford University Press. pp. 20–23. ISBN 978-0-19-866262-4.
  95. Jordan, William Chester (1997). The Great Famine: Northern Europe in the Early Fourteenth Century. Princeton U.P.
  96. Crosby, Alfred. "The Columbian Exchange". The Gilder Lehrman Institute of American History. Retrieved 2013-05-11.
  97. Wagner, Holly. "Super-Sized Cassava Plants May Help Fight Hunger In Africa". The Ohio State University. Retrieved 2013-05-11.
  98. Florence Wambugu; John Wafula, eds. (2000). "Advances in Maize Streak Virus Disease Research in Eastern and Southern Africa". International Service for the Acquisition of Agri-Biotech Applications. Retrieved 2013-04-16.
  99. Chapman, Jeff. "The Impact of the Potato". History Magazine (2).
  100. Mann, Charles C. (November 2011). "How the Potato Changed History". Smithsonian.
  101. Snell, K.D.M. (1985). Annals of the Labouring Poor, Social Change and Agrarian England 1660–1900. Cambridge University Press. ISBN 0-521-24548-6. Chapter 4
  102. Thirsk, Joan. "'Blith, Walter (bap. 1605, d. 1654)'". Oxford Dictionary of National Biography, Oxford University Press, 2004; online edn, Jan 2008. Retrieved 2 September 2011.
  103. Jaap Harskamp, "The Low Countries and the English Agricultural Revolution." (2009): 32-41. in JSTOR
  104. The Rotherham Plough
  105. Barlow, Robert Stockes; "300 Years of Farm Implements and Machinery 1630–1930"; Krause Publications (2003); p.33; ISBN 978-0873496322
  106. Hodge, James (1973). Richard Trevithick. Shire Publications. p. 30. ISBN 0-85263-177-4.
  107. Macmillan, Don; Broehl, Wayne G. The John Deere Tractor Legacy. Voyageur Press. p. 45.
  108. Coprolite Fertilizer Industry in Britain Accessed 3 April 2012
  109. Janick, Jules. "Agricultural Scientific Revolution: Mechanical" (PDF). Purdue University. Retrieved 24 May 2013.
  110. Reid, John F. (2011). "The Impact of Mechanization on Agriculture". The Bridge on Agriculture and Information Technology. 41 (3).
  111. "A Historical Perspective". International Fertilizer Industry Association. Retrieved 7 May 2013.
  112. Moss, Brian (2008). "Water Pollution by Agriculture" (PDF). Phil. Trans. Royal Society B. 363: 659–666. doi:10.1098/rstb.2007.2176.
  113. "Title 05 – Agriculture and rural development". Retrieved 16 June 2016.
  114. James, Clive (1996). "Global Review of the Field Testing and Commercialization of Transgenic Plants: 1986 to 1995" (PDF). The International Service for the Acquisition of Agri-biotech Applications. Retrieved 17 July 2010.
  115. Weasel, Lisa H. 2009. Food Fray. Amacom Publishing
  116. Douglas, James S., Hydroponics, 5th ed. Bombay: Oxford UP, 1975. 1–3
  117. "Towards Sustainable Production and Use of Resources: Assessing Biofuels" (PDF). United Nations Environment Programme. 16 October 2009. Retrieved 24 October 2009.
  118. Philpott, Tom (19 April 2013). "A Brief History of Our Deadly Addiction to Nitrogen Fertilizer". Mother Jones. Retrieved 7 May 2013.
  119. "Ten worst famines of the 20th century". Sydney Morning Herald. 15 August 2011.
  120. Khoury, C.K.; Achicanoy, H.A.; Bjorkman, A.D.; Navarro-Racines, C.; Guarino, L.; Flores-Palacios, X.; Engels, J.M.M.; Wiersema, J.H.; Dempewolf, H.; Sotelo, S.; Ramírez-Villegas, J.; Castañeda-Álvarez, N.P.; Fowler, C.; Jarvis, A.; Rieseberg, L.H.; Struik, P.C. (2016). "Origins of food crops connect countries worldwide". Proc. R. Soc. B. 283 (1832): 20160792. doi:10.1098/rspb.2016.0792.
  121. Hazell, Peter B.R. (2009). The Asian Green Revolution. IFPRI Discussion Paper. International Food Policy Research Institute. GGKEY:HS2UT4LADZD.
  122. Barrionuevo, Alexei; Bradsher, Keith (8 December 2005). "Sometimes a Bumper Crop Is Too Much of a Good Thing". The New York Times.
  123. 1 2 3 Tilman D, Cassman KG, Matson PA, Naylor R, Polasky S (August 2002). "Agricultural sustainability and intensive production practices" (PDF). Nature. 418 (6898): 671–7. doi:10.1038/nature01014. PMID 12167873.
  124. Paull, John (2011) "Attending the First Organic Agriculture Course: Rudolf Steiner’s Agriculture Course at Koberwitz, 1924", European Journal of Social Sciences, 21(1):64-70.
  125. Paull, John (2014) Lord Northbourne, the man who invented organic farming, a biography, Journal of Organic Systems, 9 (1), pp. 31-53.

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