History of agriculture

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Ploughing with a yoke of horned cattle in Ancient Egypt. Painting from the burial chamber of Sennedjem, c. 1200 BC. Maler der Grabkammer des Sennudem 001.jpg
Ploughing with a yoke of horned cattle in Ancient Egypt. Painting from the burial chamber of Sennedjem, c.1200 BC.

Agriculture began independently in different parts of the globe, and included a diverse range of taxa. At least eleven separate regions of the Old and New World were involved as independent centers of origin. The development of agriculture about 12,000 years ago changed the way humans lived. They switched from nomadic hunter-gatherer lifestyles to permanent settlements and farming. [1]

Contents

Wild grains were collected and eaten from at least 104,000 years ago. [2] However, domestication did not occur until much later. The earliest evidence of small-scale cultivation of edible grasses is from around 21,000 BC with the Ohalo II people on the shores of the Sea of Galilee. [3] By around 9500 BC, the eight Neolithic founder crops  emmer wheat, einkorn wheat, hulled barley, peas, lentils, bitter vetch, chickpeas, and flax  – were cultivated in the Levant. [4] Rye may have been cultivated earlier, but this claim remains controversial. [5] Regardless, rye's spread from Southwest Asia to the Atlantic was independent of the Neolithic founder crop package. [6] Rice was domesticated in China by 6200 BC [7] with earliest known cultivation from 5700 BC, followed by mung, soy and azuki beans. Rice was also independently domesticated in West Africa and cultivated by 1000 BC. [8] [9] Pigs were domesticated in Mesopotamia around 11,000 years ago, followed by sheep. Cattle were domesticated from the wild aurochs in the areas of modern Turkey and India around 8500 BC. Camels were domesticated late, perhaps around 3000 BC.

In subsaharan Africa, sorghum was domesticated in the Sahel region of Africa by 3000 BC, along with pearl millet by 2000 BC. [10] [11] Yams were domesticated in several distinct locations, including West Africa (unknown date), and cowpeas by 2500 BC. [12] [13] Rice (African rice) was also independently domesticated in West Africa and cultivated by 1000 BC. [8] [9] Teff and likely finger millet were domesticated in Ethiopia by 3000 BC, along with noog, ensete, and coffee. [14] [15] Other plant foods domesticated in Africa include watermelon, okra, tamarind and black eyed peas, along with tree crops such as the kola nut and oil palm. [16] Plantains were cultivated in Africa by 3000 BC and bananas by 1500 BC. [17] [18] The helmeted guineafowl was domesticated in West Africa. [19] Sanga cattle was likely also domesticated in North-East Africa, around 7000 BC, and later crossbred with other species. [20] [21]

In South America, agriculture began as early as 9000 BC, starting with the cultivation of several species of plants that later became only minor crops. In the Andes of South America, the potato was domesticated between 8000 BC and 5000 BC, along with beans, squash, tomatoes, peanuts, coca, llamas, alpacas, and guinea pigs. Cassava was domesticated in the Amazon Basin no later than 7000 BC. Maize (Zea mays) found its way to South America from Mesoamerica, where wild teosinte was domesticated about 7000 BC and selectively bred to become domestic maize. Cotton was domesticated in Peru by 4200 BC; another species of cotton was domesticated in Mesoamerica and became by far the most important species of cotton in the textile industry in modern times. [22] Evidence of agriculture in the Eastern United States dates to about 3000 BCE. Several plants were cultivated, later to be replaced by the Three Sisters cultivation of maize, squash, and beans.

Sugarcane and some root vegetables were domesticated in New Guinea around 7000 BC. Bananas were cultivated and hybridized in the same period in Papua New Guinea. In Australia, agriculture was invented at a currently unspecified period, with the oldest eel traps of Budj Bim dating to 6,600 BC [23] and the deployment of several crops ranging from yams [24] to bananas. [25]

The Bronze Age, from c.3300 BC, witnessed the intensification of agriculture in civilizations such as Mesopotamian Sumer, ancient Egypt, ancient Sudan, the Indus Valley civilisation of the Indian subcontinent, ancient China, and ancient Greece. 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. [26] During the Iron Age and era of classical antiquity, the expansion of ancient Rome, both the Republic and then the Empire, throughout the ancient Mediterranean and Western Europe built upon existing systems of agriculture while also establishing the manorial system that became a bedrock of medieval agriculture. In the Middle Ages, both in Europe and in the Islamic world, 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 the voyages of Christopher Columbus in 1492, the Columbian exchange brought New World crops such as maize, potatoes, tomatoes, 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 overpopulation, water pollution, biofuels, genetically modified organisms, tariffs and farm subsidies. In response, organic farming developed in the twentieth century as an alternative to the use of synthetic pesticides.

Origins

Origin hypotheses

Indigenous Australian camp by Skinner Prout, 1876 Native Encampment by Skinner Prout, from Australia (1876, vol II).jpg
Indigenous Australian camp by Skinner Prout, 1876

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 the Levant, 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 immediately domesticated. [27] [28]

Localised climate change is the favoured explanation for the origins of agriculture in the Levant. [1] 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. [29] 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. [1] Across Western Eurasia it was not until approximately 4,000 BC that farming societies completely replaced hunter-gatherers. These technologically advanced societies expanded faster in areas with less forest, pushing hunter-gatherers into denser woodlands. Only the middle-late Bronze Age and Iron Age societies were able to fully replace hunter-gatherers in their final stronghold located in the most densely forested areas. Unlike their Bronze and Iron Age counterparts, Neolithic societies couldn't establish themselves in dense forests, and Copper Age societies had only limited success. [30]

Early development

Sumerian harvester's sickle, 3000 BC, made from baked clay ClaySumerianSickle.jpg
Sumerian harvester's sickle, 3000 BC, made from baked clay

Early people began altering communities of flora and fauna for their own benefit through means such as fire-stick farming and forest gardening very early. [31] [32] [33] Wild grains have been collected and eaten from at least 105,000 years ago, and possibly much longer. [2] 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. [34]

An Indian farmer with a rock-weighted scratch plough pulled by two oxen. Similar ploughs were used throughout antiquity. Traditional Farming Methods and Equipments.jpg
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. [35] Some of the earliest known domestications were of animals. Domestic pigs had multiple centres of origin in Eurasia, including Europe, East Asia and Southwest Asia, [36] where wild boar were first domesticated about 10,500 years ago. [37] Sheep were domesticated in Mesopotamia between 11,000 BC and 9000 BC. [38] Cattle were domesticated from the wild aurochs in the areas of modern Turkey and India around 8500 BC. [39] Camels were domesticated relatively late, perhaps around 3000 BC. [40]

Centres of origin identified by Nikolai Vavilov in the 1930s. Area 3 (grey) is no longer recognised as a centre of origin, and Papua New Guinea (red, 'P') was identified more recently. Vavilov-centers updated.jpg
Centres of origin identified by Nikolai Vavilov in the 1930s. Area 3 (grey) is no longer recognised as a centre of origin, and Papua New Guinea (red, 'P') was identified more recently.

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.[ citation needed ][ dubious discuss ] At around the same time (9400 BC), parthenocarpic fig trees were domesticated. [42] [43]

Domesticated rye occurs in small quantities at some Neolithic sites in (Asia Minor) Turkey, such as the Pre-Pottery Neolithic B (c. 7600 – c. 6000 BC) Can Hasan III near Çatalhöyük, [44] but is otherwise absent until the Bronze Age of central Europe, c. 1800–1500 BC. [45] Claims of much earlier cultivation of rye, at the Epipalaeolithic site of Tell Abu Hureyra in the Euphrates valley of northern Syria, remain controversial. [46] Critics point to inconsistencies in the radiocarbon dates, and identifications based solely on grain, rather than on chaff. [47]

By 8000 BC, farming was entrenched on the banks of the 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 southern Mexico by 6700 BC. [48] The potato (8000 BC), tomato, [49] pepper (4000 BC), squash (8000 BC) and several varieties of bean (8000 BC onwards) were domesticated in the New World.[ citation needed ]

Agriculture was independently developed on the island of New Guinea. [50] Banana cultivation of Musa acuminata , including hybridization, dates back to 5000 BC, and possibly to 8000 BC, in Papua New Guinea. [51] [52]

Bees were kept for honey in the Middle East around 7000 BC. [53] Archaeological evidence from various sites on the Iberian peninsula suggest the domestication of plants and animals between 6000 and 4500 BC. [54] The Céide Fields, located in Ireland consist of extensive tracts of land enclosed by stone walls, these walls date to 3500 BC and is the oldest known field systems in europe. [55] [56] The horse was domesticated in the Pontic steppe around 4000 BC In Siberia. [57] 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. [58]

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. Old bull cart.jpg
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 northern China, millet was domesticated by early Sino-Tibetan speakers at around 8000 to 6000 BC, becoming the main crop of the Yellow River basin by 5500 BC. [59] [60] They were followed by mung, soy and azuki beans.

Chronological dispersal of Austronesian peoples across the Indo-Pacific Chronological dispersal of Austronesian people across the Pacific.svg
Chronological dispersal of Austronesian peoples across the Indo-Pacific

In southern China, rice was domesticated in the Yangtze River basin at around 11,500 to 6200 BC, along with the development of wetland agriculture, by early Austronesian and Hmong-Mien-speakers. Other food plants were also harvested, including acorns, water chestnuts, and foxnuts. [7] [59] [62] [63] Rice cultivation was later spread to Maritime Southeast Asia by the Austronesian expansion, starting at around 3,500 to 2,000 BC. This migration event also saw the introduction of cultivated and domesticated food plants from Taiwan, Maritime Southeast Asia, and New Guinea into the Pacific Islands as canoe plants. Contact with Sri Lanka and Southern India by Austronesian sailors also led to an exchange of food plants which later became the origin of the valuable spice trade. [64] [65] [66] In the 1st millennium AD, Austronesian sailors also settled Madagascar and the Comoros, bringing Southeast Asian and South Asian food plants with them to the East African coast, including bananas and rice. [67] [68] Rice was also spread southwards into Mainland Southeast Asia by around 2000 to 1500 BC by the migrations of the early Austroasiatic and Kra-Dai-speakers. [62]

In the Sahel region of Africa, sorghum was domesticated by 3000 BC in Sudan [69] and pearl millet by 2500 BC in Mali. [70] Kola nut and coffee were also domesticated in Africa. [71] In New Guinea, ancient Papuan peoples began practicing agriculture around 7000 BC, domesticating sugarcane and taro. [72] 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. [73]

Maize and squash were domesticated in Mesoamerica; potatoes in South America, and sunflowers in the Eastern Woodlands of North America. [74]

Civilizations

Sumer

Domesticated animals on a Sumerian cylinder seal, 2500 BC VAM - Rollsiegel 1.jpg
Domesticated animals on a Sumerian cylinder seal, 2500 BC

Sumerian farmers grew the cereals barley and wheat, starting to live in villages from about 8000 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 3000 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. [75] [76]

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. Tomb of Nakht (2).jpg
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, starting in the pre-dynastic period from the end of the Paleolithic into the Neolithic, between around 10,000 BC and 4000 BC. [77] This was made possible with the development of basin irrigation. [78] Their staple food crops were grains such as wheat and barley, alongside industrial crops such as flax and papyrus. [77] Archaeological evidence also suggests that the spread of agriculture in Egypt was facilitated by farming communities associated with the playa lakes of the Sahara some 6,500 years ago. [79]

Indian Subcontinent

Jujube was domesticated in the Indian subcontinent by 9000 BC. [80] Barley and wheat cultivation – along with the domestication of cattle, primarily sheep and goats – followed in Mehrgarh culture by 8000–6000 BC. [81] [82] [83] This period also saw the first domestication of the elephant. [80] Pastoral farming in India included threshing, planting crops in rows – either of two or of six – and storing grain in granaries. [82] [84] Cotton was cultivated by the 5th–4th millennium BC. [85] By the 5th millennium BC, agricultural communities became widespread in Kashmir. [82] Irrigation was developed in the Indus Valley Civilisation by around 4500 BC. [86] The size and prosperity of the Indus civilization grew as a result of this innovation, leading to more thoroughly planned settlements which used drainage and sewers. [86] Archeological evidence of an animal-drawn plough dates back to 2500 BC in the Indus Valley Civilization. [87]

Ancient China

Ancient rice terraces in Yuanyang County, Yunnan Terrace field yunnan china.jpg
Ancient rice terraces in Yuanyang County, Yunnan

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 Qimin Yaoshu of AD 535, written by Jia Sixie. [88] 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. [89] 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. [90] 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 1313. [89]

A Northern Song era (960-1127 AD) Chinese watermill for dehusking grain with a horizontal waterwheel Song Dynasty Hydraulic Mill for Grain.JPG
A Northern Song era (960–1127 AD) Chinese watermill for dehusking grain with a horizontal waterwheel

For agricultural purposes, the Chinese had innovated the hydraulic-powered trip hammer by the 1st century BC. [91] 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. [92] Although the chain pump found use in public works of providing water for urban and palatial pipe systems, [93] it was used largely to lift water from a lower to higher elevation in filling irrigation canals and channels for farmland. [94] By the end of the Han dynasty in the late 2nd century, heavy ploughs had been developed with iron ploughshares and mouldboards. [95] [96] These slowly spread west, revolutionizing farming in Northern Europe by the 10th century. (Thomas 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.) [97]

Asian rice was domesticated 8,200–13,500 years ago in China, with a single genetic origin from the wild rice Oryza rufipogon , [7] in the Pearl River valley region of China. Rice cultivation then spread to South and Southeast Asia. [98]

Ancient Greece and Hellenistic world

An ear of barley, symbol of wealth in the city of Metapontum in Magna Graecia (i.e. the Greek colonies of southern Italy), stamped stater, c. 530-510 BC Noe 082.jpg
An ear of barley, symbol of wealth in the city of Metapontum in Magna Graecia (i.e. the Greek colonies of southern Italy), stamped stater, c. 530–510 BC

The major cereal crops of the ancient Mediterranean region were wheat, emmer, and barley, while common vegetables included peas, beans, fava, and olives, dairy products came mostly from sheep and goats, and meat, which was consumed on rare occasion for most people, usually consisted of pork, beef, and lamb. [99] Agriculture in ancient Greece was hindered by the topography of mainland Greece that only allowed for roughly 10% of the land to be cultivated properly, necessitating the specialised exportation of oil and wine and importation of grains from Thrace (centered in what is now Bulgaria) and the Greek colonies of Pontic Greeks near the Black Sea. During the Hellenistic period, the Ptolemaic Empire controlled Egypt, Cyprus, Phoenicia, and Cyrenaica, major grain-producing regions that mainland Greeks depended on for subsistence, while the Ptolemaic grain market also played a critical role in the rise of the Roman Republic. In the Seleucid Empire, Mesopotamia was a crucial area for the production of wheat, while nomadic animal husbandry was also practiced in other parts. [100]

Roman Empire

Roman harvesting machine, a vallus, from a Roman wall in Belgium, which was then part of the province of Gallia Belgica Mahmaschine.jpg
Roman harvesting machine, a vallus, from a Roman wall in Belgium, which was then part of the province of Gallia Belgica

In the Greco-Roman world of Classical antiquity, Roman agriculture was built on techniques originally pioneered by the Sumerians, transmitted to them by subsequent cultures, with a specific emphasis on the cultivation of crops for trade and export. The 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 to 88 iugera (one iugerum is equal to about 0.65 acre). Medium-sized farms were from 80 to 500 iugera (singular iugerum). Large estates (called latifundia) were over 500 iugera. The Romans had four systems of farm management: direct work by the owner and his family; slaves doing work under the 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. [101]

The Americas

Agricultural history took a different path from the Old World as the Americas lacked large-seeded, easily domesticated grains (such as wheat and barley) and large domestic animals that could be used for agricultural labor. Rather than the practice which developed in the Old World of sowing a field with a single crop, pre-historic American agriculture usually consisted of cultivating many crops close to each other utilizing only hand labor. Moreover, agricultural areas in the Americas lacked the uniformity of the east–west area of Mediterranean and semi-arid climates in southern Europe and southwestern Asia, but instead had a north–south pattern with a variety of different climatic zones in close proximity to each other. This fostered the domestication of many different plants. [102]

At the time of first contact between the Europeans and the Americans, the Europeans practiced "extensive agriculture, based on the plough and draught animals," with tenants under landlords, but also forced labor or slavery, while the Indigenous peoples of the Americas practiced "intensive agriculture, based on human labour." [103] Europeans wanted control of land for the grazing of their livestock and property rights for the control of production. Though they were impressed with the productivity of traditional farming techniques, they saw no connection to their system and were dismissive of Native American practices as "gardening" rather than a commercializable enterprise. [103] [104] Due to several thousand years of selective breeding, maize, the hemisphere's most important crop, was more productive than Old World grain crops. Maize produced two and one-half times more calories per acre than wheat and barley. [105]

South America

Agriculture terraces were (and are) common in the austere, high-elevation environment of the Andes. Colca Canyon Puno.jpg
Agriculture terraces were (and are) common in the austere, high-elevation environment of the Andes.
Inca farmers using a human-powered foot plough Trabajo-inca8.jpg
Inca farmers using a human-powered foot plough

The earliest known areas of possible agriculture in the Americas dating to about 9000 BC are in Colombia, near present-day Pereira, and by the Las Vegas culture in Ecuador on the Santa Elena peninsula. The plants cultivated (or manipulated by humans) were lerén (Calathea allouia), arrowroot (Maranta arundinacea), squash (Cucurbita species), and bottle gourd (Lagenaria siceraria). All are plants of humid climates and their existence at this time on the semi-arid Santa Elena peninsula may be evidence that they were transplanted there from more humid environments. [106] [107] In another study, this area of South America was identified as one of the four oldest places of origin for agriculture, along with the Fertile Crescent, China, and Mesoamerica, dated between 6200 BC and 10000 BC. [108] (To facilitate comprehension by readers, Radiocarbon calibrated BP dates in the above sources have been converted to BC.)

In the Andes region, with civilizations including the Inca, the major crop was the potato, domesticated between 8000 and 5000 BC. [109] [110] [111] Coca, still a major crop to this day, was domesticated in the Andes, as were the peanut, tomato, tobacco, and pineapple. [72] Cotton was domesticated in Peru by 4200 BC. [112] [113] Animals were also domesticated, including llamas, alpacas, and guinea pigs. [114] The people of the Inca Empire of South America grew large surpluses of food which they stored in buildings called Qullqas. [115]

The most important crop domesticated in the Amazon Basin and tropical lowlands was probably cassava, (Manihot esculenta), which was domesticated before 7000 BCE, likely in the Rondônia and Mato Grosso states of Brazil. [116] The Guaitecas Archipelago in modern Chile was the southern limit of Pre-Hispanic agriculture near 44° South latitude, [117] as noted by the mention of the cultivation of Chiloé potatoes by a Spanish expedition in 1557. [118]

Mesoamerica

The creation of maize from teosinte (top), maize-teosinte hybrid (middle), to maize (bottom) Maize-teosinte.jpg
The creation of maize from teosinte (top), maize-teosinte hybrid (middle), to maize (bottom)

In Mesoamerica, wild teosinte was transformed through human selection into the ancestor of modern maize, about 7,000 BC. It gradually spread across North America and to South America and was the most important crop of Native Americans at the time of European exploration. [119] Other Mesoamerican crops include hundreds of varieties of locally domesticated squash and beans, while cocoa, also domesticated in the region, was a major crop. [72] The turkey, one of the most important poultry birds, was probably domesticated in Mexico or the U.S. Southwest. [120]

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. [121] [122]

North America

Wichita village of grass houses surrounded by maize fields in the United States. Wichita Indian village 1850-1875.jpg
Wichita village of grass houses surrounded by maize fields in the United States.

The indigenous people of the Eastern U.S. domesticated numerous crops. Sunflowers, tobacco, [123] varieties of squash and Chenopodium , as well as crops no longer grown, including marsh elder and little barley. [124] [125] Wild foods including wild rice and maple sugar were harvested. [126] The domesticated strawberry is a hybrid of a Chilean and a North American species, developed by breeding in Europe and North America. [127] Two major crops, pecans and Concord grapes, were used extensively in prehistoric times but do not appear to have been domesticated until the 19th century. [128] [129]

The indigenous people 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. [130] [131] [132] [133]

A system of companion planting called the Three Sisters was developed in North America. Three crops that complemented each other were planted together: winter squash, maize (corn), and climbing beans (typically tepary beans or common beans). The maize provides a structure for the beans to climb, eliminating the need for poles. The beans provide the nitrogen to the soil that the other plants use, and the squash spreads along the ground, blocking the sunlight, helping prevent the establishment of weeds. The squash leaves also act as a "living mulch". [134] [135]

Sub-Saharan Africa

Yam festival in the Ashanti Empire. Thomas E. Bowdich - 1817. Ashanti Yam Ceremony 1817.jpg
Yam festival in the Ashanti Empire. Thomas E. Bowdich – 1817.

In the Sahel region, civilizations such as the Mali and Songhai empires cultivated sorghum and pearl millet, which were domesticated between 3000 and 2500 BC. [69] [70] The donkey was domesticated in Nubia at approximately 5000 BC. [136] [137] Archaeological evidence suggests that Sanga cattle may have been independently domesticated in East Africa at around 1600 BC. [138]

In the tropical region of West Africa, crops such as black-eyed peas, Sea Island red peas, yams, kola nuts, Jollof rice and kokoro were domesticated between 3000 and 1000 BC. [71] The coastal region of West Africa is often referred to as the "Yam Belt", due to its high production of yams. [139] The guineafowl is a poultry bird that was domesticated in West Africa, and while the time of the guineafowl's domestication remains unclear, there is evidence that it was present in Ancient Greece during the 5th century BC. [140]

Several species of coffee were also domesticated throughout Sub-Saharan Africa, with Coffea arabica originating in Ethiopia and serving as the main production of modern-day coffee since the late 15th century. [141]

Oceania

Australia

Native millet, Panicum decompositum, was planted and harvested by Indigenous Australians in eastern central Australia. Panicum decompositum habitus.jpg
Native millet, Panicum decompositum , was planted and harvested by Indigenous Australians in eastern central Australia.

Indigenous Australians were predominately nomadic hunter-gatherers. Due to the policy of terra nullius , Aboriginals were regarded as not having been capable of sustained agriculture. However, the current consensus is that various agricultural methods were employed by the indigenous people. [24] [142] [25]

In two regions of Central Australia, the central west coast and eastern central Australia, forms of agriculture were 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 ( Marsilea drummondii ). [31] :281–304 [28]

Indigenous Australians used systematic burning, fire-stick farming, to enhance natural productivity. [143] 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. [144] The archaeologist Harry Lourandos suggested in the 1980s that there was evidence of 'intensification' in progress across Australia, [145] a process that appeared to have continued through the preceding 5,000 years. These concepts led the historian Bill Gammage to argue that in effect the whole continent was a managed landscape. [31]

Torres Strait Islanders are now known to have planted bananas. [25]

Pacific Islands

In New Guinea, archaeological evidence suggests that agriculture independently emerged around 7,000 years ago with the domestication of crops such as bananas and taro. Pigs and chickens were imported to New Guinea, which were later innovated by other Pacific Island nations, such as those in Polynesia. [146]

Middle Ages and Early Modern period

Europe

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. [147] 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. [148]

Agricultural calendar, c. 1470, from a manuscript of Pietro de Crescenzi Crescenzi calendar.jpg
Agricultural calendar, c. 1470, 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 heavy 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. [149] [150] At the same time, some 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. [151] Improved horse harnesses and the whippletree further improved cultivation. [152]

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. [153]

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. [154] Though the limitations of medieval farming were once thought to have provided a ceiling for the population growth in the Middle Ages, recent studies have shown that the technology of medieval agriculture was always sufficient for the needs of the people under normal circumstances, [155] [156] 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. [157] [158]

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. Water Wheel of Hama.jpg
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 to the 14th century, the Islamic world underwent a transformation in agricultural practice, described by the historian Andrew Watson as the Arab agricultural revolution. [159] 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. [159] 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 imported 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. [159] [160] [161]

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 in the Early Modern period. [162]

The Harvesters. Pieter Bruegel - 1565 Pieter Bruegel the Elder- The Harvesters - Google Art Project.jpg
The Harvesters . Pieter Bruegel – 1565

Maize and cassava were introduced from Brazil into Africa by Portuguese traders in the 16th century, [163] becoming staple foods, replacing native African crops. [164] 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. [165] 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. [166]

Modern agriculture

British agricultural revolution

The agriculturalist Charles 'Turnip' Townshend introduced four-field crop rotation and the cultivation of turnips. Charles Townshend, 2nd Viscount Townshend by Sir Godfrey Kneller, Bt (2).jpg
The agriculturalist Charles 'Turnip' Townshend introduced four-field crop rotation and the cultivation of turnips.

Between the 17th 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 19 US bushels (670 L; 150 US dry gal; 150 imp gal) per acre in 1720 to around 30 US bushels (1,100 L; 240 US dry gal; 230 imp gal) by 1840, marking a major turning point in history. [167]

Jethro Tull's seed drill, invented in 1701 Jethro Tull seed drill (1762).png
Jethro Tull's seed drill, invented in 1701

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. [168] 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. [169] 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 [170] to James Small's improved "Scots Plough" metal in 1763. In 1789 Ransomes, Sims & Jefferies was producing 86 plough models for different soils. [171] Powered farm machinery began with Richard Trevithick's stationary steam engine, used to drive a threshing machine, in 1812. [172] Mechanisation spread to additional farm uses throughout the 19th century. The first petrol-driven tractor was built in America by John Froelich in 1892. [173]

John Bennet Lawes began the scientific investigation of fertilization at the Rothamsted Experimental Station in 1843. 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. [174]

20th century

Early 20th-century image of a tractor ploughing an alfalfa field Agriculture (Plowing) CNE-v1-p58-H.jpg
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. [175] 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. [176]

Bt-toxins in genetically modified peanut leaves (bottom) protect from damage by corn borers (top). Bt plants.png
Bt-toxins in genetically modified peanut leaves (bottom) protect from damage by corn borers (top).

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. [178]

Collective farming was widely practiced in the Soviet Union, the Eastern Bloc countries, China, and Vietnam, starting in the 1930s in the Soviet Union; one result was the Soviet famine of 1932–33. [179] Another consequence occurred during the Great Leap Forward in China initiated by Mao Tse-tung that resulted in the Great Chinese Famine from 1959 to 1961 and ultimately reshaped the thinking of Deng Xiaoping.

In the past century agriculture has been characterized by increased productivity, the substitution of synthetic fertilizers and pesticides for labour, water pollution, [180] and farm subsidies. [181] Other applications of scientific research since 1950 in agriculture include gene manipulation, [182] [183] hydroponics, [184] and the development of economically viable biofuels such as ethanol. [185]

The number of people involved in farming in industrial countries fell radically from 24 percent of the American population to 1.5 percent in 2002. The number of farms also decreased, and their ownership became more concentrated; for example, between 1967 and 2002, one million pig farms in America consolidated into 114,000, with 80 percent of the production on factory farms. [186] According to the Worldwatch Institute, 74 percent of the world's poultry, 43 percent of beef, and 68 percent of eggs are produced this way. [186] [187]

Famines however continued to sweep the globe through the 20th century. Through the effects of climatic events, government policy, war and crop failure, millions of people died in each of at least ten famines between the 1920s and the 1990s. [188]

Green Revolution

Norman Borlaug, father of the Green Revolution of the 1970s, is credited with saving over a billion people worldwide from starvation. Norman Borlaug.jpg
Norman Borlaug, father of the Green Revolution of the 1970s, is credited with saving over a billion people worldwide from starvation.

The Green Revolution was a series of research, development, and technology transfer initiatives between the 1940s and the late 1970s. It increased agriculture production around the world, especially from 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. [189]

Synthetic nitrogen, mined rock phosphate, pesticides, and mechanization have greatly increased crop yields in the early 20th century. Increased supply of grains has also led to cheaper livestock. 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. Still, technologies such as the Green Revolution have allowed the world to produce a food surplus. [190]

Although the Green Revolution significantly increased rice yields in Asia, yield leveled off. 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". 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. [191]

An organic farmer, California, 1972 TONY OWEN ORGANIC FARM - NARA - 543017.jpg
An organic farmer, California, 1972

Organic agriculture

For most of its history, agriculture has been organic, without synthetic fertilisers or pesticides, and without GMOs. With the advent of chemical agriculture, Rudolf Steiner called for farming without synthetic pesticides, and his Agriculture Course of 1924 laid the foundation for biodynamic agriculture. [192] Lord Northbourne developed these ideas and presented his manifesto of organic farming in 1940. This became a worldwide movement, and organic farming is now practiced in many countries. [193]

See also

Related Research Articles

Agriculture encompasses crop and livestock production, aquaculture, and forestry for food and non-food products. Agriculture was a key factor in the rise of sedentary human civilization, whereby farming of domesticated species created food surpluses that enabled people to live in cities. While humans started gathering grains at least 105,000 years ago, nascent farmers only began planting them around 11,500 years ago. Sheep, goats, pigs, and cattle were domesticated around 10,000 years ago. Plants were independently cultivated in at least 11 regions of the world. In the 20th century, industrial agriculture based on large-scale monocultures came to dominate agricultural output.

<span class="mw-page-title-main">Neolithic</span> Archaeological period, last part of the Stone Age

The Neolithic or New Stone Age is an archaeological period, the final division of the Stone Age in Europe, Asia, Mesopotamia and Africa. It saw the Neolithic Revolution, a wide-ranging set of developments that appear to have arisen independently in several parts of the world. This "Neolithic package" included the introduction of farming, domestication of animals, and change from a hunter-gatherer lifestyle to one of settlement. The term 'Neolithic' was coined by Sir John Lubbock in 1865 as a refinement of the three-age system.

<span class="mw-page-title-main">Wheat</span> Genus of grass cultivated for grain

Wheat is a grass widely cultivated for its seed, a cereal grain that is a staple food around the world. The many species of wheat together make up the genus Triticum ; the most widely grown is common wheat. The archaeological record suggests that wheat was first cultivated in the regions of the Fertile Crescent around 9600 BC. Botanically, the wheat kernel is a caryopsis, a type of fruit.

<span class="mw-page-title-main">Rice</span> Cereal grain and staple food

Rice is a cereal grain and in its domesticated form is the staple food of over half of the world's population, particularly in Asia and Africa. Rice is the seed of the grass species Oryza sativa —or, much less commonly, Oryza glaberrima. Asian rice was domesticated in China some 13,500 to 8,200 years ago; African rice was domesticated in Africa about 3,000 years ago. Rice has become commonplace in many cultures worldwide; in 2021, 787 million tons were produced, placing it fourth after sugarcane, maize, and wheat. Only some 8% of rice is traded internationally. China, India, and Indonesia are the largest consumers of rice. A substantial amount of the rice produced in developing nations is lost after harvest through factors such as poor transport and storage. Rice yields can be reduced by pests including insects, rodents, and birds, as well as by weeds, and by diseases such as rice blast. Traditional rice polycultures such as rice-duck farming, and modern integrated pest management seek to control damage from pests in a sustainable way.

<span class="mw-page-title-main">Millet</span> Group of grasses (food grain)

Millets are a highly varied group of small-seeded grasses, widely grown around the world as cereal crops or grains for fodder and human food. Most millets belong to the tribe Paniceae.

<span class="mw-page-title-main">Einkorn wheat</span> Primitive wheat

Einkorn wheat can refer either to a wild species of wheat (Triticum) or to its domesticated form. The wild form is T. boeoticum, and the domesticated form is T. monococcum. Einkorn is a diploid species of hulled wheat, with tough glumes ('husks') that tightly enclose the grains. The cultivated form is similar to the wild, except that the ear stays intact when ripe and the seeds are larger. The domestic form is known as "petit épeautre" in French, "Einkorn" in German, "einkorn" or "littlespelt" in English, "piccolo farro" in Italian and "escanda menor" in Spanish. The name refers to the fact that each spikelet contains only one grain.

<span class="mw-page-title-main">Domestication</span> Selective breeding of plants and animals to serve humans

Domestication is a multi-generational mutualistic relationship in which an animal species, such as humans or leafcutter ants, takes over control and care of another species, such as sheep or fungi, to obtain from them a steady supply of resources, such as meat, milk, or labor. The process is gradual and geographically diffuse, based on trial and error. Domestication affected genes for behavior in animals, making them less aggressive. In plants, domestication affected genes for morphology, such as increasing seed size and stopping the shattering of cereal seedheads. Such changes both make domesticated organisms easier to handle and reduce their ability to survive in the wild.

<span class="mw-page-title-main">Animal husbandry</span> Management of farm animals

Animal husbandry is the branch of agriculture concerned with animals that are raised for meat, fibre, milk, or other products. It includes day-to-day care, management, production, nutrition, selective breeding, and the raising of livestock. Husbandry has a long history, starting with the Neolithic Revolution when animals were first domesticated, from around 13,000 BC onwards, predating farming of the first crops. During the period of ancient societies like ancient Egypt, cattle, sheep, goats, and pigs were being raised on farms.

<span class="mw-page-title-main">Columbian exchange</span> Transfers between the Old and New Worlds

The Columbian exchange, also known as the Columbian interchange, was the widespread transfer of plants, animals, and diseases between the New World in the Western Hemisphere, and the Old World (Afro-Eurasia) in the Eastern Hemisphere, in the late 15th and following centuries. It is named after the Italian explorer Christopher Columbus and is related to the European colonization and global trade following his 1492 voyage. Some of the exchanges were purposeful while others were unintended. Communicable diseases of Old World origin resulted in an 80 to 95 percent reduction in the number of Indigenous peoples of the Americas from the 15th century onwards, most severely in the Caribbean.

<span class="mw-page-title-main">Neolithic Revolution</span> Transition in human history from hunter-gatherer to settled peoples

The Neolithic Revolution, also known as the First Agricultural Revolution, was the wide-scale transition of many human cultures during the Neolithic period in Afro-Eurasia from a lifestyle of hunting and gathering to one of agriculture and settlement, making an increasingly large population possible. These settled communities permitted humans to observe and experiment with plants, learning how they grew and developed. This new knowledge led to the domestication of plants into crops.

<span class="mw-page-title-main">Founder crops</span> Original agricultural crops

The founder crops or primary domesticates are a group of flowering plants that were domesticated by early farming communities in Southwest Asia and went on to form the basis of agricultural economies across Eurasia. As originally defined by Daniel Zohary and Maria Hopf, they consisted of three cereals, four pulses, and flax. Subsequent research has indicated that many other species could be considered founder crops. These species were amongst the first domesticated plants in the world.

<span class="mw-page-title-main">New World crops</span> Crops native to the New World

New World crops are those crops, food and otherwise, that are native to the New World and were not found in the Old World before 1492 AD. Many of these crops are now grown around the world and have often become an integral part of the cuisine of various cultures in the Old World. Notable among them are the "Three Sisters": maize, winter squash, and climbing beans.

<span class="mw-page-title-main">Mixed farming</span> Economic activity

Mixed farming is a type of farming which involves both the growing of crops and the raising of livestock. Such agriculture occurs across Asia and in countries such as India, Malaysia, Indonesia, Afghanistan, South Africa, China, Central Europe, Nordic countries, Canada, and Russia. Though at first it mainly served domestic consumption, countries such as the United States and Japan now use it for commercial purposes.

<span class="mw-page-title-main">Vavilov center</span> Area where domestication traits arise

A Vavilov center or center of origin is a geographical area where a group of organisms, either domesticated or wild, first developed its distinctive properties. They are also considered centers of diversity. Centers of origin were first identified in 1924 by Nikolai Vavilov.

<span class="mw-page-title-main">History of agriculture in the Indian subcontinent</span>

The oldest evidence for Indian agriculture is in north-west India at the site of Mehrgarh, dated ca. 7000 BCE, with traces of the cultivation of plants and domestication of crops and animals. Indian subcontinent agriculture was the largest producer of wheat and grain. They settled life soon followed with implements and techniques being developed for agriculture. Double monsoons led to two harvests being reaped in one year. Indian products soon reached the world via existing trading networks and foreign crops were introduced to India. Plants and animals—considered essential to their survival by the Indians—came to be worshiped and venerated.

<span class="mw-page-title-main">History of the potato</span> Domestication, spread, and popular usage of the potato in history

The potato was the first domesticated vegetable in the region of modern-day southern Peru and extreme northwestern Bolivia between 8000 and 5000 BC. Cultivation of potatoes in South America may go back 10,000 years, but tubers do not preserve well in the archaeological record, making identification difficult. The earliest archaeologically verified potato tuber remains have been found at the coastal site of Ancón, dating to 2500 BC. Aside from actual remains, the potato is also found in the Peruvian archaeological record as a design influence of ceramic pottery, often in the shape of vessels. The potato has since spread around the world and has become a staple crop in most countries.

The means by which agriculture expanded into the Philippines is argued by many different anthropologists and an exact date of its origin is unknown. However, there are proxy indicators and other pieces of evidence that allow anthropologists to get an idea of when different crops reached the Philippines and how they may have gotten there. Rice is an important agricultural crop today in the Philippines and many countries throughout the world import rice and other products from the Philippines.

<span class="mw-page-title-main">History of rice cultivation</span>

The history of rice cultivation is an interdisciplinary subject that studies archaeological and documentary evidence to explain how rice was first domesticated and cultivated by humans, the spread of cultivation to different regions of the planet, and the technological changes that have impacted cultivation over time.

References

  1. 1 2 3 "The Development of Agriculture". National Geographic. 2022-07-08. Archived from the original on 2023-01-30. Retrieved 2023-01-30.
  2. 1 2 Mercader, J. (December 2009). "Mozambican grass seed consumption during the Middle Stone Age". Science. 326 (5960): 1680–1683. Bibcode:2009Sci...326.1680M. doi:10.1126/science.1173966. PMID   20019285. S2CID   44865552.
  3. Snir, Ainit (2015). "The Origin of Cultivation and Proto-Weeds, Long before Neolithic Farming". PLOS ONE. 10 (7): e0131422. Bibcode:2015PLoSO..1031422S. doi: 10.1371/journal.pone.0131422 . PMC   4511808 . PMID   26200895.
  4. Zeder, Melinda (October 2011). "The Origins of Agriculture in the Near East". Current Anthropology. 52 (S4): 221–235. doi:10.1086/659307. JSTOR   10.1086/659307. S2CID   8202907.
  5. Hirst, Kris (June 2019). "Domestication History of Rye". ThoughtCo. Retrieved 18 April 2020.
  6. Seabra, Luís; Teira-Brión, Andrés; López-Dóriga, Inés; Martín-Seijo, María; Almeida, Rubim; Tereso, João Pedro (10 May 2023). "The introduction and spread of rye (Secale cereale) in the Iberian Peninsula". PLOS ONE. 18 (5): e0284222. Bibcode:2023PLoSO..1884222S. doi: 10.1371/journal.pone.0284222 . PMC   10171662 . PMID   37163473.
  7. 1 2 3 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): 8351–6. Bibcode:2011PNAS..108.8351M. doi: 10.1073/pnas.1104686108 . PMC   3101000 . PMID   21536870.
  8. 1 2 Choi, Jae Young; Zaidem, Maricris; Gutaker, Rafal; Dorph, Katherine; Singh, Rakesh Kumar; Purugganan, Michael D. (2019-03-07). "The complex geography of domestication of the African rice Oryza glaberrima". PLOS Genetics. 15 (3): e1007414. doi: 10.1371/journal.pgen.1007414 . ISSN   1553-7404. PMC   6424484 . PMID   30845217.
  9. 1 2 Cubry, Philippe; Tranchant-Dubreuil, Christine; Thuillet, Anne-Céline; Monat, Cécile; Ndjiondjop, Marie-Noelle; Labadie, Karine; Cruaud, Corinne; Engelen, Stefan; Scarcelli, Nora; Rhoné, Bénédicte; Burgarella, Concetta (2018-07-23). "The Rise and Fall of African Rice Cultivation Revealed by Analysis of 246 New Genomes". Current Biology. 28 (14): 2274–2282.e6. Bibcode:2018CBio...28E2274C. doi: 10.1016/j.cub.2018.05.066 . ISSN   0960-9822. PMID   29983312. S2CID   51600014.
  10. Winchell, Frank; Brass, Michael; Manzo, Andrea; Beldados, Alemseged; Perna, Valentina; Murphy, Charlene; Stevens, Chris; Fuller, Dorian Q. (2018). "On the Origins and Dissemination of Domesticated Sorghum and Pearl Millet across Africa and into India: a View from the Butana Group of the Far Eastern Sahel". The African Archaeological Review. 35 (4): 483–505. doi:10.1007/s10437-018-9314-2. ISSN   0263-0338. PMC   6394749 . PMID   30880862.
  11. Manning, Katie; Pelling, Ruth; Higham, Tom; Schwenniger, Jean-Luc; Fuller, Dorian Q. (2011-02-01). "4500-Year old domesticated pearl millet (Pennisetum glaucum) from the Tilemsi Valley, Mali: new insights into an alternative cereal domestication pathway". Journal of Archaeological Science. 38 (2): 312–322. Bibcode:2011JArSc..38..312M. doi:10.1016/j.jas.2010.09.007. ISSN   0305-4403.
  12. Scarcelli, Nora; Cubry, Philippe; Akakpo, Roland; Thuillet, Anne-Céline; Obidiegwu, Jude; Baco, Mohamed N.; Otoo, Emmanuel; Sonké, Bonaventure; Dansi, Alexandre; Djedatin, Gustave; Mariac, Cédric (2019-05-03). "Yam genomics supports West Africa as a major cradle of crop domestication". Science Advances. 5 (5): eaaw1947. Bibcode:2019SciA....5.1947S. doi:10.1126/sciadv.aaw1947. ISSN   2375-2548. PMC   6527260 . PMID   31114806.
  13. Herniter, Ira A.; Muñoz-Amatriaín, María; Close, Timothy J. (December 2020). "Genetic, textual, and archeological evidence of the historical global spread of cowpea ( Vigna unguiculata [L.] Walp.)". Legume Science. 2 (4). doi: 10.1002/leg3.57 . ISSN   2639-6181. S2CID   220516241.
  14. Edward, Sue B. (1991), Hawkes, J. G.; Engels, J. M. M.; Worede, M. (eds.), "Crops with wild relatives found in Ethiopia", Plant Genetic Resources of Ethiopia, Cambridge: Cambridge University Press, pp. 42–74, ISBN   978-0-521-38456-8 , retrieved 2022-08-09
  15. "Finger Millet". Crop Wild Relatives. Retrieved 2022-08-09.
  16. "Plant studies show where Africa's early farmers tamed some of the continent's key crops". science.org. Retrieved 2022-08-09.
  17. "Why It's Difficult to Chart Banana History". ThoughtCo. Retrieved 2022-08-11.
  18. "Early Africans Went Bananas". science.org. Retrieved 2022-08-11.
  19. Shen, Quan-Kuan; Peng, Min-Sheng; Adeola, Adeniyi C; Kui, Ling; et al. (8 June 2021). "Genomic Analyses Unveil Helmeted Guinea Fowl ( Numida meleagris ) Domestication in West Africa". Genome Biology and Evolution. 13 (6). doi: 10.1093/gbe/evab090 . PMC   8214406 . PMID   34009300.
  20. Pitt, Daniel; Sevane, Natalia; Nicolazzi, Ezequiel L.; MacHugh, David E.; Park, Stephen D. E.; Colli, Licia; Martinez, Rodrigo; Bruford, Michael W.; Orozco-terWengel, Pablo (January 2019). "Domestication of cattle: Two or three events?". Evolutionary Applications. 12 (1): 123–136. Bibcode:2019EvApp..12..123P. doi:10.1111/eva.12674. ISSN   1752-4571. PMC   6304694 . PMID   30622640.
  21. Mwai, Okeyo; Hanotte, Olivier; Kwon, Young-Jun; Cho, Seoae (2015-06-11). "- Invited Review - African Indigenous Cattle: Unique Genetic Resources in a Rapidly Changing World". Asian-Australasian Journal of Animal Sciences. 28 (7): 911–921. doi:10.5713/ajas.15.0002R. ISSN   1011-2367. PMC   4478499 . PMID   26104394.
  22. World Cotton Production, Yara North America
  23. National Heritage Places – Budj Bim National Heritage Landscape". Australian Government. Dept of the Environment and Energy. 20 July 2004. Retrieved 30 January 2020. See also attached documents: National Heritage List Location and Boundary Map, and Government Gazette, 20 July 2004.
  24. 1 2 Gammage, Bill (October 2011). The Biggest Estate on Earth: How Aborigines made Australia. Allen & Unwin. pp. 281–304. ISBN   978-1-74237-748-3.
  25. 1 2 3 "Indigenous Australians 'farmed bananas 2,000 years ago'". BBC News. 12 August 2020.
  26. Stromberg, Joseph (February 2013). "Classical gas". Smithsonian. 43 (10): 18. Archived from the original on 15 October 2013. Retrieved 27 August 2013.
  27. 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
  28. 1 2 Gerritsen, R. (2008). Australia and the Origins of Agriculture. Archaeopress. pp. 29–30.
  29. "Climate". National Climate Data Center. Retrieved 1 December 2013.
  30. Gavashelishvili, A; et al. (2023), "The time and place of origin of South Caucasian languages: insights into past human societies, ecosystems and human population genetics", Scientific Reports, 13 (21133): 21133, Bibcode:2023NatSR..1321133G, doi:10.1038/s41598-023-45500-w, PMC   10689496 , PMID   38036582
  31. 1 2 3 Gammage, Bill (October 2011). The Biggest Estate on Earth: How Aborigines made Australia. Allen & Unwin. ISBN   978-1-74237-748-3.
  32. Douglas John McConnell (2003). The Forest Farms of Kandy: And Other Gardens of Complete Design. Ashgate. p. 1. ISBN   978-0-7546-0958-2.
  33. McConnell, Douglas John (1992). The forest-garden farms of Kandy, Sri Lanka. Food & Agriculture Org. p. 1. ISBN   978-92-5-102898-8.
  34. 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. Bibcode:2008PNAS..10513982A. doi: 10.1073/pnas.0803780105 . PMC   2544565 . PMID   18768818.
  35. 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): 6139–46. Bibcode:2014PNAS..111.6139L. doi: 10.1073/pnas.1323964111 . PMC   4035915 . PMID   24757054.
  36. Larson, Greger; Dobney, Keith; Albarella, Umberto; Fang, Meiying; Matisoo-Smith, Elizabeth; Robins, Judith; Lowden, Stewart; Finlayson, Heather; Brand, Tina (2005-03-11). "Worldwide Phylogeography of Wild Boar Reveals Multiple Centers of Pig Domestication". Science. 307 (5715): 1618–1621. Bibcode:2005Sci...307.1618L. doi:10.1126/science.1106927. PMID   15761152. S2CID   39923483.
  37. Larson, Greger; Albarella, Umberto; Dobney, Keith; Rowley-Conwy, Peter; Schibler, Jörg; Tresset, Anne; Vigne, Jean-Denis; Edwards, Ceiridwen J.; Schlumbaum, Angela (2007-09-25). "Ancient DNA, pig domestication, and the spread of the Neolithic into Europe". Proceedings of the National Academy of Sciences. 104 (39): 15276–15281. Bibcode:2007PNAS..10415276L. doi: 10.1073/pnas.0703411104 . PMC   1976408 . PMID   17855556.
  38. Ensminger, M.E.; Parker, R.O. (1986). Sheep and Goat Science (Fifth ed.). Interstate Printers and Publishers. ISBN   978-0-8134-2464-4.
  39. McTavish, E.J.; Decker, J.E.; Schnabel, R.D.; Taylor, J.F.; Hillis, D.M. (2013). "New World cattle show ancestry from multiple independent domestication events". PNAS. 110 (15): 1398–406. Bibcode:2013PNAS..110E1398M. doi: 10.1073/pnas.1303367110 . PMC   3625352 . PMID   23530234.
  40. Sapir-Hen, Lidar; Ben-Yosef, Erez (2013). "The Introduction of Domestic Camels to the Southern Levant: Evidence from the Aravah Valley" (PDF). Tel Aviv. 40 (2): 277–285. doi:10.1179/033443513x13753505864089. S2CID   44282748.
  41. Ladizinsky, G. (1998). Plant Evolution under Domestication. Kluwer. ISBN   978-0-412-82210-0.
  42. Kislev, M. E. (2006). "Early Domesticated Fig in the Jordan Valley". Science. 312 (5778): 1372–1374. Bibcode:2006Sci...312.1372K. doi:10.1126/science.1125910. PMID   16741119. S2CID   42150441.
  43. Lev-Yadun, S. (2006). "Comment on "Early Domesticated Fig in the Jordan Valley"". Science. 314 (5806): 1683a. Bibcode:2006Sci...314.1683L. doi: 10.1126/science.1132636 . PMID   17170278.
  44. Hillman, Gordon (1978). "On the Origins of Domestic rye: Secale Cereale: The Finds from Aceramic Can Hasan III in Turkey". Anatolian Studies. 28: 157–174. doi:10.2307/3642748. JSTOR   3642748. S2CID   85225244.  via  JSTOR (subscription required)
  45. Zohary, Daniel; Hopf, Maria; Weiss, Ehud (2012). Domestication of Plants in the Old World: The Origin and Spread of Domesticated Plants in Southwest Asia, Europe, and the Mediterranean Basin. Oxford: Oxford University Press. p. 62. ISBN   978-0-19-954906-1 via Google Books.
  46. Hillman, Gordon; Hedges, Robert; Moore, Andrew; Colledge, Susan; Pettitt, Paul (2001). "New evidence of Lateglacial cereal cultivation at Abu Hureyra on the Euphrates". The Holocene. 11 (4): 383–393. Bibcode:2001Holoc..11..383H. doi:10.1191/095968301678302823. S2CID   84930632.
  47. Colledge, Sue; Conolly, James (2010). "Reassessing the evidence for the cultivation of wild crops during the Younger Dryas at Tell Abu Hureyra, Syria". Environmental Archaeology. 15 (2): 124–138. Bibcode:2010EnvAr..15..124C. doi:10.1179/146141010X12640787648504. S2CID   129087203.
  48. Dolores, R.; Piperno, Anthony J.; Ranere, Irene Holst; Iriarte, Jose; Dickau, Ruth (2009). "Starch grain and phytolith evidence for early ninth millennium B.P. maize from the Central Balsas River Valley, Mexico". PNAS. 106 (13): 5019–5024. Bibcode:2009PNAS..106.5019P. doi: 10.1073/pnas.0812525106 . PMC   2664021 . PMID   19307570.
  49. Smith, A.F. (1994). The Tomato in America: Early History, Culture, and Cookery . University of South Carolina Press. p.  13. ISBN   978-1-57003-000-0.
  50. Denham, T.P. (2003). "Origins of Agriculture at Kuk Swamp in the Highlands of New Guinea" (PDF). Science. 301 (5630): 189–193. doi:10.1126/science.1085255. PMID   12817084. S2CID   10644185.
  51. Nelson, S.C.; Ploetz, R.C.; Kepler, A.K. (2006). "Musa species (bananas and plantains)" (PDF). In Elevitch, C.R. (ed.). Species Profiles for Pacific Island Agroforestry. Hōlualoa, Hawaiʻi: Permanent Agriculture Resources.
  52. Denham, T.P.; Haberle, S.G.; Lentfer, C.; Fullagar, R.; Field, J.; Therin, M.; Porch, N.; Winsborough, B. (2003). "Origins of Agriculture at Kuk Swamp in the Highlands of New Guinea" (PDF). Science. 301 (5630): 189–193. doi:10.1126/science.1085255. PMID   12817084. S2CID   10644185.
  53. Roffet-Salque, Mélanie; Regert, Martine; Evershed, Richard P.; et al. (2015). "Widespread exploitation of the honeybee by early Neolithic farmers". Nature. 527 (7577): 226–230. Bibcode:2015Natur.527..226R. doi:10.1038/nature15757. hdl: 10379/13692 . PMID   26560301. S2CID   205246432.
  54. "Southern Europe, 8000–2000 B.C. Timeline of Art History". The Metropolitan Museum of Art. Archived from the original on 26 January 2007. Retrieved 2011-07-16.
  55. "Ceide Fields Visitor Centre, Ballycastle, County Mayo, West of Ireland". Museums of Mayo. Archived from the original on 22 July 2011. Retrieved 16 July 2011.
  56. "The Céide Fields and North West Mayo Boglands". UNESCO World Heritage Centre. Archived from the original on Oct 17, 2011. Retrieved 16 July 2011.
  57. Anthony, David W. (2007). The Horse, the Wheel, and Language: How Bronze-Age Riders from the Eurasian Steppes Shaped the Modern World . Princeton University Press.
  58. 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.
  59. 1 2 He, Keyang; Lu, Houyuan; Zhang, Jianping; Wang, Can; Huan, Xiujia (7 June 2017). "Prehistoric evolution of the dualistic structure mixed rice and millet farming in China". The Holocene. 27 (12): 1885–1898. Bibcode:2017Holoc..27.1885H. doi:10.1177/0959683617708455. S2CID   133660098.
  60. Lu, H.; Zhang, J.; Liu, K.B.; Wu, N.; Li, Y.; Zhou, K.; Ye, M.; Zhang, T.; et al. (2009). "Earliest domestication of common millet (Panicum miliaceum) in East Asia extended to 10,000 years ago". Proceedings of the National Academy of Sciences of the United States of America. 106 (18): 7367–7372. Bibcode:2009PNAS..106.7367L. doi: 10.1073/pnas.0900158106 . PMC   2678631 . PMID   19383791.
  61. Chambers, Geoff (2013). "Genetics and the Origins of the Polynesians". eLS. John Wiley & Sons, Inc. doi:10.1002/9780470015902.a0020808.pub2. ISBN   978-0-470-01617-6.
  62. 1 2 Bellwood, Peter (9 December 2011). "The Checkered Prehistory of Rice Movement Southwards as a Domesticated Cereal—from the Yangzi to the Equator" (PDF). Rice. 4 (3–4): 93–103. Bibcode:2011Rice....4...93B. doi: 10.1007/s12284-011-9068-9 . S2CID   44675525.
  63. Hsieh, Jaw-shu; Hsing, Yue-ie Caroline; Hsu, Tze-fu; Li, Paul Jen-kuei; Li, Kuang-ti; Tsang, Cheng-hwa (24 December 2011). "Studies on Ancient Rice—Where Botanists, Agronomists, Archeologists, Linguists, and Ethnologists Meet". Rice. 4 (3–4): 178–183. Bibcode:2011Rice....4..178H. doi: 10.1007/s12284-011-9075-x .
  64. Gilboa, Ayelet; Namdar, Dvory (9 February 2016). "On the Beginnings of South Asian Spice Trade with the Mediterranean Region: A Review". Radiocarbon. 57 (2): 265–283. doi:10.2458/azu_rc.57.18562. S2CID   55719842.
  65. Zumbroich, Thomas J. (2007–2008). "The origin and diffusion of betel chewing: a synthesis of evidence from South Asia, Southeast Asia and beyond". eJournal of Indian Medicine. 1: 87–140.
  66. Mahdi, Waruno (1999). "The Dispersal of Austronesian boat forms in the Indian Ocean". In Blench, Roger; Spriggs, Matthew (eds.). Archaeology and Language III: Artefacts languages, and texts. One World Archaeology. Vol. 34. Routledge. pp. 144–179. ISBN   978-0-415-10054-0.
  67. Beaujard, Philippe (August 2011). "The first migrants to Madagascar and their introduction of plants: linguistic and ethnological evidence" (PDF). Azania: Archaeological Research in Africa. 46 (2): 169–189. doi:10.1080/0067270X.2011.580142. S2CID   55763047.
  68. Walter, Annie; Lebot, Vincent (2007). Gardens of Oceania. IRD Éditions-CIRAD. ISBN   978-1-86320-470-5.
  69. 1 2 Winchell, Frank (October 2017). "Evidence for Sorghum Domestication in Fourth Millennium BC Eastern Sudan: Spikelet Morphology from Ceramic Impressions of the Butana Group" (PDF). Current Anthropology. 58 (5): 673–683. doi:10.1086/693898. S2CID   149402650.
  70. 1 2 Manning, Katie (February 2011). "4500-Year old domesticated pearl millet (Pennisetum glaucum) from the Tilemsi Valley, Mali: new insights into an alternative cereal domestication pathway". Journal of Archaeological Science. 38 (2): 312–322. Bibcode:2011JArSc..38..312M. doi:10.1016/j.jas.2010.09.007 via Elsevier Science Direct.
  71. 1 2 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.
  72. 1 2 3 Murphy, Denis (2011). Plants, Biotechnology and Agriculture. CABI. pp. 153–. ISBN   978-1-84593-913-7.
  73. 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.
  74. Anderson, David; Goudie, Andrew; Parker, Adrian (2013). Global Environments Through the Quaternary: Exploring Environmental Change. Oxford University Press. p. 283. ISBN   978-0-19-969726-7.
  75. "Farming". British Museum. Archived from the original on 16 June 2016. Retrieved 15 June 2016.
  76. Tannahill, Reay (1968). The fine art of food. Folio Society.
  77. 1 2 Janick, Jules (2002). "Ancient Egyptian Agriculture and the Origins of Horticulture" (PDF). Acta Hort. 583 (582): 23–39. doi:10.17660/ActaHortic.2002.582.1.
  78. Kees, Herman (1961). Ancient Egypt: A Cultural Topography . University of Chicago Press. ISBN   978-0-226-42914-4.
  79. Jack, R. Harlan (2006-05-18). "Indigenous African Agriculture". The Origins of Agriculture: An International Perspective (New ed.). Tuscaloosa: University of Alabama Press. pp. 59–71. ISBN   0-8173-5349-6.
  80. 1 2 Gupta, Anil K (10 July 2004). "Origin of agriculture and domestication of plants and animals linked to early Holocene climate amelioration". Current Science. 87 (1). Indian Academy of Sciences: 58–59.
  81. Baber, Zaheer (1996). The Science of Empire: Scientific Knowledge, Civilization, and Colonial Rule in India. State University of New York Press. p. 19. ISBN   978-0-7914-2919-8.
  82. 1 2 3 Harris, David R.; Gosden, C. (1996). The Origins and Spread of Agriculture and Pastoralism in Eurasia: Crops, Fields, Flocks And Herds. Routledge. p. 385. ISBN   978-1-85728-538-3.
  83. Wright, Rita P (2009). The Ancient Indus: Urbanism, Economy, and Society. Cambridge University Press. pp. 44, 51. ISBN   978-0-521-57652-9.
  84. Possehl, Gregory L. (1996). Mehrgarh in Oxford Companion to Archaeology, edited by Brian Fagan. Oxford University Press.
  85. Stein, Burton (1998). A History of India. Blackwell Publishing. 47. ISBN   0-631-20546-2.
  86. 1 2 Rodda & Ubertini (2004). The Basis of Civilization – Water Science?. International Association of Hydrological Science. p. 279. ISBN   978-1-901502-57-2.
  87. Lal, R. (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]. Bibcode:2001STilR..61....3L. doi:10.1016/S0167-1987(01)00184-2.
  88. Needham, Joseph (1986). Science and Civilization in China: Volume 6, Part 2. Taipei: Caves Books Ltd. pp. 55–56.
  89. 1 2 Needham, Volume 6, Part 2, 56.
  90. Needham, Volume 6, Part 2, 57.
  91. Needham, Joseph (1986). Science and Civilization in China: Volume 4, Physics and Physical Technology, Part 2, Mechanical Engineering. Taipei: Caves Books, Ltd. p. 184
  92. Needham, Volume 4, Part 2, 89, 110.
  93. Needham, Volume 4, Part 2, 33.
  94. Needham, Volume 4, Part 2, 110.
  95. Robert Greenberger, The Technology of Ancient China, Rosen Publishing Group, 2006, pp. 11–12.
  96. Wang Zhongshu, trans. by K.C. Chang and Collaborators, Han Civilization (New Haven and London: Yale University Press, 1982).
  97. 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   978-0-415-96930-7.
  98. 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 . PMC   7518720 . PMID   23034647.
  99. Koester, Helmut (1995), History, Culture, and Religion of the Hellenistic Age, 2nd edition, New York: Walter de Gruyter, ISBN   3-11-014693-2, pp. 76–77.
  100. Helmut Koester (1995), History, Culture, and Religion of the Hellenistic Age, 2nd edition, New York: Walter de Gruyter, ISBN   3-11-014693-2, p. 77.
  101. White, K. D. (1970), Roman Farming (Cornell University Press)
  102. Diamond, Jared (1999). Guns, Germs, and Steel (Paperback ed.). New York: W.W. Norton. pp. 123–128, 134–142. ISBN   0-393-31755-2.
  103. 1 2 Sempat Assadourian, Carlos (1992). "The Colonial Economy; The Transfer of the European System of Production to New Spain and Peru". Journal of Latin American Studies. 24 (Quincentenary Supplement): 62. JSTOR   156945.
  104. Hill, Christina Gish (24 November 2020). "Returning Corn, Beans, and Squash to Native American Farms". JSTOR Daily. JSTOR. Retrieved 9 July 2021.
  105. Ensminger, Marion Eugene; Ensminger, Audrey H. (1994). Food & Nutrition Encyclopedia. London: CRC-Press. p. 1104.
  106. Zarrillo, S.; Pearsall, D. M.; Tisdale, M. A.; Quon, D. J. (2008). "Directly dated starch residues document early formative maize (Zea mays L.) in tropical Ecuador". Proceedings of the National Academy of Sciences of the United States of America. 105 (13): 5006–5011. Bibcode:2008PNAS..105.5006Z. doi: 10.1073/pnas.0800894105 . PMC   2278185 . PMID   18362336.
  107. Piperno, Dolores R. (2011). "The Origin of Plant Cultivation and Domestication in the New World Tropics: Pattern, Process, and New Developments". Current Anthropology. 52 (S-4): S453–S470. doi:10.1086/659998. S2CID   83061925.
  108. Larson, Gregor (29 April 2014). "Current Perspectives and the Future of Domestication Studies". Proceedings of the National Academy of Sciences. 111 (17): 6139–6146. Bibcode:2014PNAS..111.6139L. doi: 10.1073/pnas.1323964111 . PMC   4035915 . PMID   24757054.
  109. 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): 14694–14699. Bibcode:2005PNAS..10214694S. doi: 10.1073/pnas.0507400102 . PMC   1253605 . PMID   16203994.
  110. Office of International Affairs (1989). Lost Crops of the Incas: Little-Known Plants of the Andes with Promise for Worldwide Cultivation. p. 92. doi:10.17226/1398. ISBN   978-0-309-04264-2 via nap.edu.
  111. John Michael Francis (2005). Iberia and the Americas. ABC-CLIO. ISBN   978-1-85109-426-4.
  112. Rajpal, Vijay Rani (2016). Gene Pool Diversity and Crop Improvement, Volume 1. Springer. p. 117. ISBN   978-3-319-27096-8 . Retrieved 9 April 2016.
  113. 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.
  114. 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.
  115. Mumford, Jeremy Ravi (2012). Vertical Empire. Durham, NC: Duke University Press. pp. 15, 27. ISBN   978-0-8223-5310-2.
  116. Isendahl, Christian (December 2011). "The Domestication and Early Spread of Manioc". Latin American Antiquity. 22 (4): 464. doi:10.7183/1045-6635.22.4.452. JSTOR   23072569. S2CID   161372308.
  117. Bird, Junius (1946). "The Alacaluf". In Steward, Julian H. (ed.). Handbook of South American Indians. Bulletin 143. Vol. I. –Bureau of American Ethnology. pp. 55–79.
  118. Contreras, Andrés; Ciampi, Luigi; Padulosi, Stefano; Spooner, David M. (1993). "Potato germplasm collecting expedition to the Guaitecas and Chonos Archipelagos, Chile, 1990". Potato Research . 36 (4): 309–316. doi:10.1007/BF02361797. S2CID   6759459. Archived from the original on 2020-08-01. Retrieved 2019-01-11.
  119. Johannessen, S.; Hastorf, C.A. (eds.). Corn and Culture in the Prehistoric New World. Westview Press.
  120. Speller, Camilla F.; et al. (2010). "Ancient mitochondrial DNA analysis reveals complexity of indigenous North American turkey domestication". PNAS. 107 (7): 2807–2812. Bibcode:2010PNAS..107.2807S. doi: 10.1073/pnas.0909724107 . PMC   2840336 . PMID   20133614.
  121. Mascarelli, Amanda (5 November 2010). "Mayans converted wetlands to farmland". Nature. doi:10.1038/news.2010.587.
  122. Morgan, John (2012-11-06). "Invisible Artifacts: Uncovering Secrets of Ancient Maya Agriculture with Modern Soil Science" (pdf). Soil Horizons. 53 (6). Madison, Illinois: Soil Science Society of America: 3–6. doi: 10.2136/sh2012-53-6-lf (inactive 2024-11-01). ISSN   2163-2812. OCLC   8561599813. Archived from the original on 2020-07-28.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  123. Heiser, Carl B. Jr. (1992). "On possible sources of the tobacco of prehistoric Eastern North America". Current Anthropology. 33: 54–56. doi:10.1086/204032. S2CID   144433864.
  124. Prehistoric Food Production in North America, edited by Richard I. Ford. Museum of Anthropology, University of Michigan, Anthropological Papers 75.
  125. Adair, Mary J. (1988) Prehistoric Agriculture in the Central Plains. Publications in Anthropology 16. University of Kansas, Lawrence.
  126. Smith, Andrew (2013). The Oxford Encyclopedia of Food and Drink in America. OUP US. pp. 1–. ISBN   978-0-19-973496-2.
  127. Hardigan, Michael A. "P0653: Domestication History of Strawberry: Population Bottlenecks and Restructuring of Genetic Diversity through Time". Pland & Animal Genome Conference XXVI January 13–17, 2018 San Diego, California. Retrieved 28 February 2018.
  128. "Pecans at Texas A&M University". Pecankernel.tamu.edu. 2006-08-18. Archived from the original on 2010-05-25. Retrieved 2010-06-03.
  129. The History of Concord Grapes, http://www.concordgrape.org/bodyhistory.html
  130. Sugihara, Neil G.; Jan W. Van Wagtendonk; Shaffer, Kevin E.; Fites-Kaufman, Joann; Thode, Andrea E., eds. (2006). "17". Fire in California's Ecosystems. University of California Press. p. 417. ISBN   978-0-520-24605-8.
  131. Blackburn, Thomas C. and Kat Anderson, ed. (1993). Before the Wilderness: Environmental Management by Native Californians. Ballena Press. ISBN   978-0-87919-126-9.
  132. Cunningham, Laura (2010). State of Change: Forgotten Landscapes of California. Heyday. pp. 135, 173–202. ISBN   978-1-59714-136-9.
  133. Anderson, M. Kat (2006). Tending the Wild: Native American Knowledge And the Management of California's Natural Resources . University of California Press. ISBN   978-0-520-24851-9.
  134. Wilson, Gilbert (1917). Agriculture of the Hidatsa Indians: An Indian Interpretation. Dodo Press. pp. 25 and passim. ISBN   978-1-4099-4233-7. Archived from the original on 14 March 2016.
  135. Landon, Amanda J. (2008). "The "How" of the Three Sisters: The Origins of Agriculture in Mesoamerica and the Human Niche". Nebraska Anthropologist. University of Nebraska-Lincoln: 110–124.
  136. Beja-Pereira, Albano; et al. (18 June 2004). "African Origins of the Domestic Donkey". Science. 304 (1781): 1781. doi:10.1126/science.1096008. PMID   15205528. S2CID   12783335.
  137. Roger Blench, "The history and spread of donkeys in Africa" (PDF). (235 KB)
  138. Grigson, Caroline (1991). "An African origin for African cattle? — some archaeological evidence". The African Archaeological Review. 9 (1): 119–144. doi:10.1007/BF01117218. S2CID   162307756.
  139. "Celebrating Nigeria's yummy yams". BBC News. 2010-09-22. Retrieved 2023-11-15.
  140. Blench, Roger; MacDonald, Kevin C. (1999). The Origins and Development of African Livestock. London: UCL. p. 10. ISBN   978-1-84142-018-9.
  141. Weinberg, Bennett Alan; Bealer, Bonnie K. (2001). The World of Caffeine: The Science and Culture of the World's Most Popular Drug. Psychology Press. pp. 3–4. ISBN   978-0-415-92723-9.
  142. Dark Emu
  143. Jones, R. (1969). "Fire-stick Farming". Australian Natural History. 16: 224.
  144. Williams, E. (1988) Complex Hunter-Gatherers: A Late Holocene Example from Temperate Australia. British Archaeological Reports, Oxford
  145. Lourandos, H. (1997) Continent of Hunter-Gatherers: New Perspectives in Australian Prehistory Cambridge University Press, Cambridge
  146. Bourke, R. Michael (2009), "History of agriculture in Papua New Guinea", in Bourke, R. Michael; Harwood, Tracy (eds.), Food and Agriculture in Papua New Guinea, Australian National University Press, pp. 10–26, ISBN   978-1-921536-60-1, JSTOR   j.ctt24h987.12
  147. Jourdan, Pablo. "Medieval Horticulture/Agriculture". Ohio State University. Archived from the original on 14 April 2013. Retrieved 24 April 2013.
  148. Janick, Jules (2008). "Islamic Influences on Western Agriculture" (PDF). Purdue University. Retrieved 2013-05-23.
  149. White, Lynn (1967). "The Life of the Silent Majority". In Hoyt, Robert S. (ed.). Life and Thought in the Early Middle Ages. University of Minnesota Press. p. 88.
  150. Andersen, Thomas Barnebeck; Jensen, Peter Sandholt; Skovsgaard, Christian Volmar (December 2014). "The Heavy Plough and the Agricultural Revolution in Medieval Europe" (PDF). European Historical Economics Society. Archived from the original (PDF) on 2016-08-18. Retrieved 2017-04-05.
  151. Fox, H.S.A. (November 1986). "The Alleged Transformation from Two-Field to Three-Field Systems in Medieval England". The Economic History Review. 39 (4): 526–548. doi:10.1111/j.1468-0289.1986.tb01255.x. JSTOR   2596482.
  152. White, Lynn Townsend (1978). Medieval Religion and Technology: Collected Essays . University of California Press. p.  143. ISBN   978-0-520-03566-9.
  153. Newman, Paul B. (2001). Daily Life in the Middle Ages. McFarland. pp. 88–89. ISBN   978-0-7864-5052-7.
  154. 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.
  155. Campbell, Bruce M.S. (2000). English Seigniorial Agriculture, 1250–1450. Cambridge University Press. ISBN   978-0-521-30412-2.
  156. Stone, David (2005). Decision-Making in Medieval Agriculture. Oxford University Press. ISBN   978-0-19-924776-9.
  157. Langdon, John (2010). Bjork, Robert E. (ed.). The Oxford Dictionary of the Middle Ages. Oxford University Press. pp. 20–23. ISBN   978-0-19-866262-4.
  158. Jordan, William Chester (1997). The Great Famine: Northern Europe in the Early Fourteenth Century. Princeton University Press. ISBN   978-1-4008-2213-3.
  159. 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. S2CID   154359726.
  160. Watson, Andrew M. (1983). Agricultural Innovation in the Early Islamic World. Cambridge University Press. ISBN   978-0-521-24711-5.
  161. Food Journeys of a Lifetime. National Geographic Society. 2015. pp. 126–. ISBN   978-1-4262-1609-1.
  162. Crosby, Alfred. "The Columbian Exchange". The Gilder Lehrman Institute of American History. Retrieved 11 May 2013.
  163. Wagner, Holly. "Super-Sized Cassava Plants May Help Fight Hunger In Africa". The Ohio State University. Archived from the original on 2013-12-08. Retrieved 11 May 2013.
  164. Wambugu, Florence; Wafula, John, eds. (2000). "Advances in Maize Streak Virus Disease Research in Eastern and Southern Africa". International Service for the Acquisition of Agri-Biotech Applications. Retrieved 16 April 2013.
  165. Chapman, Jeff (2000). "The Impact of the Potato". History Magazine (2). Archived from the original on 11 May 2000.
  166. Mann, Charles C. "How the Potato Changed History". Smithsonian (November 2011). Archived from the original on 2013-11-02. Retrieved 2013-11-28. Adapted from 1493: Uncovering the New World Columbus Created, by Charles C. Mann.
  167. Snell, K.D.M. (1985). Annals of the Labouring Poor, Social Change and Agrarian England 1660–1900. Cambridge University Press. ISBN   978-0-521-24548-7. Chapter 4
  168. Thirsk, Joan (2004). "Blith, Walter (bap. 1605, d. 1654)" . Oxford Dictionary of National Biography (online ed.). Oxford University Press. doi:10.1093/ref:odnb/2655 . Retrieved 2 September 2011.(Subscription or UK public library membership required.)
  169. Harskamp, Jaap (2009). "The Low Countries and the English Agricultural Revolution". Gastronomica. 9 (3): 32–41. doi:10.1525/gfc.2009.9.3.32. JSTOR   10.1525/gfc.2009.9.3.32.
  170. Payne, F.G. "The British Plough: Some Stages in its Development" (PDF). British Agricultural History Society. Retrieved 5 April 2017.
  171. Barlow, Robert Stockes (2003). 300 Years of Farm Implements and Machinery 1630–1930. Krause Publications. p. 33. ISBN   978-0-87349-632-2.
  172. Hodge, James (1973). Richard Trevithick. Shire Publications. p. 30. ISBN   978-0-85263-177-5.
  173. Macmillan, Don; Broehl, Wayne G. The John Deere Tractor Legacy. Voyageur Press. p. 45. ISBN   978-1-61060-529-8.
  174. "The Coprolite Industry". Cambridgeshire History. Archived from the original on 4 April 2016. Retrieved 5 April 2017.
  175. Janick, Jules. "Agricultural Scientific Revolution: Mechanical" (PDF). Purdue University. Retrieved 24 May 2013.
  176. Reid, John F. (2011). "The Impact of Mechanization on Agriculture". The Bridge on Agriculture and Information Technology. 41 (3).
  177. Suszkiw, Jan (November 1999). "Tifton, Georgia: A Peanut Pest Showdown". Agricultural Research magazine. Retrieved 23 November 2008.
  178. "A Historical Perspective". International Fertilizer Industry Association. Archived from the original on 9 March 2012. Retrieved 7 May 2013.
  179. Iordachi, Constantin; Bauerkamper, Arnd (2014). The Collectivization of Agriculture in Communist Eastern Europe: Comparison and Entanglements. Central European University Press. p. 9. ISBN   978-615-5225-63-5.
  180. Moss, Brian (2008). "Water Pollution by Agriculture". Phil. Trans. R. Soc. Lond. B. 363 (1491): 659–666. doi:10.1098/rstb.2007.2176. PMC   2610176 . PMID   17666391.
  181. "Title 05 – Agriculture and rural development". Archived from the original on 4 December 2013. Retrieved 16 June 2016.
  182. 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.
  183. Weasel, Lisa H. 2009. Food Fray. Amacom Publishing
  184. Douglas, James S., Hydroponics, 5th ed. Oxford University Press, 1975. 1–3
  185. "Towards Sustainable Production and Use of Resources: Assessing Biofuels" (PDF). United Nations Environment Programme. 16 October 2009. Archived from the original (PDF) on 22 November 2009. Retrieved 24 October 2009.
  186. 1 2 Scully, Matthew (2002). Dominion: The Power of Man, the Suffering of Animals, and the Call to Mercy. Macmillan. pp. 26, 29. ISBN   978-0-312-31973-1.
  187. "State of the World 2006". Worldwatch Institute. 2006.
  188. "Ten worst famines of the 20th century". Sydney Morning Herald. 15 August 2011.
  189. Hazell, Peter B.R. (2009). The Asian Green Revolution. IFPRI Discussion Paper. International Food Policy Research Institute. GGKEY:HS2UT4LADZD.
  190. Barrionuevo, Alexei; Bradsher, Keith (8 December 2005). "Sometimes a Bumper Crop Is Too Much of a Good Thing". The New York Times .
  191. Tilman, D.; Cassman, K.G.; Matson, P.A.; Naylor, R.; Polasky, S. (August 2002). "Agricultural sustainability and intensive production practices" (PDF). Nature. 418 (6898): 671–677. Bibcode:2002Natur.418..671T. doi:10.1038/nature01014. PMID   12167873. S2CID   3016610. Archived from the original (PDF) on 2011-07-16. Retrieved 2013-11-28.
  192. Paull, John (2011). "Attending the First Organic Agriculture Course: Rudolf Steiner's Agriculture Course at Koberwitz, 1924" (PDF). European Journal of Social Sciences. 21 (1): 64–70.
  193. Paull, John (2014). "Lord Northbourne, the man who invented organic farming, a biography" (PDF). Journal of Organic Systems. 9 (1): 31–53.

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