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Thursday, February 3, 2022

Agricultural biodiversity

From Wikipedia, the free encyclopedia
 
Unusual strains of maize are examples of crop diversity and can be used as the basis for breeding new varieties.

Agricultural biodiversity is a sub-set of general biodiversity. Otherwise known as agrobiodiversity, agricultural biodiversity is a broad term that includes "the variety and variability of animals, plants and micro-organisms at the genetic, species and ecosystem levels that sustain the ecosystem structures, functions and processes in and around production systems, and that provide food and non-food agricultural products.” managed by farmers, pastoralists, fishers and forest dwellers, agrobiodiversity provides stability, adaptability and resilience and constitutes a key element of the livelihood strategies of rural communities throughout the world. Agrobiodiversity is central to sustainable food systems and sustainable diets. The use of agricultural biodiversity can contribute to food security, nutrition security, and livelihood security, and it is critical for climate adaptation and climate mitigation.

History of the term

It is not clear when exactly the term agrobiodiversity was coined nor by whom. The 1990 annual report of the International Board for Plant Genetic Resources (IBPGR, now Bioversity International) is one of the earliest references to biodiversity in the context of agriculture. Most references to agricultural biodiversity date from the late 1990s onwards.

While similar, different definitions are used by different bodies to describe biodiversity in connection with food production. CGIAR tends to use agricultural biodiversity or agrobiodiversity, while the Food and Agriculture Organization of the UN (FAO) uses 'biodiversity for food and agriculture' and the Convention on Biological Diversity (CBD) uses the term 'agricultural diversity'. The CBD more or less (but not entirely) excludes marine aquatic organisms and forestry in its usage because they have their own groups and international frameworks for discussion of international policies and actions. Decision V/5 of the CBD provides the framing description.

Levels of agrobiodiversity

Genetic diversity

Diversity of quinoa (Chenopodium quinoa) near harvest, with quinoa farmer, in Cachilaya, Bolivia, Province La Paz

Genetic diversity refers to the variety and variability within and between species. It can refer to the naturally occurring genetic variability within and between populations of a species, for example wild relatives of food crops, or to the variability created by humans, for example farmer-developed traditional crop varieties called landraces, or commercially bred varieties of a crop (e.g. different apple varieties: Fuji, Golden Delicious, Golden Pippin, etc.). There is considerable genetic diversity within all food crop species, particularly in centres of origin, which are the geographical areas where species were originally developed. For example, the Andean region of Peru is a centre of origin for certain tuber species, and over 1,483 varieties of these species can be found there. Genetic diversity is important as different genes give rise to important traits, such as nutrient composition, hardiness to different environments, resistance to pests, or ample harvests. Genetic diversity is decreasing due to agricultural modernization, changing land use and climate change, among other factors. (It is even possible that breeding narrowly for the pest- and disease-resistance necessary to deal with climate change will, itself, reduce agrobiodiversity.) Genetic diversity is not static but is constantly evolving in response to changes in the environment and according to human intervention, whether farmers or breeders.

Neglected and underutilized crop species in Benin

Species diversity

Species diversity refers to the number and abundance of different species used for food and agriculture. The number of species considered to contribute to food alone ranges from 5,538 to 75,000 depending on definitions. A conservative estimate is that about 6,000 species are commonly used for food. Species diversity includes "the domesticated plants and animals that are part of crop, livestock, forest or aquaculture systems, harvested forest and aquatic species, the wild relatives of domesticated species, and other wild species harvested for food and other products. It also encompasses what is known as “associated biodiversity”, the vast range of organisms that live in and around food and agricultural production systems, sustaining them and contributing to their output." Agriculture is understood to include crop and livestock production, forestry, fisheries and aquaculture.

Aquatic diversity is an important component of agricultural biodiversity. The conservation and sustainable use of local aquatic ecosystems, ponds, rivers, coastal commons by artisanal fisherfolk and smallholder farmers is important to the survival of both humans and the environment. Since aquatic organisms, including fish, provide much of our food supply as well as underpinning the income of coastal peoples, it is critical that fisherfolk and smallholder farmers have genetic reserves and sustainable ecosystems to draw upon as aquaculture and marine fisheries management continue to evolve.

Ecosystem diversity

Rice terraces in Munduk. The mosaic of ecosystem components provides various ecosystem services

Ecosystem diversity refers to the variety and variability of different components in a given geographical area (e.g. landscape, country). In the context of agrobiodiversity ecosystem diversity refers to the diversity within and between agroecosystems: e.g. pastures, ponds and rivers, planted fields, hedges, trees and so on. Landscape-level biodiversity has received less research attention than the other levels of biodiversity.

Contributions of agrobiodiversity to food and agriculture

Introduction

Contributions from agrobiodiversity to food and agriculture are usually categorized by their contribution to ecosystem services. Ecosystem services are the services provided by well functioning ecosystems (agroecosystems and also wild ecosystems such as forests or grasslands) to human wellbeing. They are usually clustered into four broader categories: provisioning (direct provision of goods such as food and water), supporting (the services that are needed for agriculture to be healthy, such as soil), regulating (regulating natural processes needed in agriculture such as pollination, carbon capture or pest control), or cultural (recreational, aesthetic and spiritual benefits).

Provisioning

Agrobiodiversity's contribution to provisioning services is mainly for providing food and nutrition. Food biodiversity is "the diversity of plants, animals and other organisms used for food, covering the genetic resources within species, between species and provided by ecosystems." Historically at least 6,000 plant species and numerous animal species have been used as human food. This number is considered to be decreasing now, resulting in concerns about long-term diet diversity. Food biodiversity also covers subspecies or varieties of crops, for example the many forms of the Brassica oleracea species (cauliflowers, different broccolis, cabbages, Brussel sprouts, etc.). Many species which have been overlooked by mainstream research ('orphan' or 'neglected and underutilized' species) are rich in micronutrients and other healthful components. Also among different varieties of a species, there can be a wide variety of nutrient composition; for example some sweet potato varieties contain negligible levels of beta-carotene, which others can contain up to 23,100 mcg per 100g of raw, peeled sweet potatoes. Other provisioning services from agrobiodiversity are the provision of wood, fibre, fuel, water and medicinal resources. Sustainable food security is linked to improving the conservation, sustainable use and enhancement of the diversity of all genetic resources for food and agriculture, especially plant and animal genetic resources, in all types of production systems.

Supporting

Wild onion blossoms (Allium)

Agrobiodiversity's contribution to supporting services is providing the biological or life support to production, emphasising conservation, sustainable use and enhancement of the biological resources that support sustainable production systems. The main service is to maintain genetic diversity of crops and species, so that it is available to maintain adaptability to new and changing climate and weather conditions. Genetic diversity is the basis of crop and livestock improvement programmes, which breed new varieties of crops and livestock in response to consumer demand and farmers' needs. An important source of genetic diversity are crop wild relatives, wild plant species that are genetically related to cultivated crops. A second supporting service is to maintain the habitat of wild biodiversity, particularly associated biodiversity, for example pollinators and predators. Agrobiodiversity can support wild biodiversity through the use of field margins, riparian corridors, hedgerows and clumps of trees, which provide and connect habitats. A further supporting service is maintaining healthy soil biota.

Regulating

Agrobiodiversity makes several contributions to regulating services, which control the natural processes needed for a healthy agroecosystem. Pollination, pest control and carbon capture are examples.

Pollination

A larva of a ladybird, devouring aphids. Chimoio, Mozambique

75% of the 115 major crop species grown globally rely on pollinators. Agrobiodiversity contributes to the health of pollinators by: (a) providing habitat for them to live and breed; (b) providing non-chemical biological options for pest control (see below) so that insecticide use can be reduced, and insect pollinators not damaged; (c) providing a symbiotic relationship of constant flower production, with crops flowering at different times, so that the pollinators have constant access to nectar-producing flowers.

Pest control

Agrobiodiversity contributes to pest control by: (a) providing a habitat for pests' natural enemies to live and breed in; (b) providing wide genetic diversity which means it is more likely that genes contain resistance to any given pathogen or pest, and also that the plant can evolve as pests and diseases evolve. Genetic diversity also means that some crops grow earlier or later, or in wetter or drier conditions, so the crop might avoid attacks from the pest or pathogen.

Carbon capture

Agrobiodiversity contributes to carbon capture if used as part of a package of agroecological practices, for example by providing cover crops which can be dug into the land as green manure; maintaining tree stands and hedgerows; and protecting the integrity of soils so that they continue to house local microbes. Farmers and breeders can use genetic diversity to breed varieties which are more tolerant to changing climate conditions, and which, combined with practices like conservation agriculture, can increase sequestration in soils and biomass, and reduce emissions by avoiding the degrading of farmlands. Using agroforestry, the inclusion of trees and shrubs as an integral part of a farming system, can also successfully sequester carbon.

Cultural

Celebrating Chhath puja with traditional fruit species

Agrobiodiversity is central to cultural ecosystem services in the form of food biodiversity, which is central to local cuisines worldwide. Agrobiodiversity provides locally appreciated crops and species, and also unique varieties which have cultural significance. For example, ethnic traditional cultures influence the conservation of a wide diversity of rice varieties in China (e.g. red rice, sweet glutinous rices) developed by farmers over thousands of years and used in traditional cultures, rituals and customs. Another example are local food fairs, epitomized by the Slow Food movement, which celebrates local food varieties in order to add value to them, raise awareness about them and ultimately conserve and use them. In addition, some traditional cultures use agrobiodiversity in cultural rituals, e.g. many populations of fruit species (pomelo and mango) are maintained in rural communities specifically for use at the 'Chhath Puja' festival, celebrated in parts of India, Nepal and Mauritius. Home gardens are important as culturally constructed spaces where agrobiodiversity is conserved for a wide variety of social, aesthetic and cultural reasons. Genetic diversity is maintained by resource-poor farmers because of many non-monetary values, including culture and food.

Loss of agrobiodiversity

Agrobiodiversity is threatened by changing patterns of land use (urbanization, deforestation), agricultural modernization (monocultures and abandoning of traditional, biodiversity-based practices); Westernization of diets and their supply chains. It has been estimated that biodiversity as a whole is being lost at 100–1000 times the natural background rate. This extends also to agricultural biodiversity and loss of genetic diversity from farmers' fields and the wild.

Agrobiodiversity loss leads to genetic erosion, the loss of genetic diversity, including the loss of individual genes, and the loss of particular combinations of genes (or gene complexes) such as those manifested in locally adapted landraces or breeds. Genetic vulnerability occurs when there is little genetic diversity within a population of plants. This lack of diversity makes the population as a whole particularly vulnerable to disease, pests, or other factors. The problem of genetic vulnerability often arises with modern crop varieties, which are uniform by design. An example of the consequences of genetic vulnerability occurred in 1970 when corn blight struck the US corn belt, destroying 15% of the harvest. A particular plant cell characteristic known as Texas male sterile cytoplasm conferred vulnerability to the blight - a subsequent study by the National Academy of Sciences found that 90% of American maize plants carried this trait.

Reduced agrobiodiversity influences, and is influenced by, changes in human diets. Since the mid-1900s, human diets across the world have become more diverse in the consumption of major commodity staple crops, with a corollary decline in consumption of local or regionally important crops, and thus have become more homogeneous globally. The differences between the foods eaten in different countries decreased by 68% between 1961 and 2009. The modern 'global standard' diet contains an increasingly large percentage of a relatively small number of major staple commodity crops, which have increased substantially in the share of the total food energy (calories), protein, fat, and food weight that they provide to the world's human population, including wheat, rice, sugar, maize, soybean (by +284%), palm oil (by +173%), and sunflower (by +246%). Whereas nations used to consume greater proportions of locally or regionally important food biodiversity, wheat has become a staple in over 97% of countries, with the other global staples showing similar dominance worldwide. Other crops have declined sharply over the same period, including rye, yam, sweet potato (by -45%), cassava (by -38%), coconut, sorghum (by -52%) and millets (by -45%).

Conservation

Attempts to conserve or safeguard agrobiodiversity usually focus on species or genetic level of agrobiodiversity. Conservation of genetic diversity and species diversity can be carried out ex situ, which means removing the materials from their growing site and looking after them elsewhere, or in situ, which means that they are conserved in their natural or cultivated site. While these two approaches are sometimes pitted against each other as either/or, both have merits. Conservation practitioners recommend integrating both methods, according to the purpose of conservation, threats, uniqueness of diversity, etc.

Ex situ conservation

ex situ conservation at a genebank at the International Center for Tropical Agriculture (CIAT), Colombia

Ex situ conservation is defined as the “conservation of components of biological diversity outside their natural habitats.” Ex situ conservation is the conservation of genetic resources (species, varieties, cultivars, sub-species, landraces etc.) for food and agriculture outside their natural habitat, in a managed environment including: botanical gardens, seedbanks, pollenbanks, field genebanks, cryobank or herbaria. Ex situ conservation is considered a relatively reliable way of maintaining genetic diversity, since it is usually preserved over the longer term  and is less prone to change. The diversity of much of the world's major crops has been extensively collected and conserved in genebanks. Over 7 million samples are conserved in 1,750 genebanks worldwide. Collections are safety-duplicated as an insurance in case of damage to one genebank. In addition, most globally important collections of annual or seed-bearing crops have a backup in the Svalbard global seed vault.

Ex situ conservation offers some advantages for seed-bearing crops: 1) Seed requires little space; 2) Ex situ conservation can be implemented anywhere; 3) There is easy access to what is conserved for distribution, further use, research  and breeding; 4) Costs for maintaining genetic diversity that has no immediate production or market value are minimum.

Weaknesses of ex situ conservation include: 1) it is costly to maintain seeds and germplasm healthily in perpetual storage, or in field collections; 2) Coverage of the diversity of neglected and underutilized crops or crop wild relatives is currently very limited. Genebanks have largely focused on the conservation of major staple crops while non-staple crops and crop wild relatives are poorly represented; 3) There are species with ‘recalcitrant’ seeds, which means they cannot be stored long term; 4) Specialized infrastructure and staff are needed.

In situ conservation

In situ conservation means "the conservation of ecosystems and natural habitats and the maintenance and recovery of viable populations of species in their natural surroundings and, in the case of domesticated or cultivated species, in the surroundings where they have developed their distinctive properties". In situ conservation comprises both conservation of trees and crop wild relatives in situ in the wild, and conservation of landraces and neglected and underutilized species on farm in farmers' fields. Conserving agrobiodiversity in situ has the benefit that species can continue to evolve in response to natural and human pressures. In the case of crops, a large amount of diversity is retained in developing countries by smallholder farmers, particularly for many crops in their centers of domestication and diversity. There, farmers continue to grow landraces and maintain traditional knowledge and seed management practices in a process known as de facto conservation. Home gardens too are repositories of high levels of species diversity, and traditional landraces contain wide genetic diversity. For forest trees, in situ conservation is considered the most appropriate method since most tree seeds cannot be conserved ex situ, and because there are 60,000 tree species, each with multiple populations, so too many to identify and collect.

Having limited access to synthetic inputs, resource-poor farmers' fields are often organic by default. A meta-analysis of studies comparing biodiversity noted that, when compared to organic cropping systems, conventional systems had significantly lower species richness and abundance (30% greater richness and 50% greater abundance in organic systems, on average), though 16% of studies did find a greater level of species richness in conventional systems.

In situ conservation is relatively low cost for high levels of biodiversity, particularly crop wild relatives, neglected and underutilized species, landraces, trees, fish and livestock. However, species and varieties conserved in situ can be vulnerable to climate changes, land use changes and market demand.

Ecosystem level conservation

Ecosystem level conservation looks at landscape level, with landscapes managed by the group of stakeholders working together to achieve biodiversity, production and livelihood goals. Land use mosaics combine

  1. ‘natural’ areas
  2. agricultural production areas
  3. institutional mechanisms to coordinate initiatives to achieve production, conservation and livelihood objectives at landscape, farm and community scales, by exploiting synergies and managing trade-offs among them.

There are limited initiatives that focus on conserving entire landscapes or agro-ecosystems. One is 'Globally Important Agricultural Heritage Systems' (GIAHS), which are conserved and maintained as unique systems of agriculture, in order to sustainably provide multiple goods and services, food and livelihood security for millions of small-scale farmers.

Prehistoric Europe

Tarxien Temples, Malta, around 3150 BC

Prehistoric Europe is Europe with human presence but before the start of recorded history, beginning in the Lower Paleolithic. As history progresses, considerable regional irregularities of cultural development emerge and increase. The region of the eastern Mediterranean is, due to its geographic proximity, greatly influenced and inspired by the classical Middle Eastern civilizations, and adopts and develops the earliest systems of communal organization and writing. The Histories of Herodotus (from around 440 BC) is the oldest known European text that seeks to systematically record traditions, public affairs and notable events. In contrast, the European regions furthest away from the ancient centers of civilization tended to be the slowest, regarding acculturation. In Northern and Eastern Europe in particular, writing and systematic recording was only introduced in the context of Christianization, after 1000 A.D.

Overview

Widely dispersed, isolated finds of individual fossils of bone fragments (Atapuerca, Mauer mandible), stone artifacts or assemblages that suggest that during Lower Paleolithic, spanning from 3 million until 300,000 years ago, palaeo-human presence are rare and typically separated by thousands of years. The karstic region of the Atapuerca Mountains in Spain represents the currently earliest known and reliably dated location of residence for more than a single generation and a group of individuals. Prolonged presence has been attested for Homo antecessor (or Homo erectus antecessor, Homo heidelbergensis, and Neanderthals).

Homo neanderthalensis emerged in Eurasia between 350,000 and 600,000 years ago as the earliest body of European people, that left behind a substantial tradition, a set of evaluable historic data through rich fossil record in Europe's limestone caves and a patchwork of occupation sites over large areas, including Mousterian cultural assemblages. Modern humans arrived in Mediterranean Europe during the Upper Paleolithic between 45,000 and 43,000 years ago, and both species occupied a common habitat for several thousand years. Research has so far produced no universally accepted conclusive explanation as to what caused the Neanderthal's extinction between 40,000 and 28,000 years ago.

Homo sapiens subsequently proceeded to populate the entire continent during the Mesolithic and advanced north, following the retreating ice sheets of the last glacial maximum that spanned between 26,500 and 19,000 years ago. A 2015 publication on ancient European DNA collected from Spain to Russia concluded that the original hunter-gatherer population had assimilated a wave of "farmers" who had arrived from the Near East during the Neolithic about 8,000 years ago.

The Mesolithic era site Lepenski Vir in modern-day Serbia, the earliest documented sedentary community of Europe with permanent buildings as well as monumental art precedes sites previously considered to be the oldest known by many centuries. The community's year round access to a food surplus prior to the introduction of agriculture was the basis for the sedentary lifestyle. However, the earliest record for the adoption of elements of farming can be found in Starčevo, a community with close cultural ties.

Belovode and Pločnik, also in Serbia, is currently the oldest reliably dated copper smelting site in Europe (around 7,000 years ago). Attributed to the Vinča culture, which on the contrary provides no links to the initiation of or a transition to the Chalcolithic or Copper Age.

The process of smelting bronze is an imported technology with debated origins and history of geographic cultural profusion. It established in Europe about 3200 BC in the Aegean and production was centered around Cyprus, the primary source of copper for the Mediterranean for many centuries.

The introduction of metallurgy which initiated unprecedented technological progress has also been linked with the establishment of social stratification and distinction between rich and poor and precious metals as the means to fundamentally control the dynamics of culture and society.

The European Iron Age culture also originates in the East through the absorption of the technological principles obtained from the Hittites about 1200 BC, finally arriving in Northern Europe by 500 BC.

During the Iron Age, Central, Western and most of Eastern Europe gradually entered the historical period. Greek maritime colonization and Roman terrestrial conquest form the basis for the diffusion of literacy in large areas to this day. This tradition continued in an altered form and context for the most remote regions (Greenland and Old Prussians, 13th century) via the universal body of Christian texts, including the incorporation of East Slavic peoples and Russia into the Orthodox cultural sphere. Latin and ancient Greek language continued to be the primary and best way to communicate and express ideas in Liberal arts education and the sciences all over Europe until the early modern period.

Early prehistory

Paleolithic

Oldest fossils, artifacts and sites

Name Abstract Age Location Information Coordinates
Dmanisi skull 5 Homo erectus 1.77 Mio Dmanisi "early Homo adult with small brains but large body mass" 41°19′N 44°12′E
Lézignan-la-Cèbe Lithic Assemblage 1.57 Mio Lézignan-la-Cébe a 30 pebble culture, lithic tools, argon dated 43°29′N 3°26′E
Kozarnika limestone cave 1.5 Mio Kozarnika
43°39′N 22°42′E
Orce fossil cranial fragment 1.3 Mio Venta Micena most finds are stone tools 37°43′N 2°28′W
Pleistocene mandibel Homo antecessor 1.3 Mio Atapuerca Mountains
42°22′N 3°30′W
Mauer 1 Homo heidelbergensis 600,000 Mauer earliest Homo heidelbergensis 49°20′N 8°47′E
Boxgrove Man Homo heidelbergensis 500,000 Boxgrove
50°51′N 0°42′W
Tautavel Man Homo erectus 450,000 Tautavel proposed subspecies 42°48′N 2°45′E
Swanscombe Man Homo heidelbergensis 400,000 Swanscombe north-western habitat maximum 51°26′N 0°17′E
Schöningen Spears wooden javelins 380,000 Schoningen 1995 active hunt 42°48′N 2°45′E

Lower and Middle Paleolithic human presence

Acheulean hand axes and hand axe-like implements, flint, 800,000–300,000 BC

The climatic record of the Paleolithic is characterised by the Pleistocene pattern of cyclic warmer and colder periods, including eight major cycles and numerous shorter episodes. The northern maximum of human occupation fluctuated in response to the changing conditions, and successful settlement required constant adaption capabilities and problem solving. Most of Scandinavia, the North European Plain and Russia remained off limits for occupation during the Paleolithic and Mesolithic.

Associated evidence, such as stone tools, artifacts and settlement localities, is more numerous than fossilised remains of the hominin occupants themselves. The simplest pebble tools with a few flakes struck off to create an edge were found in Dmanisi, Georgia, and in Spain at sites in the Guadix-Baza basin and near Atapuerca. The Oldowan tool discoveries, called Mode 1-type assemblages are gradually replaced by a more complex tradition that included a range of hand axes and flake tools, the Acheulean, Mode 2-type assemblages. Both types of tool sets are attributed to Homo erectus, the earliest and for a very long time the only human in Europe and more likely to be found in the southern part of the continent. However, the Acheulean fossil record also links to the emergence of Homo heidelbergensis, particularly its specific lithic tools and handaxes. The presence of Homo heidelbergensis is documented since 600,000 BC in numerous sites in Germany, Great Britain and northern France.

Although palaeoanthropologists generally agree that Homo erectus and Homo heidelbergensis immigrated to Europe, debates remain about migration routes and the chronology.

The fact that Homo neanderthalensis is found only in a contiguous range of presence in Eurasia and the general acceptance of the Out of Africa hypothesis both suggest that the species has evolved locally. Again, consensus prevails on the matter, but widely debated are origin and evolution patterns. Neanderthal fossil record ranges from Western Europe to the Altai Mountains in Central Asia and the Ural Mountains in the North to the Levant in the South. Unlike its predecessors, they were biologically and culturally adapted to survival in cold environments and successfully extended their range to the glacial environments of Central Europe and the Russian plains. The great number and, in some cases, exceptional state of preservation of Neanderthal fossils and cultural assemblages enables researchers to provide a detailed and accurate data on behaviour and culture. Neanderthals are associated with the Mousterian culture (Mode 3), stone tools that first appeared approximately 160,000 years ago.

Upper Paleolithic

Aurignacian cave paintings, Chauvet Cave

Homo sapiens arrived in Europe around 45,000 and 43,000 years ago via the Levant and entered the continent through the Danubian corridor, as the fossils at Peștera cu Oase suggest. The fossils' genetic structure indicates a recent Neanderthal ancestry and the discovery of a fragment of a skull in Israel in 2008 support the notion that humans interbred with Neanderthals in the Levant.

After the slow processes of the previous hundreds of thousands of years a turbulent period of Neanderthal–Homo sapiens coexistence demonstrated that cultural evolution had replaced biological evolution as the primary force of adaptation and change in human societies.

Generally-small and widely dispersed fossil sites suggest that Neanderthals lived in less numerous and moresocially-isolated groups than Homo sapiens. Tools and Levallois points are remarkably sophisticated from the outset, but they have a slow rate of variability, and general technological inertia is noticeable during the entire fossil period. Artifacts are of utilitarian nature, and symbolic behavioral traits are undocumented before the arrival of modern humans. The Aurignacian culture, introduced by modern humans is characterized by cut bone or antler points, fine flint blades and bladelets struck from prepared cores, rather than using crude flakes. The oldest examples and subsequent widespread tradition of prehistoric art originate from the Aurignacian.

Venus of Moravany, found in Slovakia, dated to 22,800 BC

After more than 100,000 years of uniformity, around 45,000 years ago, the Neanderthal fossil record changed abruptly. The Mousterian had quickly become more versatile and was named the Chatelperronian culture, which signifies the diffusion of Aurignacian elements into Neanderthal culture. Although debated, the fact proved that Neanderthals had, to some extent, adopted the culture of modern Homo sapiens. However, the Neanderthal fossil record completely vanished after 40,000 years BC. Whether Neanderthals were also successful in diffusing their genetic heritage into Europe's future population or they simply went extinct and, if so, what caused the extinction cannot conclusively be answered.

Around 32,000 years ago, the Gravettian culture appeared in the Crimean Mountains (southern Ukraine). By 24,000 BC, the Solutrean and Gravettian cultures were present in the Aouthwestern Europe. Gravettian technology and culture have been theorised to have come with migrations of people from the Middle East, Anatolia and the Balkans and might be linked with the transitional cultures mentioned earlier since their techniques have some similarities and are both very different from Aurignacian ones but this issue is very obscure. The Gravettian also appeared in the Caucasus and Zagros Mountains but soon disappeared from southwestern Europe, with the notable exception of the Mediterranean coasts of Iberia.

The Solutrean culture, extended from northern Spain to southeastern France, includes not only a beautiful stone technology but also the first significant development of cave painting and the use of the needle and possibly that of the bow and arrow. The more widespread Gravettian culture is no less advanced, at least in artistic terms: sculpture (mainly venuses) is the most outstanding form of creative expression of such peoples.

Around 19,000 BC, Europe witnesses the appearance of a new culture, known as Magdalenian, possibly rooted in the old Aurignacian one, and soon supersedes the Solutrean area and also the Gravettian of Central Europe. However, in Mediterranean Iberia, Italy, the Balkans and Turkey, epi-Gravettian cultures continued to evolve locally.

With the Magdalenian culture, the Paleolithic development in Europe reaches its peak and this is reflected in art, owing to previous traditions of paintings and sculpture.

Map showing hypothetical extent of Doggerland, from the Weichselian glaciation until the current situation.

Around 12,500 BC, the Würm Glacial Age ended. Slowly, through the following millennia, temperatures and sea levels rose, changing the environment of prehistoric people. Ireland and Great Britain become islands, and Scandinavia became separated from the main part of the European Peninsula. (They had all once been connected by a now-submerged region of the continental shelf known as Doggerland.) Nevertheless, the Magdalenian culture persisted until 10,000 BC, when it quickly evolved into two microlith cultures: Azilian, in Spain and southern France, and Sauveterrian, in northern France and Central Europe. Despite some differences, both cultures shared several traits: the creation of very small stone tools called microliths and the scarcity of figurative art, which seems to have vanished almost completely, which was replaced by abstract decoration of tools.

In the late phase of the epi-Paleolithic period, the Sauveterrean culture evolved into the so-called Tardenoisian and strongly influenced its southern neighbour, clearly replacing it in Mediterranean Spain and Portugal. The recession of the glaciers allowed human colonisation in Northern Europe for the first time. The Maglemosian culture, derived from the Sauveterre-Tardenois culture but with a strong personality, colonised Denmark and the nearby regions, including parts of Britain.

Mesolithic

Two skeletons of women aged between 25 and 35 years, dated between 6740 and 5680 BC, both died a violent death and were found at Téviec, France, in 1938.
 
Lepenski Vir culture, 7000 BC, Cobblestone (red sandstone)

A transition period in the development of human technology between the Paleolithic and the Neolithic, the Balkan Mesolithic began around 15,000 years ago. In Western Europe, the Early Mesolithic, or Azilian, began about 14,000 years ago, in the Franco-Cantabrian region of northern Spain and southern France. In other parts of Europe, the Mesolithic began by 11,500 years ago (the beginning Holocene) and ended with the introduction of farming, which, depending on the region, occurred 8,500 to 5,500 years ago.

In areas with limited glacial impact, the term "Epipaleolithic" is sometimes preferred for the period. Regions that experienced greater environmental effects as the Last Glacial Period ended had a much more apparent Mesolithic era that lasted millennia. In Northern Europe, societies were able to live well on rich food supplies from the marshlands, which had been created by the warmer climate. Such conditions produced distinctive human behaviours that are preserved in the material record, such as the Maglemosian and Azilian cultures. Such conditions delayed the coming of the Neolithic to as late as 5,500 years ago in Northern Europe.

As what Vere Gordon Childe termed the "Neolithic Package" (including agriculture, herding, polished stone axes, timber longhouses and pottery) spread into Europe, the Mesolithic way of life was marginalised and eventually disappeared. Controversy over the means of that dispersal is discussed below in the Neolithic section. A "Ceramic Mesolithic" can be distinguished between 7,200 and 5,850 years ago and ranged from Southern to Northern Europe.

Neolithic

chronology of agriculture introduction in Europe
 

The European Neolithic is assumed to have arrived from the Near East via Asia Minor, the Mediterranean and the Caucasus. There has been a long discussion between migrationists, who claim that the Near Eastern farmers almost totally displaced the European native hunter-gatherers, and diffusionists, who claim that the process was slow enough to have occurred mostly through cultural transmission. A relationship has been suggested between the spread of agriculture and the diffusion of Indo-European languages, with several models of migrations trying to establish a relationship, like the Anatolian hypothesis, which sets the origin of Indo-European agricultural terminology in Anatolia.

Early Neolithic

Apparently related with the Anatolian culture of Hacilar, the Greek region of Thessalia was the first place in Europe known to have acquired agriculture, cattle-herding and pottery. The early stages are known as pre-Sesklo culture. The Thessalian Neolithic culture soon evolved into the more coherent culture of Sesklo (8000 BC), which was the origin of the main branches of Neolithic expansion in Europe. Practically all of the Balkan Peninsula was colonized in the 6th millennium from there. The expansion, reaching the easternmost Tardenoisian outposts of the upper Tisza, gave birth to the Proto-Linear Pottery culture, a significant modification of the Balkan Neolithic that was the origin of one of the most important branches of European Neolithic: the Danubian group of cultures. In parallel, the coasts of the Adriatic and of southern Italy witnessed the expansion of another Neolithic current with less clear origins. Settling initially in Dalmatia, the bearers of the Cardium pottery culture may have come from Thessalia (some of the pre-Sesklo settlements show related traits) or even from Lebanon (Byblos). They were sailors, fishermen and sheep and goat herders, and the archaeological findings show that they mixed with natives in most places. Other early Neolithic cultures can be found in Ukraine and Southern Russia, where the epi-Gravettian locals assimilated cultural influxes from beyond the Caucasus (culture of Dniepr-Don and related) and in Andalusia (Spain), where the rare Neolithic of La Almagra Pottery appeared without known origins very early (c. 7800 BC).

Middle Neolithic

Europe ca. 6500–6000 BC

This phase, starting 7000 years ago was marked by the consolidation of the Neolithic expansion towards western and northern Europe but also by the rise of a new culture that probably violently occupied most of the Balkans, substituting or subjugating the first Neolithic settlers. That is the culture of Dimini (Thessalia) and the related ones of Vinca-Turdas (Serbia and Romania) and Karanovo III-Veselinovo (Bulgaria and nearby areas), the last one more hybrid than the other two. Meanwhile, the tiny Proto-Linear Pottery culture gave birth to two very dynamic branches: the Western and Eastern Linear Pottery Cultures. The latter one is basically an extension of the Balkan Neolithic, but the more original western branch expanded quickly, assimilating Germany, the Czech Republic, Poland and even large parts of western Ukraine, historical Moldavia, the lowlands of Romania, and regions of France, Belgium and the Netherlands, all in less than 1000 years. With expansion comes diversification and a number of local Danubian cultures start forming at the end of the 5th millennium. In the Mediterranean, the Cardium pottery fishermen showed no less dynamism and colonised or assimilated all of Italy and the Mediterranean regions of France and Spain. Even in the Atlantic, some groups among the native hunter-gatherers started the slow incorporation of the new technologies. Among them, the most noticeable regions seem to be southwestern Iberia, which was influenced by the Mediterranean but especially by the Andalusian Neolithic, which soon developed the first Megalithic burials (dolmens) and the area around Denmark (Ertebölle culture), influenced by the Danubian complex.

Late Neolithic

Neolithic bone hammer, Stone Age museum, Landau, Germany

This period occupies the first half of the 6th millennium BC and is rather quiet. The tendencies of the previous period consolidated and so there was a fully-formed Neolithic Europe, with five main cultural regions:

  1. Danubian cultures: from northern France to western Ukraine. Now split into several local cultures, the most relevant ones being the Romanian branch (Boian culture) that expanded into Bulgaria, the culture of Rössen that was pre-eminent in the west, and the Lengyel culture of Austria and western Hungary, which would have a major role in later periods.
  2. Mediterranean cultures: from the Adriatic to eastern Spain, including Italy and large portions of France and Switzerland. They were also diversified into several groups.
  3. The area of Dimini-Vinca: Thessalia, Macedonia and Serbia but extending its influence to parts of the mid-Danubian basin (Tisza, Slavonia) and southern Italy.
  4. Eastern Europe: basically central and eastern Ukraine and parts of southern Russia and Belarus (Dniepr-Don culture). Apparently, they were the first to domesticate horses though some Paleolithic evidence could disprove it.
  5. Atlantic Europe: a mosaic of local cultures, some of them still pre-Neolithic, from Portugal to southern Sweden. In around 5800 BC, western France began to incorporate the Megalithic style of burial.

There were also a few independent areas, including Andalusia, southern Greece and the western coasts of the Black Sea (Hamangia culture).

Chalcolithic

Diffusion of copper metallurgy in Europe.
 
grave platelet with deer from the castle New home of Saint Peter
 
silo shaped ossuary, Dagon Museum, Downtown, Haifa, Israel
 
battle axe (Streitaxe) or boat axe of Swedish-Norwegian type (Corded Ware culture), 2800-2400 BC
 
Double spiral pin, c. 5000 BC
 
Reconstruction of Ötzi's copper axe.

Also known as "Copper Age", the European Chalcolithic was a time of changes and confusion. The most relevant fact was the infiltration and the invasion of large parts of the territory by people originating from Central Asia, which is considered by mainstream scholars to be the original Indo-Europeans, but there are again several theories in dispute. Other phenomena are the expansion of Megalithism, the appearance of the first significant economic stratification and the related first known monarchies in the Balkan region.

The economy of the Chalcolithic, even in the regions in which copper is not used yet, was no longer that of peasant communities and tribes: since some materials began to produced in specific locations and distributed to wide regions. Mining of metal and stone was particularly developed in some areas, along with the processing of those materials into valuable goods.

Ancient Chalcolithic

From 5500 to 5000 BC, copper started to be used in the Balkans, and Eastern and Central Europe. However, the key factor could be the use of horses, which would increase mobility. From 5500 BC onwards, Eastern Europe was apparently infiltrated by people originating from beyond the Volga (Yamna culture), creating a plural complex known as Sredny Stog culture, which substituted the previous Dnieper-Donets culture, pushing the natives to migrate northwest to the Baltic and to Denmark, where they mixed with the natives (TRBK A and C). That may be correlated with the linguistic fact of the spread of Indo-European languages, according to the Kurgan hypothesis. Near the end of the period, another branch left many traces in the lower Danube area (culture of Cernavodă I) in what seems to be another invasion.

Meanwhile, the Danubian Lengyel culture absorbs its northern neighbours in the Czech Republic and Poland for some centuries, only to recede in the second half of the period. In Bulgaria and Wallachia (southern Romania), the culture of Boian-Marica evolvef into a monarchy with a clearly-royal cemetery near the coast of the Black Sea. The model seems to have been copied later in the Tiszan region with the culture of Bodrogkeresztur. Labour specialisation, economic stratification and possibly the risk of invasion may have been the reasons behind that development. The influx of early Troy (Troy I) was clear in both the expansion of metallurgy and social organization.

In the western Danubian region (the Rhine and Seine basins), the Michelsberg culture displaced its predecessor, the Rössen culture. Meanwhile, in the Mediterranean basin, several cultures (most notably Chassey in southeastern France and La Lagozza in northern Italy) converged into a functional union of which the most significant characteristic was the distribution network of honey-coloured silex. Despite the unity, the signs of conflicts are clear, as many skeletons show violent injuries. It is the time and area of Ötzi, the famous man found in the Alps. Another significant development of the period is that the Megalithic phenomenon started to spread to most of the Atlantic region, bringing agriculture to some underdeveloped regions there.

Middle Chalcolithic

This period extends along the first half of the 3rd millennium BC. Most significant was the reorganisation of the Danubians in the powerful Baden culture, which extended more or less to Austria-Hungary. The rest of the Balkans was profoundly restructured after the invasions of the previous period, but, with the exception of the Coțofeni culture, in a mountainous region, they show no eastern (or presumably Indo-European) traits. The new Ezero culture, in Bulgaria, shows the first traits of pseudo-bronze (an alloy of copper with arsenic), as does the first significant Aegean group, the Cycladic culture after 2800 BC.

The supposedly Indo-European groups seem to recede temporarily in Northern Europe and suffered a strong cultural Danubianisation. In East Europe, the peoples beyond the Volga (Yamna culture), surely Indo-Europeans who were ancestors of the Iranian Scythians, took over southern Russia and Ukraine. In the Western world, the only sign of unity came from the Megalithic super-culture, which extended from southern Sweden to southern Spain, including large parts of southern Germany as well. However, the Mediterranean and Danubian groupings of the previous period appear to have fragmented into many smaller pieces, some of them apparently backward in technological matters. From 2800 BC, the Danubian Seine-Oise-Marne culture pusheed directly or indirectly southwards and destroyed most of the rich Megalithic culture of western France. After 2600 BC, several phenomena prefigured the changes of the upcoming period:

Large towns with stone walls appeared in two different areas of the Iberian Peninsula: one in the Portuguese region of Estremadura (culture of Vila Nova de Sao Pedro), strongly embedded in the Atlantic Megalithic culture; the other near Almería (southeastern Spain), centred around the large town of Los Millares, of Mediterranean character, probably affected by eastern cultural influxes (tholoi). Despite the many differences, bith civilisations seem have had friendly contact and to productive exchanges. In the area of Dordogne (Aquitaine, France), a new unexpected culture of bowmen appears: the Artenac culture soon takes control of western and even northern France and Belgium. In Poland and nearby regions, the putative Indo-Europeans reorganised and reconsolidated with the culture of the Globular Amphoras. Nevertheless, the influence of many centuries in direct contact with the still-powerful Danubian peoples had greatly modified their culture.

Late Chalcolithic

This period extends from 2500 BC to 1800 or 1700 BC, depending on the region. The dates are general for the whole of Europe, and the Aegean area was already fully in the Bronze Age. c. 2500 BC the new Catacomb culture (proto-Cimmerians?), whose origins were obscure but were also Indo-Europeans, displaced the Yamna peoples in the regions north and east of the Black Sea, confining them to their original area east of the Volga. Around 2400 BC, the Corded Ware people replaced their predecessors and expanded to Danubian and Nordic areas of western Germany. One related branch invaded Denmark and southern Sweden (Scandinavian culture of Individual Sepultures), and the mid-Danubian basin, though showing more continuity, had clear traits of new Indo-European elites (Vučedol culture). Simultaneously, in the West, the Artenac peoples reached Belgium. With the partial exception of Vučedol, the Danubian cultures, which had been so buoyant just a few centuries ago, were wiped off the map of Europe. The rest of the period was the story of a mysterious phenomenon: the Beaker people, which seemed to be of a mercantile character and to have preferred being buried according to a very specific, almost invariable, ritual. Nevertheless, out of their original area of western Central Europe, they appeared only within local cultures and so they never invaded and assimilated but went to live among those peoples and kept their way of life, which is why they are believed to be merchants.

The rest of Europe remained mostly unchanged and apparently peaceful. In 2300 BC, the first Beaker Pottery appeared in Bohemia and expanded in many directions but particularly westward, along the Rhone and the seas, reaching the culture of Vila Nova (Portugal) and Catalonia (Spain) as their limits. Simultaneously but unrelatedly, in 2200 BC in the Aegean region, the Cycladic culture decayed and was substituted by the new palatine phase of the Minoan culture of Crete.

The second phase of Beaker Pottery, from 2100 BC onwards, is marked by the displacement of the centre of thevphenomenon to Portugal, within the culture of Vila Nova. The new centre's influence reached to all of southern and western France but was absent in southern and western Iberia, with the notable exception of Los Millares. After 1900 BC, the centre of the Beaker Pottery returned to Bohemia, and in Iberia, a decentralisation of the phenomenon occurred, with centres in Portugal but also in Los Millares and Ciempozuelos.

Bronze Age

Though the use of bronze started much earlier in the Aegean area (c. 3.200 BC), 2000 BC can be considered typical for the start of this stage in Europe in general.

  • c. 1800 BC, the culture of Los Millares, in Southwestern Spain, was substituted by that of El Argar, fully of the Bronze Age, which may well have been a centralised state.
  • c. 1700 BC, the Central European cultures of Unetice, Adlerberg, Straubing and pre-Lausitz started working bronze, a technique that reached them through the Balkans and Danube.
  • c. 1600 BC is considered a reasonable date to place the start of Mycenaean Greece, after centuries of infiltration of Indo-European Greeks of an unknown origin.
  • c. 1500 BC, most of these Central European cultures were unified in the powerful Tumulus culture. Simultaneously but unrelatedly, the culture of El Argar started Phase B, which sas characterised by a detectable Aegean influence (pithoi burials). About then, it is believed that Minoan Crete fell under the rule of the Mycenaean Greeks.
  • Around 1300 BC, the Indo-European cultures of Central Europe, such as Celts, Italics and certainly Illyrians, changed the cultural phase conforming to the expansionist Urnfield culture, starting a quick expansion that brought them to occupy most of the Balkans, Asia Minor, where they destroyed the Hittite Empire (conquering the secret of iron smelting), northeastern Italy, parts of France, Belgium, the Netherlands, northeastern Spain and southwestern England.

Derivations of the sudden expansion were the Sea Peoples, who attacked Egypt unsuccessfully for some time, including the Philistines (Pelasgians?) and the Dorians, most likely Hellenised members of the group that ended invading Greek itself and destroying the might of Mycene and later Troy.

Simultaneously, around then, the culture of Vila Nova de Sao Pedro, which lasted 1300 years in its urban form, vanishes into a less spectacular one but finally with bronze. The centre of gravity of the Atlantic cultures (the Atlantic Bronze complex) was now displaced towards Great Britain. Also about then, the culture of Villanova, the possible precursor of the Etruscan civilisation, appeared in central Italy, possibly with an Aegean origin.

Iron Age

Though the use of iron was known to the Aegean peoples about 1100 BC, it failed to reached Central Europe before 800 BC, when it gave way to the Hallstatt culture, an Iron Age evolution of the Urnfield culture.

Around then, the Phoenicians, benefitting from the disappearance of the Greek maritime power (Greek Dark Ages) founded their first colony at the entrance of the Atlantic Ocean, in Gadir (modern Cádiz), most likely as a merchant outpost to convey the many mineral resources of Iberia and the British Isles.

Nevertheless, from the 7th century BC onwards, the Greeks recovered their power and started their own colonial expansion, founding Massalia (modern Marseilles) and the Iberian outpost of Emporion (modern Empúries). That occurred only after the Iberians could reconquer Catalonia and the Ebro valley from the Celts, separating physically the Iberian Celts from their continental neighbours.

The second phase of the European Iron Age was defined particularly by the Celtic La Tène culture, which started aroumd 400 BC, followed by a large expansion of them into the Balkans, the British Isles, where they assimilated druidism, and other regions of France and Italy.

The decline of Celtic power under the expansive pressure of Germanic tribes (originally from Scandinavia and Lower Germany) and the forming of the Roman Empire during the 1st century BC was also that of the end of prehistory, properly speaking; though many regions of Europe remained illiterate and therefore outside written history for many centuries, the boundary must be placed somewhere, and that date, near the start of the calendar, seems to be quite convenient. The remaining is regional prehistory, or, in most cases, protohistory, but no longer European prehistory, as a whole.

Genetic history

The genetic history of Europe has been inferred by observing the patterns of genetic diversity across the continent and in the surrounding areas. Use has been made of both classical genetics and molecular genetics. Analysis of the DNA of the modern population of Europe has mainly been used but use has also been made of ancient DNA.

This analysis has shown that modern man entered Europe from the Near East before the Last Glacial Maximum but retreated to refuges in southern Europe in this cold period. Subsequently, people spread out over the whole continent, with subsequent limited migration from the Near East and Asia.

According to a study in 2017, the early farmers belonged predominantly to the paternal Haplogroup G-M201 was also found frequently.

Linguistic history

The written linguistic record in Europe first begins with the Mycenaean record of early Greek in the Late Bronze Age. Unattested languages spoken in Europe in the Bronze and Iron Ages are the object of reconstruction in historical linguistics, in the case of Europe predominantly Indo-European linguistics.

Indo-European is assumed to have spread from the Pontic steppe at the very beginning of the Bronze Age, reaching Western Europe contemporary with the Beaker culture, after about 5,000 years ago.

Various pre-Indo-European substrates have been postulated, but remain speculative; the "Pelasgian" and "Tyrsenian" substrates of the Mediterranean world, an "Old European" (which may itself have been an early form of Indo-European), a "Vasconic" substrate ancestral to the modern Basque language, or a more widespread presence of early Finno-Ugric languages in northern Europe. An early presence of Indo-European throughout Europe has also been suggested ("Paleolithic Continuity Theory").

Donald Ringe emphasizes the "great linguistic diversity" which would generally have been predominant in any area inhabited by small-scale, tribal pre-state societies.

Inequality (mathematics)

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