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Extensive farming

Extensive farming is an agricultural system that involves cultivating crops or raising on large areas using minimal inputs of labor, , fertilizers, and machinery per unit of , resulting in relatively low yields but sustainable use of resources. This approach contrasts with by prioritizing extensive use over high-density production, often relying on processes like rainfall, , and rather than synthetic inputs or advanced . It is prevalent in regions with abundant but , such as arid or semi-arid areas in developing countries like those in and , where it supports subsistence mixed cropping or systems, and in developed areas for and sheep. Examples include , where roam freely on grasslands, and large-scale farming in low-rainfall zones. Globally, extensive systems, particularly livestock-based ones, cover about 25% of the world's and are often tied to traditional societies and practices. Key advantages of extensive farming include reduced operational costs due to low input requirements, improved through free-range practices, and lower environmental impacts such as decreased and . It also promotes by maintaining open habitats and grasslands, prevents shrub encroachment, and enhances sequestration, contributing to services and preservation. However, disadvantages encompass lower and yields compared to intensive methods, higher land demands that can lead to for wildlife, potential from , and economic vulnerabilities from market fluctuations or predation by large carnivores. These systems face ongoing challenges from , land-use pressures, and competition with more efficient intensive , necessitating policy support for .

Definition and Characteristics

Definition

Extensive farming, also known as extensive , is an agricultural system characterized by the use of relatively small inputs of labor, fertilizers, capital, and other resources in proportion to the large area of land under cultivation, relying primarily on the natural productivity of the and environment to achieve sustainable yields. This approach typically involves large-scale operations where crops or are raised with minimal intervention, such as limited , , or soil amendments, allowing natural processes like rainfall, , and to drive output. The goal is to maintain long-term viability on marginal or vast lands where intensive methods would be uneconomical or environmentally unsustainable. In contrast to , which employs high levels of inputs—including synthetic fertilizers, pesticides, machinery, and labor—to maximize yields per unit of and achieve higher per , extensive farming produces lower yields per but demonstrates greater efficiency in terms of output per unit of input due to its reliance on low-resource strategies. This distinction is often quantified through input-output ratios, where extensive systems exhibit lower ratios (fewer inputs per unit of output) because of reduced dependency on external resources, making them more resource-efficient overall despite the lower . For instance, extensive operations may achieve viable production through natural or rain-fed cropping, avoiding the high energy and chemical demands of intensive methods. The term "extensive" in this context originated in 19th-century economic classifications of efficiency, notably through the work of German economist , whose model of agricultural differentiated practices based on proximity to markets and resource intensity, with extensive methods suited to outer zones requiring less capital per area. This framework highlighted how extensive farming optimizes economic returns on peripheral lands by minimizing inputs relative to expansive land areas, influencing modern understandings of agricultural systems.

Key Characteristics

Extensive farming is characterized by the use of large land areas, often spanning thousands of hectares, to achieve production goals with minimal external inputs. This approach contrasts with , which employs high-density planting and heavy resource application on smaller plots to maximize output per unit area. A key operational trait is the low labor density, typically involving one worker managing 100 or more hectares, as seen in regions like and where average farm sizes exceed this threshold per worker. This low on farms reduces labor costs but requires vast expanses to sustain viable output levels. Extensive systems rely heavily on natural and local climate conditions rather than synthetic fertilizers or , allowing ecosystems to regenerate while supporting crop and livestock production. Structurally, extensive farming incorporates practices such as extended crop rotations and fallowing periods to preserve without chemical amendments, enabling nutrients to replenish naturally over time. For , animal densities are strictly limited to the land's —the maximum number that can be supported without degrading pastures or rangelands—often resulting in sparse stocking, such as fewer than one sheep per in arid environments. Measurable indicators include comparatively low yields, such as 1-2 tons of per in extensive systems, versus over 5 tons in intensive counterparts, reflecting the emphasis on over maximization. Input levels remain minimal, with generally confined to basic tools like tractors for plowing and harvesting, avoiding advanced machinery to keep costs low and align with natural processes.

Historical Development

Origins and Early Practices

Extensive farming, encompassing practices like pastoral nomadism and , originated during the around 10,000 BCE, as human communities transitioned from to systematic food production through animal and early crop management in regions with abundant land. In , the of animals such as sheep, goats, and began in the and spread across the steppes, enabling herding groups to follow seasonal migrations for grazing on vast, open landscapes. Similarly, in Africa, emerged around 7,000–8,000 years before present in the , where early herders adapted to arid environments by domesticating and moving with herds to exploit seasonal and availability. These practices were inherently tied to patterns, allowing populations to utilize extensive land areas without intensive soil amendment or . Early implementations of extensive farming included nomadic on the Eurasian steppes, exemplified by the around the 8th century BCE, who maintained mobile economies focused on horses, cattle, and sheep across the Pontic-Caspian grasslands north of the . These groups practiced , shifting herds seasonally to optimize forage while engaging in trade and warfare facilitated by horseback mobility. In the , pre-Columbian communities in tropical forests employed slash-and-burn techniques, clearing vegetation through cutting and controlled burning to create temporary plots for crops like , beans, and , then allowing land to regenerate after a few years of use. This method suited the nutrient-poor soils and dense vegetation of regions such as the Yucatan and , supporting dispersed populations reliant on forest resources and migration to new sites as fertility declined. A pivotal event in the spread of extensive farming was the facilitation of horse-based ranching in through Silk Road trade networks from approximately 200 BCE to 1400 CE, which connected nomadic herders with sedentary societies and promoted the exchange of , breeds, and technologies. Pastoralists in the steppes leveraged for efficient over large distances, integrating , , and production into broader economic systems that sustained migrations across arid and semi-arid zones. This connectivity not only expanded the scale of pastoral operations but also influenced cultural exchanges, laying groundwork for later evolutions such as colonial expansions in the and .

Evolution in the Modern Era

In the , colonial expansion significantly shaped extensive farming through the establishment of large-scale grazing operations in and the . In , following the crossing of the Blue Mountains in , settlers rapidly expanded westward, squatting on vast lands suitable for sheep grazing, leading to the development of expansive sheep stations in that often spanned thousands of square kilometers and supported flocks of up to 10,000 sheep. These stations exemplified low-density , with pastoralists leasing land based on stock numbers and relying on mounted stockmen for management. Similarly, in the , ranching proliferated after the Mexican-American War (1846-1848), as American settlers acquired vast tracts in and the Southwest, adapting colonial traditions to create open-range systems covering millions of acres for beef production. Policy changes further propelled extensive farming on the North American during this era. The U.S. Homestead Act of 1862, signed by President , allowed citizens and intended citizens to claim up to 160 acres of public land for a small fee after five years of residency and improvement, resulting in the distribution of over 270 million acres across 30 states by 1934. This legislation encouraged large-scale land grants and settlement in arid and semi-arid regions, transforming the into a hub for extensive and operations despite challenges like , as homesteaders often consolidated claims into bigger ranches. The 20th century brought mechanization to extensive farming, particularly post-World War II, enhancing efficiency on large landholdings. In the U.S. , adoption surged post-World War II, reaching nearly universal use by 1960, with peak production of 564,000 units in 1951, enabling the replacement of draft animals and the expansion of farm sizes for and production. This shift, accelerated by innovations like self-propelled combines and high-clearance tractors, allowed farmers to cultivate vast areas with fewer laborers, solidifying extensive systems in regions like the wheat belts of and during the 1940s to 1960s. In recent decades, extensive farming has integrated precision technologies like GPS for herd tracking while preserving its low-input core amid . Since the early 2000s, GPS collars and guidance systems have been adopted on U.S. ranches to monitor movements and patterns, with overall GPS use reaching 40% of and ranchland acreage by 2019, particularly on larger operations exceeding 1,000 acres. Despite pressures from global trade and market competition, low-input practices—such as minimal use (e.g., 12 kg/ha in African systems)—persist in low-potential areas of developing countries, facing challenges like degradation and .

Types of Extensive Farming

Pastoral and Ranching Systems

Pastoral and ranching systems represent a core component of extensive farming, centered on the rearing of such as , sheep, and goats primarily on rangelands where rely on natural for sustenance. These systems emphasize low-density rates over expansive areas, allowing to graze freely with minimal intervention in feeding. For instance, in Australian outback operations, large-scale ranches support thousands of head of across vast arid landscapes, leveraging the expansive areas for self-sustaining herds. Management in these systems prioritizes sustainable practices to maintain rangeland health and prevent degradation. is a key technique, involving the division of pastures into paddocks and systematic movement of to allow recovery, thereby avoiding overstocking and promoting regrowth. Additionally, focuses on developing hardy breeds adapted to challenging environments; the sheep, for example, has been bred for resilience in arid zones, exhibiting traits like heat tolerance and efficient use of sparse . The primary outputs of pastoral and ranching systems include , , and products, achieved through low per-animal inputs that align with the extensive nature of the operations. Animals are typically raised without supplemental feed during dry seasons, depending instead on natural pastures, which keeps production costs low while yielding robust, grass-fed products. In mixed operations, these systems may integrate briefly with crop production for complementary , though the focus remains on .

Arable and Shifting Cultivation Systems

Arable extensive farming focuses on the cultivation of staple grains such as and across vast expanses of land, typically in semi-arid or temperate regions where low rainfall limits productivity per unit area. This system employs minimal practices, such as no-till or reduced-till methods, to preserve , reduce , and conserve , allowing s to be sown directly into crop residues from previous seasons. Seeding rates are kept low to match the sparse resource availability, often around 50 kg per for in dryland conditions, promoting wider plant spacing and reliance on natural rainfall rather than or heavy fertilization. In contrast, , also known as , is a traditional extensive system prevalent in tropical rainforests and forested uplands. It involves clearing vegetation by cutting and burning to release nutrients into the ash, followed by planting a mix of crops on the prepared plots for a short period of 3-5 years before the land is abandoned to regenerate naturally. This cycling prevents depletion in nutrient-poor tropical , where continuous cropping would quickly exhaust fertility. Management in both systems emphasizes land and ing to maintain long-term . In arable setups, fields may lie intermittently or rotate with cover crops, while relies on extended periods of 20-30 years in traditional setups to allow regrowth and nutrient replenishment through natural processes. These practices support the of bulk commodities like for export, with yields in U.S. wheat belts under dryland conditions averaging around 2.7 tons per (based on 2009 data). In some regions, arable systems integrate briefly with elements, such as crop residues post-harvest in mixed farms.

Geographical Distribution

Primary Regions and Climates

Extensive farming is predominantly practiced in vast, open landscapes where low population densities and abundant land availability allow for large-scale operations with minimal inputs. Key regions include the of , where extensive grain and production occurs on expansive flatlands suitable for mechanized farming. In , the inland areas, including regions around the Murray-Darling Basin, support widespread extensive grazing of cattle and sheep across arid and semi-arid zones covering nearly half of the continent. The Eurasian steppes, especially in , feature extensive and crop cultivation on the world's largest contiguous rangelands, where mobile and dominate. Similarly, the African Sahel hosts extensive pastoral systems, with rearing on marginal lands stretching across countries like , , and , integrated with limited crop production. These regions are characterized by climatic conditions that favor extensive systems, primarily semi-arid to temperate zones with annual rainfall typically ranging from 300 to 800 mm, which supports natural vegetation growth without intensive irrigation. In semi-arid environments, erratic precipitation patterns necessitate reliance on hardy crops and grazing animals adapted to drought, as seen in the steppes and Sahel where rainfall often falls below 500 mm but enables seasonal forage. Temperate prairies in North America receive more consistent 500-800 mm annually, allowing for extensive wheat and corn cultivation alongside ranching. Regions with annual rainfall averaging 400-600 mm, such as parts of the Australian inland and the Argentine Pampas, support sheep farming and rotational grazing that maintains soil health. Farm scales in these areas reflect the need for large landholdings to achieve viable yields under low-input conditions; for instance, in the Argentine , extensive operations can range from 1,000 to over 10,000 hectares per , enabling low-density stocking rates across fertile grasslands. Comparable scales are observed in Kazakh steppes, where farms span thousands of hectares to accommodate nomadic patterns. Such expansive operations underscore the spatial demands of extensive farming in climates where productivity per unit area is inherently limited by water availability.

Factors Affecting Distribution

Extensive farming's distribution is significantly shaped by environmental drivers, particularly and . In regions with low , such as marginal or degraded lands, extensive systems become viable by spreading over larger areas to compensate for limited availability and achieve sustainable outputs without heavy reliance on synthetic fertilizers. Similarly, water availability plays a key role, as extensive farming predominantly depends on natural rainfall rather than infrastructure, making it suitable for arid or semi-arid zones where supplemental water sources are impractical or uneconomical. Economic factors further determine where extensive farming predominates, with land abundance and low acquisition costs enabling its expansion. In post-colonial contexts, such as parts of , historical land grants and policies favoring large-scale allocation promoted -extensive techniques by providing cheap access to vast tracts for and crop production. Additionally, low capital availability in developing regions discourages intensive methods that require substantial investments in machinery and inputs, steering farmers toward extensive practices that minimize upfront costs. Social drivers, including labor dynamics and cultural practices, also influence extensive farming's geographical spread. Labor scarcity in remote or sparsely populated areas favors extensive systems, which demand fewer workers per unit of land compared to labor-intensive alternatives, allowing operations to function with minimal on-site personnel. Cultural traditions reinforce this, as seen in nomadic in , where millennia-old practices integrate extensive with seasonal mobility to utilize rangelands efficiently. For instance, these factors underpin extensive ranching operations in remote areas like the Australian outback.

Farming Practices

Land Use and Management

In extensive farming systems, emphasizes long-term through practices that minimize intervention while preserving and vegetation productivity. A key strategy involves extensive crop rotations, where cultivated phases alternate with extended periods, often lasting 10-25 years or more in traditional extensive systems like , to allow soil nutrients to replenish naturally. These rotations prevent nutrient depletion by integrating periods of rest, during which native vegetation regrows, thereby supporting subsequent crop yields without heavy reliance on external inputs. Monitoring is central to and mixed extensive systems, where stocking rates are determined based on cover and availability to avoid . For instance, optimal rates are calculated using models that assess rainfall patterns and plant , ensuring numbers align with the land's regenerative potential. This approach, often guided by local ecological indicators, maintains health over decades by adjusting animal loads seasonally. Soil and vegetation management in these systems prioritizes natural processes, such as regeneration during periods, where uncultivated land allows to restore and microbial activity. In regions, controlled burning is employed to renew grass cover by clearing old growth and stimulating fresh sprouts, mimicking natural cycles to enhance quality. These techniques align with the low-input philosophy of extensive farming, relying on rather than synthetic amendments. At larger scales, extensive operations utilize vast open ranges with minimal to facilitate natural herd movement and reduce costs, as seen in open-range policies where roam freely across unfenced public and private lands. integration occurs through uncultivated margins around fields, which serve as buffers for native and , fostering connectivity and supporting pollinators essential for crop edges.

Inputs and Technologies

Extensive farming relies on minimal external inputs to maintain low-intensity operations, with minimal application, often relying on natural nutrients with low external inputs, such as around 10 kg of total nutrients per in regions like , in systems like dryland grain production. use is similarly restricted, favoring natural controls such as biological agents and to suppress pests without synthetic chemicals. Technologies in extensive farming emphasize basic mechanization suited to vast areas, including the widespread adoption of combine harvesters for arable systems since the , which enabled efficient harvesting over large fields with reduced labor needs. More recent innovations include low-tech tools like monitoring for herds, introduced post-2010 to track animal health and location across expansive pastures without intensive ground patrols. Labor requirements are low due to the scale, often involving very few seasonal workers, with ratios below 0.1 per 1,000 hectares in mechanized or arable operations, supplemented by mechanized processes. Capital financing prioritizes land leases over debt-based loans, allowing operators to access extensive tracts affordably while minimizing upfront investment risks.

Advantages

Economic Advantages

Extensive farming provides notable cost efficiencies through significantly lower operational expenses per compared to intensive systems, primarily due to minimal use of external inputs like fertilizers, pesticides, and heavy machinery. This low-input model allows for by utilizing large land volumes, spreading fixed costs such as labor and basic over vast areas to achieve without proportional increases in variable expenses. A key market benefit lies in its suitability for export-oriented commodities, where extensive systems produce high volumes of specialized goods like and for global . For example, Australia's extensive sheep ranching supports an annual valued at approximately $2.8 billion, underscoring the economic scale achievable in resource-abundant regions. Furthermore, the reduced dependence on purchased inputs confers to price fluctuations in fertilizers, fuels, and other commodities, mitigating financial risks during periods of . In terms of long-term viability, extensive farming's lower results in reduced debt reliance, as producers invest less in technology and ongoing inputs, fostering in resource-scarce or marginal lands. U.S. ranchers operating systems, for instance, benefit from lower costs per cow on larger operations, with projections showing positive net returns of $138 per cow in 2024.

Environmental and Social Advantages

Extensive farming's reliance on natural ecosystems and minimal use of synthetic fertilizers and pesticides results in substantially lower chemical runoff compared to intensive . Low-input systems characteristic of extensive practices help mitigate and risks. This approach limits nutrient excesses that contribute to algal blooms and dead zones in aquatic systems, as evidenced by reduced discharge potentials in extensive operations. By maintaining large uncultivated or lightly grazed areas, extensive farming fosters through habitat preservation and reduced . In regions like the Mediterranean, these systems support diverse and by preventing the intensification or abandonment of land that would otherwise lead to biodiversity decline. Less intensive agricultural practices overall enhance across taxonomic groups, including pollinators and soil organisms, contributing to . Extensive grasslands and pastures also play a key role in , helping mitigate . Well-managed extensive systems can sequester 0.5 to 3.6 tonnes of CO₂ equivalent per per year through organic carbon accumulation. This natural storage capacity offsets emissions associated with , particularly when local resources are utilized without heavy mechanization or feed imports. On the social front, extensive farming improves by allowing to exhibit natural behaviors, such as free-range , which reduces stress and health issues prevalent in confined intensive settings. For communities, such as the Maasai in , traditional sustains cultural practices and communal , preserving social structures tied to lifestyles. These benefits support community cohesion and knowledge transmission across generations.

Disadvantages

Economic Disadvantages

Extensive farming's reliance on vast areas for low-input production results in significantly lower yields per compared to intensive methods, often around 50% less output, such as 2.3 tonnes per for under low-input systems versus 6.3 tonnes under high-input ones. This reduced productivity heightens vulnerability in global markets, where extensive farmers struggle to compete with higher-volume intensive producers, leading to inconsistent revenues and market share erosion during periods of fluctuating demand. High initial capital requirements pose substantial barriers, particularly the cost of acquiring large tracts of essential for extensive operations; in , average broadacre farmland prices reached approximately AUD 9,429 per in 2023, with extensive lands often exceeding AUD 1,000 per in arid regions. These investments amplify sensitivity to price volatility, as seen in the Australian during the , where farm-gate wool values plummeted from over AUD 6 billion to around AUD 2.5 billion due to subdued global demand and economic slowdowns, forcing many producers into financial distress and diversification. Labor dynamics in extensive farming contribute to economic instability through seasonal unemployment patterns in rural areas, where work is concentrated during planting or shearing periods, leaving workers idle for much of the year and straining local economies. Farm consolidations, driven by the need for scale to offset low yields, have further reduced opportunities; since the , U.S. agricultural declined by over 30% amid widespread farm mergers, with similar trends in contributing to rural job losses.

Environmental and Social Disadvantages

Extensive farming's expansive land requirements and low stocking densities often result in , which accelerates degradation and contributes to in arid and semi-arid regions. In the of Africa, by in extensive systems has been a primary driver of , leading to the loss of approximately 650,000 km² of productive land since the 1970s, representing about 20% of the region's once-arable rangelands. This process exposes bare to and water , reducing vegetation cover and creating feedback loops that further entrench arid conditions. Additionally, large herds maintained in extensive systems emit significant quantities of through , contributing to global levels, although per-animal emissions are typically lower than in intensive operations due to grass-based diets with lower energy density. Socially, the labor-extensive nature of these systems promotes rural depopulation as farms consolidate and mechanize, diminishing employment opportunities in remote areas. In Australia's regions, where extensive dominates, rural populations have declined between 1980 and 2020, driven by fewer family-run operations and to centers for better services and jobs. This exodus strains remaining communities, leading to aging demographics, reduced local services, and challenges in maintaining . Furthermore, extensive land use frequently sparks conflicts over resources with groups and initiatives, as commercial operations expand into traditional or protected territories. In the , for instance, extensive cattle ranching has encroached on lands, resulting in violent disputes, , and loss of for communities reliant on those areas. issues are compounded by practices like , where repeated clearing and short periods cause notable , depleting nutrients and hindering long-term productivity. Low-input approaches in these systems can amplify vulnerabilities to climate variability, further eroding resilience in marginal lands.

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