Land use: Difference between revisions

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Land use is an umbrella term to describe what happens on a parcel of land. It concerns the benefits derived from using the land, and also the land management actions that humans carry out there.<ref name=":1" /> The following categories are used for land use: forest land, cropland (agricultural land), grassland, wetlands, settlements and other lands.<ref name=":2" /> The way humans use land, and how land use is changing, has many impacts on the environment.<ref name="Meyfroidt 52–67">Template:Cite journal</ref><ref>Template:Cite journal</ref> Effects of land use choices and changes by humans include, for example, urban sprawl, soil erosion, soil degradation, land degradation and desertification.<ref>UN Land Degradation and Land Use/Cover Data Sources ret. 26 June 2007</ref> Land use and land management practices have a major impact on natural resources including water, soil, nutrients, plants and animals.<ref>Template:Cite journal</ref><ref name="Global Land Outlook">Template:Cite report</ref>

Land use change is "the change from one land-use category to another".<ref name=":2" /> Land-use change, together with use of fossil fuels, are the major anthropogenic sources of carbon dioxide, a dominant greenhouse gas.<ref name=":16" /> Human activity is the most significant cause of land cover change, and humans are also directly impacted by the environmental consequences of these changes.<ref name=":72" /> For example, deforestation (the systematic and permanent conversion of previously forested land for other uses) has historically been a primary facilitator of land use and land cover change.<ref name=":8">Template:Cite journal</ref><ref name=":17">Template:Cite web</ref>

The study of land change relies on the synthesis of a wide range of data and a diverse range of data collection methods.<ref name=":52">Template:Cite journal</ref> These include land cover monitoring and assessments, modeling risk and vulnerability, and land change modeling.

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The IPCC defines the term land use as the "total of arrangements, activities and inputs applied to a parcel of land".<ref name=":2">IPCC, 2022: Annex II: Glossary [Möller, V., R. van Diemen, J.B.R. Matthews, C. Méndez, S. Semenov, J.S. Fuglestvedt, A. Reisinger (eds.)]. In: Climate Change 2022: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [H.-O. Pörtner, D.C. Roberts, M. Tignor, E.S. Poloczanska, K. Mintenbeck, A. Alegría, M. Craig, S. Langsdorf, S. Löschke, V. Möller, A. Okem, B. Rama (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 2897–2930, doi:10.1017/9781009325844.029.</ref>Template:Rp The same report groups land use into the following categories: forest land, cropland (agricultural land), grassland, wetlands, settlements and other lands.<ref name=":2" />Template:Rp

Another definition is that of the United Nations' Food and Agriculture Organization: "Land use concerns the products and/or benefits obtained from use of the land as well as the land management actions (activities) carried out by humans to produce those products and benefits."<ref name=":1">FAO Land and Water Division retrieved 14 September 2010</ref>

As of the early 1990s, about 13% of the Earth was considered arable land, with 26% in pasture, 32% forests and woodland, and 1.5% urban areas.<ref name=":1" />

As of 2015, the total arable land is 10.7% of the land surface, with 1.3% being permanent cropland.<ref>Template:Cite web</ref><ref>Template:Cite web</ref>

For example, the US Department of Agriculture has identified six major types of land use in the United States. Acreage statistics for each type of land use in the contiguous 48 states in 2017 were as follows:<ref name=":0">Template:Cite news</ref>

US land use (2017)<ref name=":0" />

Use	acreage (M)	km2 (M)	% of total
Pasture/range	654	2.647	35
Forest	538.6	2.18	28
Cropland	391.5	1.584	21
Special use	168.8	0.683	9
Miscellaneous	68.9	0.279	4
Urban	69.4	0.281	4
Total	1,891	7.653	100

Special use areas in the table above include national parks (29 M acres) and state parks (15 M), wildlife areas (64.4 M), highways (21 M), railroads (3M), military bases (25 M), airports (3M) and a few others. Miscellaneous includes cemeteries, golf courses, marshes, deserts, and other areas of "low economic value". The total land area of the United States is 9.1 M km² but the total used here refers only to the contiguous 48 states, without Alaska etc.

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Land use change is "the change from one land-use category to another".<ref name=":2" />Template:Rp Land-use change, together with use of fossil fuels, are the major anthropogenic sources of carbon dioxide, a dominant greenhouse gas.<ref name=":16">Template:Cite web</ref>

Human activity is the most significant cause of land cover change, and humans are also directly impacted by the environmental consequences of these changes.<ref name=":72">Template:Cite web</ref> Collective land use and land cover changes have fundamentally altered the functioning of key Earth systems.<ref name=":112">Template:Cite journal</ref> For instance, human changes to land use and land cover have a profound impact on climate at a local and regional level, which in turn contributes to climate change.<ref name=":112" />

Land use by humans has a long history, first emerging more than 10,000 years ago.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> Human changes to land surfaces have been documented for centuries as having significant impacts on both earth systems and human well-being. Deforestation is an example of large-scale land use change. The deforestation of temperate regions since 1750 has had a major effect on land cover.<ref>Template:Cite web</ref> The reshaping of landscapes to serve human needs, such as the deforestation for farmland, can have long-term effects on earth systems and exacerbate the causes of climate change.<ref name=":02">Template:Cite journal</ref>

Although the burning of fossil fuels is the primary driver of present-day climate change, prior to the Industrial Revolution, deforestation and irrigation were the largest sources of human-driven greenhouse gas emissions.<ref name=":02" /> Even today, 35% of anthropogenic carbon dioxide contributions can be attributed to land use or land cover changes.<ref name=":02" /> Currently, almost 50% of Earth’s non-ice land surface has been transformed by human activities, with approximately 40% of that land used for agriculture, surpassing natural systems as the principal source of nitrogen emissions.<ref name=":02" />

Increasing land conversion by humans in future is not inevitable: In a discussion on response options to climate change mitigation and adaptation an IPCC special report stated that "a number of response options such as increased food productivity, dietary choices and food losses, and waste reduction, can reduce demand for land conversion, thereby potentially freeing land and creating opportunities for enhanced implementation of other response options".<ref name=":15">IPCC, 2019: Summary for Policymakers. In: Climate Change and Land: an IPCC special report on climate change, desertification, land degradation, sustainable land management, food security, and greenhouse gas fluxes in terrestrial ecosystems [P.R. Shukla, J. Skea, E. Calvo Buendia, V. Masson-Delmotte, H.- O. Pörtner, D. C. Roberts, P. Zhai, R. Slade, S. Connors, R. van Diemen, M. Ferrat, E. Haughey, S. Luz, S. Neogi, M. Pathak, J. Petzold, J. Portugal Pereira, P. Vyas, E. Huntley, K. Kissick, M. Belkacemi, J. Malley, (eds.)]. https://doi.org/10.1017/9781009157988.001</ref>Template:Rp

Land change science relies heavily on the synthesis of a wide range of data and a diverse range of data collection methods, some of which are detailed below.<ref name=":5">Template:Cite journal</ref>

A primary function of land change science is to document and model long-term patterns of landscape change, which may result from both human activity and natural processes.<ref name=":3">Template:Cite web</ref> In the course of monitoring and assessing land cover and land use changes, scientists look at several factors, including where land-cover and land-use are changing, the extent and timescale of changes, and how changes vary through time.<ref name=":7">Template:Cite web</ref> To this end, scientists use a variety of tools, including satellite imagery and other sources of remotely sensed data (e.g., aircraft imagery), field observations, historical accounts, and reconstruction modeling.<ref name=":3" /> These tools, particularly satellite imagery, allow land change scientists to accurately monitor land-change rates and create a consistent, long-term record to quantify change variability over time.<ref name=":7" /> Through observing patterns in land cover changes, scientists can determine the consequences of these changes, predict the impact of future changes, and use this information to inform strategic land management.

Modeling risk and vulnerability is also one of land change science's practical applications. Accurate predictions of how human activity will influence land cover change over time, as well as the impact that such changes have on the sustainability of ecological and human systems, can inform the creation of policy designed to address these changes.<ref name=":82">Template:Cite journal</ref>

Studying risk and vulnerability entails the development of quantitative, qualitative, and geospatial models, methods, and support tools.<ref name=":4">Template:Cite web</ref> The purpose of these tools is to communicate the vulnerability of both human communities and natural ecosystems to hazard events or long-term land change. Modeling risk and vulnerability requires analyses of community sensitivity to hazards, an understanding of geographic distributions of people and infrastructure, and accurate calculation of the probability of specific disturbances occurring.<ref name=":4" />

A key method for studying risk and vulnerability is land change modeling (LCM), which can be used to simulate changes and land use and land cover.<ref name=":10">Template:Cite journal</ref> LCMs can be used to predict how land use and land cover may change under alternate circumstances, which is useful for risk assessment, in that it allows for the prediction of potential impacts and can be used to inform policy decisions, albeit with some uncertainty.<ref name=":10" />Template:Excerpt

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Deforestation is the systematic and permanent conversion of previously forested land for other uses.<ref name=":17" /> It has historically been a primary facilitator of land use and land cover change.<ref name=":8" /> Forests are a vital part of the global ecosystem and are essential to carbon capture, ecological processes, and biodiversity.<ref name=":8" /> However, since the invention of agriculture, global forest cover has diminished by 35%.<ref name=":8" />

There is rarely one direct or underlying cause for deforestation.<ref name=":12">Template:Cite web</ref> Rather, deforestation is the result of intertwining systemic forces working simultaneously or sequentially to change land cover.<ref name=":12" /> Deforestation occurs for many interconnected reasons.<ref name=":92">Template:Cite journal</ref> For instance, mass deforestation is often viewed as the product of industrial agriculture, yet a considerable portion old-growth forest deforestation is the result of small-scale migrant farming.<ref name=":9">Template:Cite journal</ref> As forest cover is removed, forest resources become exhausted and increasing populations lead to scarcity, which prompts people to move again to previously undisturbed forest, restarting the process of deforestation.<ref name=":9" /> There are several reasons behind this continued migration: poverty-driven lack of available farmland and high costs may lead to an increase in farming intensity on existing farmland.<ref name=":9" /> This leads to the overexploitation of farmland, and down the line results in desertification, another land cover change, which renders soil unusable and unprofitable, requiring farmers to seek out untouched and unpopulated old-growth forests.<ref name=":9" />

In addition to rural migration and subsistence farming, economic development can also play a substantial role in deforestation.<ref name=":12" /> For example, road and railway expansions designed to increase quality of life have resulted in significant deforestation in the Amazon and Central America.<ref name=":12" /> Moreover, the underlying drivers of economic development are often linked to global economic engagement, ranging from increased exports to a foreign debt.<ref name=":12" />

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Broadly, urbanization is the increasing number of people who live in urban areas. Urbanization refers to both urban population growth and the physical growth of urban areas.<ref>Template:Cite web</ref> According to the United Nations, the global urban population has increased rapidly since 1950, from 751 million to 4.2 billion in 2018, and current trends predict this number will continue to grow.<ref name=":13">United Nations, Department of Economic and Social Affairs, Population Division (2019). World Urbanization Prospects 2018: Highlights (ST/ESA/SER.A/421).</ref> Accompanying this population shift are significant changes in economic flow, culture and lifestyle, and spatial population distribution.<ref name=":13" /> Although urbanized areas cover just 3% of the Earth's surface, they nevertheless have a significant impact on land use and land cover change.<ref>Template:Cite journal</ref>

Urbanization is important to land use and land cover change for a variety of reasons. In particular, urbanization affects land change elsewhere through the shifting of urban-rural linkages, or the ecological footprint of the transfer of goods and services between urban and rural areas.<ref name=":11">Template:Cite journal</ref> Increases in urbanization lead to increases in consumption, which puts increased pressure on surrounding rural lands.<ref name=":11" /> The outward spread of urban areas can also take over adjacent land formerly used for crop cultivation.<ref name=":11" />

Urbanization additionally affects land cover through the urban heat island effect. Heat islands occur when, due to high concentrations of structures, such as buildings and roads, that absorb and re-emit solar radiation, and low concentrations of vegetative cover, urban areas experience higher temperatures than surrounding areas.<ref name=":14">Template:Cite web</ref> The high temperatures associated with heat islands can compromise human health, particularly in low-income areas.<ref name=":14" />

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The rapid decline of the Aral Sea is an example how local-scale land use and land change can have compounded impacts on regional climate systems, particularly when human activities heavily disrupt natural climatic cycles, how land change science can be used to map and study such changes.<ref name=":03">Template:Cite journal</ref> In 1960, the Aral Sea, located in Central Asia, was the world's fourth largest lake.<ref name=":6">Template:Cite book</ref> However, a water diversion project, undertaken by the Soviet Union to irrigate arid plains in what is now Kazakhstan, Uzbekistan, and Turkmenistan, resulted in the Aral Sea losing 85% of its land cover and 90% of its volume.<ref name=":6" /> The loss of the Aral Sea has had a significant effect on human-environment interactions in the region, including the decimation of the sea's fishing industry and the salinization of agricultural lands by the wind-spread of dried sea salt beds.<ref name=":03" /><ref name=":6" />

Additionally, scientists have been able to use technology such as NASA's Moderate Resolution Imaging Spectroradiometer (MODIS) to track changes to the Aral Sea and its surrounding climate over time.<ref>Template:Cite web</ref> This use of modeling and satellite imagery to track human-caused land cover change is characteristic of the scope of land change science.

Commonly, political jurisdictions will undertake land-use planning and regulate the use of land in an attempt to avoid land-use conflicts. Land use plans are implemented through land division and use ordinances and regulations, such as zoning regulations.

The urban growth boundary is one form of land-use regulation. For example, Portland, Oregon is required to have an urban growth boundary which contains at least Template:Convert of vacant land. Additionally, Oregon restricts the development of farmland. The regulations are controversial, but an economic analysis concluded that farmland appreciated similarly to the other land.<ref>Jaeker WG, Plantinga AJ (2007). How have Land-use regulations Affected Property Values in Oregon? Template:Webarchive OSU Extension.</ref>

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In colonial America, few regulations were originally put into place regarding the usage of land. As society shifted from rural to urban, public land regulation became important, especially to city governments trying to control industry, commerce, and housing within their boundaries. The first zoning ordinance was passed in New York City in 1916,<ref>Village of Euclid, Ohio v. Ambler Realty Co.</ref><ref>Template:Cite journal</ref> and, by the 1930s, most states had adopted zoning laws. In the 1970s, concerns about the environment and historic preservation led to further regulation.

Today, federal, state, and local governments regulate growth and development through statutory law. The majority of controls on land, however, stem from the actions of private developers and individuals. Judicial decisions and enforcement of private land-use arrangements can reinforce public regulation, and achieve forms and levels of control that regulatory zoning cannot. There is growing concern that land use regulation is a direct cause of housing segregation in the United States today.<ref>Template:Cite journal</ref>

Two major federal laws passed in the 1960s limit the use of land significantly. These are the National Historic Preservation Act of 1966 (today embodied in 16 U.S.C. 461 et seq.) and the National Environmental Policy Act of 1969 (42 U.S.C. 4321 et seq.).

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