Fact-checked by Grok 2 weeks ago

Marginal land

Marginal land refers to areas characterized by low productivity for conventional due to biophysical constraints such as poor , , steep slopes, salinization, or extreme climatic conditions, often combined with socioeconomic limitations like limited access to markets and that hinder cost-effective production. These lands are dynamically defined and can vary by context, encompassing degraded, abandoned, or less-favorable agricultural areas that are not suitable for high-yield crop production but may support alternative uses. Globally, as of 2022, marginal lands cover approximately 21% of the Earth's land surface, totaling about 2.74 billion hectares out of 13.5 billion hectares, with 224–300 million hectares currently under agricultural use. The characteristics of marginal lands often include fragile ecosystems prone to degradation, erosion, and reduced nutrient-holding capacity, affecting around 40% of the world's arable land and exacerbating issues like salinization, which impacts nearly 1.4 billion hectares worldwide as of 2024. These areas are particularly vulnerable to climate change, which can intensify water scarcity and environmental risks, leading to further marginalization. Assessment of marginal lands typically relies on qualitative methods, such as the United States Department of Agriculture's Natural Resources Conservation Service (USDA-NRCS) land capability classification system, which categorizes them into classes IV–VIII based on limitations for crop production, or frameworks from the Food and Agriculture Organization (FAO) that consider factors like erosion, flooding, and soil toxicity. Despite these challenges, marginal lands hold potential for rehabilitation through targeted management practices, including conservation tillage, soil amendments, and policy interventions like the U.S. Conservation Reserve Program (CRP), which aim to balance agricultural viability with ecosystem services such as carbon sequestration and biodiversity preservation. As of 2022, marginal lands play a in global and alleviation, supporting 1.75 billion people—38% of the world's rural —primarily in developing regions like (27% of its land area) and (11%). In these hotspots, where approximately 700 million people live on less than USD 2.15 per day as of 2024 and around 733 million faced as of 2023, marginal lands represent opportunities for sustainable intensification to enhance and reduce , though they currently contribute to heightened vulnerability due to affecting 3.2 billion people globally. Beyond traditional , such as limited or low-input cropping, marginal lands are increasingly utilized for production (e.g., biomass crops on 3.6 million hectares in ) and projects like solar farms, which can coexist with practices such as pollinator habitats or solar to minimize environmental impacts while generating economic returns. Effective policies, including the U.S. and Security Act, emphasize their role in by promoting non-competitive land uses that avoid displacement of production.

Definition and Characteristics

Core Definition

Marginal land refers to areas of agricultural characterized by low productivity potential, where the economic benefits derived from barely offset the associated production costs, often stemming from inherent limitations that hinder efficient farming. This emphasizes the economic at which land becomes unprofitable for conventional crop production, leading to its exclusion from intensive use. In contrast to , which supports viable crop yields and positive net returns through standard practices, marginal land marks the boundary where returns diminish to near zero after accounting for inputs like labor, fertilizers, and machinery. This distinction highlights marginality not as absolute barrenness but as a relative economic viability, often assessed against regional benchmarks for profitability. Basic classification systems for marginal land include soil-based approaches, which identify limitations such as low or erosion-prone profiles using standardized ratings, and economic evaluations, which focus on scenarios where input costs exceed or equal output values, resulting in minimal or no surplus. These systems provide a for determining suitability without implying uniform degradation across all cases. Such classifications align briefly with principles, where marginal land generates no excess return beyond production expenses.

Key Physical and Economic Traits

Marginal land exhibits distinct physical traits that hinder conventional agricultural use, primarily stemming from limitations. Poor is a hallmark, often manifested as low nutrient content, which reduces and yields, or high acidity that inhibits and microbial activity. Steep , typically with slopes exceeding 15%, exacerbates these issues by complicating machinery operation and accelerating loss. Inadequate water availability further qualifies land as marginal, encompassing both chronic conditions with insufficient rainfall and excessive wetness from poor or high water tables, leading to waterlogging that restricts development. Exposure to is another critical trait, where fragile soils on undulating terrains are prone to wind or water-induced degradation, diminishing depth below viable thresholds like 50 cm. These physical constraints are often quantified through established classification systems to identify marginal suitability. In the United States, the USDA Land Capability Classification assigns Classes V through VIII to such lands based on severe limitations; for instance, Class V soils have limitations such as wetness or stoniness that make cultivation impractical but allow pasture, range, or woodland uses, while Class VI soils feature steep slopes, low moisture capacity, or excessive wetness that preclude cultivation but allow limited grazing or forestry with management. Class VII intensifies these with very steep gradients or shallow rooting zones, restricting use to woodland or wildlife, while Class VIII represents the most marginal, with erosion hazards or salinity rendering commercial production impossible. Internationally, criteria like the Soil Ecological Index (SEI) integrate factors such as bulk density, moisture index, and agrochemical properties to score land marginality, with low scores indicating unsuitability; similarly, yields below 9 t/ha for corn or growing periods under 210 days signal marginal status. Economically, marginal land is defined by elevated cultivation costs that erode profitability, often requiring extensive inputs like soil amendments or irrigation infrastructure to achieve even modest yields. These costs lead to low profitability s, where the ratio of production expenses to output approaches or exceeds unity, making operations unviable without subsidies. Cost-to-yield s serve as key metrics, evaluating input-output balances to determine economic marginality; for example, land is deemed marginal when total inputs (e.g., labor, fertilizers) equal or surpass from expected harvests, aligning with the core of zero net returns. Such indices emphasize the interplay of physical drawbacks and factors, where high needs amplify expenses relative to low-yield outputs.

Historical and Theoretical Foundations

Early Economic Theories

The concept of marginal land emerged prominently in through David Ricardo's theory of differential rent, outlined in his 1817 work On the Principles of Political Economy and Taxation. Ricardo posited that land rents arise from differences in and location, with the most inferior or marginal land in yielding no because its produce just covers the costs of , serving as the baseline for determining rents on superior lands. This marginal land represents the threshold where additional or forces the extension of cultivation to less productive areas without generating surplus for landlords. Ricardo's framework established rent gradients, where more fertile lands command progressively higher due to their greater net produce after covering production costs, while the of agricultural output is set by the from the marginal land to ensure profitability across all cultivated plots. Under this model, as population grows, inferior lands are brought into use, compressing profits and wages while elevating , thereby illustrating how land scarcity shapes economic distribution. This theory profoundly influenced , integrating Thomas Malthus's ideas from his 1798 An Essay on the Principle of Population, which emphasized population pressures outpacing food supply and driving cultivation onto marginal lands with . Ricardo adopted and refined Malthusian dynamics to argue that unchecked would compel the use of progressively poorer soils, intensifying economic tensions between classes and limiting long-term . These foundational ideas laid the groundwork for later , though modern extensions often incorporate technological advancements to mitigate marginal land constraints.

Evolution in Agricultural Policy

In the early 20th century, concepts of marginal land, building on David Ricardo's 19th-century theory of economic rent that distinguished land productivity based on fertility and location, began influencing agricultural policies aimed at sustainable land use. During the 1930s Dust Bowl crisis in the United States, the Soil Conservation Service (SCS), established by the Soil Conservation Act of 1935, developed land capability classifications to identify submarginal lands prone to erosion and unsuitable for intensive cropping. These classifications guided federal efforts to retire approximately 11 million acres of such lands from production through purchases and resettlements under the Resettlement Administration and its successor, the Farm Security Administration, providing payments to farmers to shift to conservation practices and prevent further degradation. The Bankhead-Jones Farm Tenant Act of 1937 further authorized the acquisition of submarginal farmlands for retirement, marking a pivotal policy shift toward land retirement as a mechanism for soil conservation and economic stabilization during the Great Depression. In the , the (CAP), launched in 1962 to support farm incomes and stabilize markets, initially focused on price supports but evolved through reforms to address overproduction and environmental concerns involving marginal lands. The 1992 MacSharry reforms introduced compulsory set-aside schemes, requiring farmers to withdraw at least 15% of from production in exchange for compensatory payments, which helped control surpluses while allowing marginal areas to revert to non-cropping uses like or . Subsequent CAP reforms, such as the 2003 Fischler reforms and the 2013 policy update, decoupled payments from production and incorporated environmental cross-compliance, including set-asides and agri-environmental schemes that provided additional payments for maintaining marginal lands in ecological states, such as through the Programme's support for less-favored areas. In the 2020s, biofuel mandates in both the and have promoted the use of marginal lands to produce advanced from non-food feedstocks, minimizing displacement of crops and indirect change. The promotes cellulosic through volume mandates, while the 2022 offers tax credits, such as the 45Z clean fuel production credit, for low-carbon fuels including those produced from marginal or idle lands using feedstocks like switchgrass. Similarly, the 's Revised Renewable Energy Directive (RED III, effective 2023) sets a sub-target of 5.5% for advanced and of non-biological origin in transport energy by 2030, prioritizing feedstocks from marginal lands to meet criteria that avoid crop . These policies reflect a broader emphasis on marginal lands as a resource for transitions while safeguarding .

Uses and Management Practices

Agricultural Applications

Marginal lands, characterized by low , poor water retention, and risks, require specialized farming techniques to sustain and production. Conservation minimizes disturbance, preserving and reducing on these challenging sites, while cover cropping with or grasses maintains cover, enhances nutrient cycling, and suppresses weeds to counteract nutrient deficiencies. , employing tools like variable-rate applicators and sensors, allows targeted inputs such as fertilizers and water, optimizing resource use on heterogeneous marginal soils and potentially improving over time. These methods collectively address low by promoting and microbial activity, enabling viable food production where conventional would exacerbate . Suitable crops for marginal lands emphasize hardy, low-input varieties adapted to stress conditions, such as drought-resistant grains including , millet, and improved wheat cultivars like Nachit and Jabal, which maintain productivity under limited rainfall and nutrient availability. For , extensive grazing systems, including with multi-species pastures, leverage the land's potential without intensive inputs, supporting or sheep production on slopes or degraded areas. These approaches prioritize , with examples like the (SRI) for rainfed enabling wider spacing and organic amendments to boost root development on infertile plots. Yields on marginal lands typically range 10-20% lower than on prime farmlands for major crops like corn and soybeans, reflecting constraints such as shallower soils and variable moisture that limit accumulation. For instance, expanded croplands in the U.S., often on marginal sites, show corn yields below national averages, underscoring the productivity gap. Cost-benefit analyses for smallholder farmers indicate that adopting these techniques yields long-term gains, with SRI reducing input costs by 10-20% and increasing net profits through higher yields after initial labor investments, though upfront expenses and can delay returns. incentives, such as subsidies for practices, can further enhance economic viability for these farmers. Globally, similar techniques are applied in regions like , where on marginal lands integrates trees with crops to improve and yields for smallholders.

Non-Agricultural Utilization

Marginal lands offer viable opportunities for bioenergy production through the cultivation of perennial grasses such as switchgrass (Panicum virgatum) and miscanthus (Miscanthus × giganteus), which are well-suited to low-fertility, eroded, or otherwise suboptimal soils and thus avoid competition with prime agricultural areas for food crops. These crops require minimal inputs like fertilizers and can sustain productivity on sites with poor drainage or acidity, making them ideal for marginal conditions. Biomass yields typically range from 5 to 10 tons per acre annually for miscanthus under moderate management, while switchgrass achieves around 4 to 6 tons per acre, depending on regional climate and soil amendments. This approach not only generates renewable energy feedstocks but also improves soil health through deep root systems that reduce erosion. Beyond , marginal lands support initiatives aimed at , where tree planting on degraded or low-productivity sites captures atmospheric CO₂ while enhancing resilience. Studies indicate that afforesting marginal agricultural lands in the could offset 6-8% of regional emissions through long-term carbon storage in and soils. Species like Scots pine have demonstrated effective sequestration on marginal sites in , accumulating up to 100-150 tons of carbon per over 50-80 years. These projects leverage the low of such lands, transforming them into carbon sinks without displacing higher-value uses. Marginal lands also serve as habitats for wildlife conservation, where restoration practices establish native vegetation to support biodiversity and pollinator populations on sites unsuitable for intensive farming. Through programs like the U.S. Conservation Reserve Program (CRP), farmers enroll marginal acres to create pollinator-friendly prairies or wetland buffers, fostering habitats for species such as bobwhite quail and monarch butterflies while providing annual rental payments. Restored marginal farmlands can deliver ecosystem services including improved water quality and increased avian diversity, with studies showing higher bird species richness compared to active croplands. These efforts prioritize low-maintenance native plantings that align with the inherent limitations of marginal soils. Renewable energy infrastructure, such as photovoltaic arrays and turbines, increasingly utilizes marginal s due to their lower land values and reduced conflict with agricultural production. In the United States, about 11% of mainland land classified as marginal—including abandoned sites and eroded fields—is suitable for such developments, with potential on these areas alone exceeding national electricity consumption in 2022. Disturbed or contaminated marginal lands, like former brownfields, benefit from installations that shade soil, retain moisture, and prevent further degradation without requiring extensive remediation. projects on marginal rangelands similarly minimize disruption by spacing turbines to allow continued . For lands degraded by activities, reclamation strategies often convert marginal sites into recreational areas, restoring and to support public access and leisure uses. Post-mining reclamation has successfully transformed over 2.8 million acres since 1978 into parks, trails, and fishing ponds, mimicking pre-disturbance landscapes for activities like hiking and wildlife viewing. These efforts stabilize soils, revegetate with , and create accessible green spaces on formerly hazardous terrains, enhancing community benefits without reverting to . Such adaptations highlight the versatility of marginal lands in providing non-agricultural value through targeted .

Environmental and Economic Impacts

Ecological Consequences

Exploitation or neglect of marginal land exacerbates and degradation, particularly on terrains with inherent vulnerabilities such as steep slopes. When these lands are cultivated intensively or left barren, erosion rates can reach 10-20 tons per acre per year, far exceeding tolerable levels and accelerating the loss of fertility. This process contributes to , where productive land transforms into arid, unproductive expanses, diminishing stability and amplifying environmental risks like dust storms and reduced water retention. According to assessments by the , such degradation affects global ecosystems by altering and nutrient cycles, with marginal areas bearing disproportionate impacts due to their low . Biodiversity on marginal land exhibits a dynamic, serving as potential refugia for when unmanaged, yet suffering severe loss under . Uncultivated marginal areas, often characterized by poor and harsh conditions, can harbor unique and adapted to stress, acting as hotspots that buffer against broader landscape fragmentation. In contrast, converting these lands for or other uses destroys specialized habitats, leading to declines in endemic and reduced ecological . Disruptions to the and carbon cycles further compound the ecological toll of marginal land mismanagement. Accelerated increases , carrying sediments and pollutants into waterways, which elevates and contaminates aquatic habitats, impairing fish populations and algal balances. Simultaneously, soil degradation on these terrains diminishes capacity, as lost releases stored carbon into the atmosphere and reduces the land's ability to capture atmospheric CO2 through vegetation and microbial activity.

Socioeconomic Effects

Marginal lands play a significant role in sustaining smallholder farming globally, with approximately % of the world's rural population—many operating small farms—relying on these areas for livelihoods, often under conditions of low productivity and resource constraints. This dependence exacerbates , as smallholders on marginal lands face limited access to markets, , and inputs, trapping them in cycles of low yields and that affect an estimated 1.75 billion people, predominantly in developing countries. Consequently, these dynamics contribute to , as wealthier farmers in fertile regions benefit from higher returns, while those on marginal lands remain disproportionately poor, with rates reaching 36% among residents in such areas. High can incentivize the expansion of into marginal lands, as farmers bring low-yield areas into to capitalize on . However, this shift often involves higher input costs and diminished outputs compared to prime lands, leading to increased overall expenses that translate into sustained or elevated rather than significant relief from shortages. The marginal of these lands influences modern pricing by setting a lower for rents on less favorable soils, amplifying when supply expansions fail to match surges effectively. Farming on marginal lands requires substantial manual labor due to poor soil quality, erratic water availability, and the need for intensive practices to achieve viable yields, which drives rural-to-urban as workers seek higher-wage opportunities elsewhere. In , where marginal lands dominate much of the agricultural landscape, this contributes to deagrarianization, with studies indicating that low on such farms prompts significant outflows of young and able-bodied individuals to urban centers, reducing rural labor pools and further straining smallholder operations. For instance, in regions like East and , historical patterns of labor have intensified under these conditions, linking marginal land challenges directly to broader patterns of and rural depopulation.

Contemporary Issues and Examples

Climate Change Interactions

significantly alters the status of through rising temperatures and shifts in patterns, often rendering previously productive areas unsuitable for or other uses. The IPCC Special Report on and highlights that increased and more frequent droughts, driven by higher temperatures and erratic rainfall, exacerbate and processes with high confidence. Projections indicate that the extent of dryness influencing exchange in could expand by at least 8% by 2050 under continued trends, affecting up to 1.3 billion people in vulnerable regions through heightened water stress and habitat loss. These changes push into already marginal zones, further straining ecosystems. A critical interaction involves feedback loops where degradation of marginal lands amplifies . Degraded soils on marginal lands release stored carbon into the atmosphere as and other greenhouse gases, while reducing the land's capacity for , creating a vicious cycle that intensifies impacts. The IPCC assesses with very high confidence that drives via these emissions and diminished uptake rates, contributing around 2% of global GHG emissions (low confidence), exacerbating the 23% from the broader , forestry, and other sector. This is particularly pronounced in , where and vegetation loss from erratic rainfall accelerate carbon release, underscoring the bidirectional relationship between marginal land conditions and atmospheric warming. The IPCC's Sixth Assessment Report (AR6, ) further projects that dryland expansion could affect additional billions under high-emission scenarios, intensifying risks to and ecosystems as of 2025. To mitigate these interactions, adaptation strategies such as play a pivotal role in preventing further land marginalization. This approach involves designating based on projected risks, restricting in high-vulnerability areas like flood-prone or drought-susceptible zones, and promoting sustainable practices on marginal lands to enhance . For instance, resilience zoning in coastal regions has demonstrated effectiveness in avoiding economic losses from sea-level rise while preserving ecosystem services, as evidenced by implementations in areas like . The IPCC emphasizes that integrating such zoning with sustainable can reduce degradation risks in targeted areas, fostering long-term stability amid climate variability.

Global Case Studies

In the United States , marginal lands characterized by semi-arid conditions and fragile soils were increasingly converted to farming in the early to meet rising demand, but this practice exacerbated vulnerability to drought and wind erosion. During the 1930s era, prolonged droughts from 1930 to 1940 stripped topsoil from over 100 million acres across states like , , and , creating massive dust storms that buried homes, ruined crops, and forced the migration of approximately 2.5 million people from the Dust Bowl states, including about 300,000–500,000 "Okies" from to . The crisis highlighted the risks of cultivating marginal lands without conservation measures, leading to the creation of the Soil Conservation Service in 1935 under the Soil Conservation Act, which promoted , , and retirement of erosion-prone areas to restore and prevent future disasters. In the of , stretching across countries like , , and , semi-arid marginal lands with low rainfall and poor support traditional as the primary for millions of herders managing such as , goats, and sheep. These vast , covering about 3 million square kilometers, rely on mobile herding to access seasonal , but population growth and climate variability have intensified pressures, degrading vegetation and contributing to that affects up to 80% of the region's . Recent droughts from 2022 to 2025 have worsened and displacement, affecting millions amid ongoing conflicts. Efforts to address these challenges include community-based management programs by organizations like the FAO, which promote and between pastoralists and expanding crop farmers to sustain ecological balance. The exemplify marginal land use in , where rugged, acidic soils and harsh weather limit to extensive , a practice dominant since the 18th and 19th centuries following the . During these clearances from the 1760s to 1850s, landlords evicted tenant farmers to consolidate land for profitable and sheep breeds, which could thrive on poor pastures but required fewer laborers, resulting in the depopulation of remote glens and the of over 100,000 people to and . This shift not only transformed the socioeconomic landscape but also perpetuated rural decline trends into the , with still occupying about 55% of Scotland's despite ongoing challenges from low profitability and aging populations.

References

  1. [1]
    [PDF] Marginal lands - FAO Knowledge Repository
    Marginal lands, 21% of global land, have potential for agricultural development, food security, and poverty reduction, but 38% of rural populations live in ...
  2. [2]
    None
    ### Summary of Marginal Agricultural Land from the Document
  3. [3]
    [PDF] Marginal Lands: Concept, Assessment and Management
    Apr 15, 2013 · Marginal lands are the poorest lands used above the margin of rent-paying land, or where cost-effective production is not possible.
  4. [4]
    Cashing In On Marginal Lands | Tellus - USDA
    “We believe marginally productive land is best defined by its economic parameters,” Mitchell said. “A good working definition for the western Corn Belt is ...
  5. [5]
    What makes up marginal lands and how can it be defined and ...
    To the category of "marginal" lands are predominantly included lands which are excluded from cultivation due to economic infeasibility or physical restriction.
  6. [6]
    Redefining marginal land for bioenergy crop production
    We then propose the concept of “socially” marginal which is defined as land that is earning close to zero returns after accounting for the monetized costs of ...
  7. [7]
    Cattle and Land Use: The Differences between Arable Land and ...
    Jan 17, 2023 · Marginal land, also known as pasture land and grassland, is an area that receives little to no water, has low quality soils, high mountains and ...
  8. [8]
    Md. Code Regs. 15.18.04.01 - Definitions | State Regulations | US Law
    (a) "Marginal land" means land where the soil characteristics do not support normal vegetative growth over time. (b) "Marginal land" includes, but is not ...
  9. [9]
    Sec. 103F.511 MN Statutes
    Subd.​​ "Marginal agricultural land" means land that is: (1) composed of class IIIe, IVe, V, VI, VII, or VIII land as identified in the land capability ...
  10. [10]
    https://clear.ucdavis.edu/explainers/cattle-and-land-use-differences-between-arable-land-and-marginal-land-and-how-cattle-use
  11. [11]
    Farmland Leases: Truths, Part-Truths, and Un-Truths
    Aug 18, 1997 · In fact this could be the definition of marginal land, where the revenues will just pay for the costs of cropping. If the likely operator ...
  12. [12]
    [PDF] Marginal lands: Concept, classification criteria and management
    Physical and production definition: Marginality is based on soil suitability with restrictions often being adopted by soil scientists and agronomists for the ...
  13. [13]
    Concepts of agricultural marginal lands and their utilisation: A review
    Marginal lands are characterised by poor climate, poor physical characteristics, or difficult cultivation. They include areas with limited rainfall, extreme ...
  14. [14]
    [PDF] LAND-CAPABILITY CLASSIFICATION - GovInfo
    ' Certain soils grouped into classes V, VI, VII, and VIII may be made fit for use for crops with major earthmoving or other costly reclamation. 9. Page 14 ...Missing: marginal | Show results with:marginal
  15. [15]
    [PDF] ECONOMIC RENT and OPPORTUNITY COST David Ricardo (1772 ...
    THE RICARDO MODEL OF ECONOMIC RENT. IN GRAIN PRODUCTION. Prices and Costs (Y axis). Last unit of marginal land called into production. D10. P10. P6. D1. P1.
  16. [16]
    The Ricardian Theory of Rent (With Diagram) - Economics Discussion
    According to Ricardo, rent of land arises because the different plots of land ... Since the third plot GJ has no surplus it is marginal land or no-rent land.
  17. [17]
    Thomas Robert Malthus and David Ricardo
    Both used Malthus' theory of rent. Both recognized that the rate of profit in agriculture was determined by the productivity of the marginal land cultivated, ...Missing: pressures | Show results with:pressures
  18. [18]
    https://www.economics.utoronto.ca/munro5/ECONRENT.pdf
  19. [19]
    (PDF) Mr. Ricardo's Theory of Land Rent - ResearchGate
    This paper is an introduction to and extension of Ricardo's theory of land rent. The paper also presents the basic Ricardian system.
  20. [20]
    NRCS History | Natural Resources Conservation Service
    The result was the Soil Conservation Act (PL 74-46), which President Roosevelt signed on April 27, 1935, creating the Soil Conservation Service (SCS) in the ...Missing: submarginal | Show results with:submarginal
  21. [21]
    https://academic.depauw.edu/~hbarreto/courses/HistEcon/Ricardo/RicardoPaper.pdf
  22. [22]
    The global energy challenge: second-generation feedstocks on ...
    Jan 17, 2025 · It is proposed to cultivate second-generation biofuel crops on marginal lands, since this option could bring benefits in terms of food security and ...
  23. [23]
    Biofueling Our Future with Agriculture - USDA ARS
    Jan 10, 2025 · For instance, plant biomass in the form of perennial grasses can be grown on marginal land and will not compete with land used for food ...Missing: 2020s mandates targeting
  24. [24]
    Techno-economic assessment of bioenergy potential on marginal ...
    This research analyzes how well an energy policy can integrate land resources including marginal lands for cultivating cellulosic biomass to produce biofuel.Missing: 2020s | Show results with:2020s<|control11|><|separator|>
  25. [25]
    Miscanthus: An Environmental Choice for Marginal Lands
    In one study, switchgrass (Panicum virgatum) yielded 10.3 Mg/ha of biomass on average, while miscanthus yielded 22.4 Mg/ha (Heaton et al. 2004).
  26. [26]
    [PDF] Adaptation of C4 Bioenergy Crop Species to Various Environments ...
    Jan 11, 2017 · Switchgrass and M. x giganteus are C4 warm-season grasses capable of fast growth and steady high yield production in marginal locations not ...
  27. [27]
    [PDF] SWITCHGRASS AND MISCANTHUS YIELDS ON RECLAIMED ...
    Both Miscanthus and switchgrass are able to produce high yields of biomass with low fertility requirements and are viable options for post-mining land uses ...
  28. [28]
    Carbon sequestration potential by afforestation of marginal ...
    Mar 1, 2006 · The results indicate that afforestation of MagLand could offset 6-8% of current CO2 emissions by combustion of fossil fuel in the region. This ...
  29. [29]
    Carbon sequestration after pine afforestation on marginal lands in ...
    The purpose of this case study was to investigate the potential for carbon sequestration from such projects. The study covers afforestation with Scots pine on ...Missing: credible | Show results with:credible
  30. [30]
    Afforestation and Reforestation of Degraded Lands - ACR Carbon
    Afforestation and reforestation (A/R) on degraded lands removes CO2, mitigates climate change, and provides ecosystem benefits. Trees sequester carbon as they ...Missing: credible | Show results with:credible
  31. [31]
    How Precision Conservation Transformed a Farm's Marginal Land ...
    Feb 27, 2025 · The final plan included 13 acres of marginal land placed into the Conservation Reserve Program as habitat where it will earn annual CRP rental ...
  32. [32]
    Ecosystem services on restored marginal farmland - MacDougall
    Jul 28, 2025 · Industrialized agriculture often uses marginal-land restoration to reduce environmental impacts, seeking to generate ecosystem services ...
  33. [33]
    [PDF] Thriving With Marginal Land - Purdue Extension
    This is an organic, protected, biodiverse habitat for pollinators, butterflies, and wildlife. It's also a farm. Somebody. Loves. This. Field!
  34. [34]
    Renewable energy potential on marginal lands in the United States
    This study identifies several marginal land categories suitable for renewable energy development, representing about 11% of US mainland.
  35. [35]
    Is Utility-Scale Solar Stealing Our Food? Think Again.
    Oct 24, 2024 · ... lands. Solar development alone on marginal lands was estimated to have the potential to produce more electricity than the U.S. consumed in 2022.
  36. [36]
    https://practicalfarmers.org/2025/02/how-precision-conservation-transformed-a-farms-marginal-land-into-valuable-habitat/
  37. [37]
    Reclamation Archives - National Mining Association
    Since 1978, more than 2.8 million acres of mined lands have been restored for wildlife areas and wetlands, recreation areas, economic ...Missing: marginal | Show results with:marginal
  38. [38]
    Reclamation and Restoration of Abandoned Mineral Lands
    Dec 3, 2021 · Reclamation in the National Park System focuses on reestablishing landscapes and environments that mimic the surrounding undisturbed lands.Missing: marginal | Show results with:marginal
  39. [39]
    [PDF] Land Reclamation - Scholars' Mine
    In most cases, land used for mining is marginal or sub-marginal land which has been and will be restored to forest, grazing lands, orchards, wildlife habitat, ...
  40. [40]
    [PDF] Soil Conservation Issues on the United States - NSERL
    Of these 5 million acres, 4 million acres had inadequate erosion control. Soil erosion rates were over 12 tons per acre per year. Some losses reached 25 tons ...
  41. [41]
    Marginal Land - an overview | ScienceDirect Topics
    Increased desertification, resulting from climate change and agriculturally marginal land degradation, and increased urbanization and sprawl continue to limit ...
  42. [42]
    Chapter 4 : Land Degradation
    Land degradation affects people and ecosystems throughout the planet and is both affected by climate change and contributes to it.
  43. [43]
    [PDF] Biocultural Refugia: Combating the Erosion of Diversity in ...
    It would seem that leaving such marginal lands fallow would increase biodiversity, but ... The heartiest of these domesticated species adapted over millennia to ...
  44. [44]
    Cropland redistribution to marginal lands undermines environmental ...
    Our research suggests that globally emerging reclamation of marginal lands should be restricted and crop yield boost should be encouraged for both food security ...
  45. [45]
    The Causes and Effects of Soil Erosion, and How to Prevent It
    Feb 7, 2020 · Erosion degrades land, which means it can support fewer plants that can take in climate-warming carbon dioxide. Soils themselves could ...Filter Your Site Experience... · Why Is Soil Erosion Such A... · 1. Use Soil-Friendly...
  46. [46]
    Soil erosion and agricultural sustainability - PMC - NIH
    ... T values, against which to evaluate “acceptable” rates of soil erosion. Generally, soil conservation programs consider T values to be ≈5–12 tons/hectare per ...Missing: marginal uncultivated acre
  47. [47]
    Policies for Sustainable Agriculture and Livelihood in Marginal Lands
    Aug 4, 2021 · Marginal lands account for about 36 percent of global agricultural land ... world's rural population lives in marginal areas; most are the poor ...
  48. [48]
    What's at stake when we pave over, fragment and otherwise fail to ...
    May 21, 2020 · American Farmland Trust's new report demonstrates how developing farmland puts food security, the environment and our way of life in jeopardy.Missing: cultivation | Show results with:cultivation
  49. [49]
    (PDF) Rising farm costs, marginal land cropping, and ecosystem service markets
    ### Summary: Impact of Expanding to Marginal Land During Shortages on Food Prices and Markets
  50. [50]
    https://www.mdpi.com/2071-1050/13/16/8692
  51. [51]
    The Role of Rural–Urban Migration in the Structural Transformation ...
    Rural-to-urban migration is an inherent part of the economic development process, yet it is relatively understudied in sub-Saharan Africa.
  52. [52]
    [PDF] AGRARIAN LABOUR AND RESOURCES IN SUB-SAHARAN AFRICA:
    Overviewing trends during 35 years of Sub-Saharan African rural change and accelerating deagrarianiza- tion, this paper traces the restructuring of rural ...
  53. [53]
    [PDF] Rural migration in sub-Saharan Africa - FAO Knowledge Repository
    First, rural households diversify their employment and income strategies engaging in a multiple range of non−farm activities that used to be part of the urban.
  54. [54]
    Special Report on Climate Change and Land — IPCC site
    An IPCC Special Report on climate change, desertification, land degradation, sustainable land management, food security, and greenhouse gas fluxes in ...Land Degradation · Summary for Policymakers · Technical Summary · Food Security
  55. [55]
    https://www.ipcc.ch/srccl/
  56. [56]
    Exploring How Land-Based Approaches to Climate Change ...
    Aug 8, 2023 · This report examines the economic and social impact of resilience zoning in Norfolk, Virginia, which offers a cutting-edge example of climate- ...Missing: marginal | Show results with:marginal
  57. [57]
    The Dust Bowl | National Drought Mitigation Center
    Due to low crop prices and high machinery costs, more submarginal lands were put into production. Farmers also started to abandon soil conservation practices.Drought · Great Depression · Cause · RecoveryMissing: marginal | Show results with:marginal
  58. [58]
    [PDF] The Enduring Impact of the American Dust Bowl: Short- and Long ...
    The newly formed Soil Conservation Service (SCS) encouraged farmers to shift land from wheat and other row crops into hay and pasture, where productivity was.
  59. [59]
    Dust Bowl Lessons: Science, Policy, Adaptation - PMC
    An important outcome of the 1930s socio-ecological crisis on the Great Plains was a greatly expanded participation of government in land management and soil ...
  60. [60]
    [PDF] Pastoralism in Sub-Saharan Africa: Know its Advantages ...
    At a time when pastoral communities are going through a multitude of crises (drought, spoliation of natural and land resources, conflicts between farmers and ...
  61. [61]
    [PDF] Overgrazing and Range Degradation in Africa: - UC Davis
    Jun 19, 2014 · Considerable grazing land has been removed from the traditional range system during this century, to provide European colonists with land, to ...Missing: challenges | Show results with:challenges
  62. [62]
    [PDF] Pastoral Strategies in Sub-Saharan Africa - World Bank Document
    First, the paper asks what characterizes traditional range management strategies, and in what sense such strategies may be said to be opportunistic. Second, the ...Missing: challenges | Show results with:challenges
  63. [63]
    [PDF] Use or delight? History of conflicting hill land uses in Scotland
    Jan 1, 2015 · Although rural Scotland only accommodates 19% of the total population, it occupies 94% of the Scottish land mass. (Scottish Government, 2009).<|control11|><|separator|>
  64. [64]
    [PDF] Hildebrandt, Ruth Nancy (1980) Migration and economic change in ...
    History of the Highland Clearances, Ope cit., pp. 43-4. 118. Page 135. Because of the potential of the terrain and the better communications with the farming ...
  65. [65]
    [PDF] THE REAL CRISIS OF SCOTTISH AGRICULTURE
    Above all, the depression severely affected the viability of hill sheep farming, particularly in the Highlands where the glens, having already been emptied of ...