Constructed soil

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Constructed soils (also called fabricated soils) are mixtures of organic and mineral material derived from a number of sources, including repurposed organic waste, that are designed to approximate natural soils and provide a growing medium for plants. [1] Constructed soils are commonly used in the reclamation of degraded land where natural topsoil is either not present or has been contaminated. Examples of these sites include mines, landfills, and other industrial or urban areas. [2] Constructed soils are classified as Technosols, and often form the upper layer, or layers, in a Technosol above a geomembrane or other barrier capping waste material. [3]

Contents

Use of constructed soils in restoring sites is preferable to importing topsoil from other locations. Topsoil harvesting means a second location will be degraded, and collection and transport expenses will generally be higher than using local materials to create a new soil. Soil that was removed and stockpiled (e.g. during the operation of a mine), can become part of a constructed soil once a site is being reclaimed. [4]

The goal in designing a constructed soil is to replicate the physical, chemical, and biological functions of natural soils. The target soil properties depend on the site location and final land use. Constructed soils are intended to be as low-maintenance as possible, [2] meaning they will be a stable and functional system over time that does not need additional inputs once biogeochemical cycling is established.

Where applicable, constructed soils must meet regulatory requirements dictating the acceptable thresholds of certain soil characteristics. Pathogens, harmful trace elements, salinity, and pH must be at values that are not harmful to human or environmental health. [5] Specific values for the balance of soil nutrients, including proportion of organic matter, carbon to nitrogen ratio, and total nitrogen, may also be required to ensure prolonged soil functioning. [6]

Constructed soil profiles

Soils naturally develop differentiated horizons, where the soil properties change with depth in a soil profile. Constructed soils that are less than approximately 45 cm thick will tend to be homogenous topsoil mixtures. [2] For thicker applications of constructed soils, natural soil profiles can be emulated and there are advantages to doing so. The most basic reason is that constructed topsoil is expensive to produce. Lower quality and less expensive materials can be used for subsoil and substratum layers. Additional layers can also improve the functioning of the soil. Thicker horizons below the topsoil increase the volume of soil available to plant roots and can be an additional nutrient source. Sublayers are also important to the regulation of water in the soil and can be used to improve or control drainage, which is critical on reclamation sites where leaching of toxic materials below the constructed soil is a concern.

When constructing a complete soil profile, the interfaces between the layers must be considered as well as the composition of each layer. Abrupt differences in soil properties at horizon boundaries (namely texture and bulk density) impacts the hydraulic functioning of a soil, determining the extent of lateral versus vertical flow and the presence of perched water in the soil. [7] Compact layers with little pore space can also impede root growth. In some situations, clay-rich layers that act as aquitards and deflect roots are used intentionally as barriers at the base of constructed soil profiles. [8] In sloped areas, the friction between the layers must be considered to minimize soil erosion and reduce the chance of slope failure. Soils with high water-holding capacity are also at risk of slumping (erosion by mass-wasting) if placed on slopes in wet climates.

Diagram of a generic natural soil profile, with O, A, B and C horizons. Generalized Soil Profile.png
Diagram of a generic natural soil profile, with O, A, B and C horizons.
Comparison of Natural and Constructed Soil Profiles
Natural Soil HorizonsConstructed Soil
O: organic layerOrganic mulch application to protect topsoil and provide habitat and nutrients to soil organisms (excluded in projects with rapid revegetation
A: surface or topsoilManufactured topsoil that serves as the primary rooting medium; high fertility; carefully designed to meet specific requirements
B: subsoil or mineral soilBulk material to add rooting volume and increase nutrient and water storage capacity; requirements are less strict
C: substratum (parent materialDrainage layer with high porosity and high density (sand or gravel); no organic matter; thickness determined by drainage requirements

Components of constructed soils

Constructed soils generally consist of three components: a mineral fraction, organic fraction, and carbon source. [2] [9] Each contributes different features to the soil. Selection of the individual materials making up each component depends on the specific objectives and parameters of a constructed soil project. The ratios of these components are determined by the target outcomes as well as considerations like cost and availability of materials, and how the components act when mixed. Not all options will combine well into a uniform soil mixture.

Mineral fraction

The mineral fraction forms the matrix of the soil, determining the final texture (relative percentages of sand, silt, and clay). The texture and proportion of mineral material determines the soil aeration and drainage and influences the soil structure. Beyond the size, physical properties such as the roundness of sand particles can also influence the packing of grains, changing the pore size distribution. Texture and angularity of grains also impacts the shear strength of a soil. [10] The mineralogy of this material determines how quickly the soil will weather when subjected to the environment and which elements will be released, changing the physical and chemical characteristics of the soil over time. [7]

Organic fraction

The organic material fraction consists of decomposed or partially decomposed organic matter. It is necessary to provide essential macronutrients and micronutrients to plants and soil organisms. This material commonly has a high water-content and high water-holding capacity. In topsoil, organic matter should not exceed 15% by weight, or approximately one-third of soil particles. [6] Above this limit, the soil will become prone to settlement, consolidation, and waterlogging. If soil remains waterlogged over an extended period of time, the soil will become anoxic, killing most plants and many soil organisms. [2] The selection of organic amendments can significantly influence the resulting soil properties and soil quality. [11]

Carbon fraction

In constructed soils, the carbon source is distinguished from the organic component as it is made up of materials that will decompose slowly, providing organic matter over time. Carbon is essential to the mediation of the organic matter decomposition rate in soils. A moderate carbon-to-nitrogen ratio (C:N ~ 20:1) will keep this rate at a level that provides a sustained release of nutrients into the soil. [12] This material also influences water retention in the soil.

Examples of Constructed Soil Materials
MineralOrganicCarbon
sand
silt
clay
gravel 		compost
peat
manure
biosolids 		sawdust
wood pulp
wood chips
tree bark
biochar
straw

Biological component

Soil, by definition, includes living organisms. [13] However, constructed soils do not typically include this factor in the development of soil mixtures. It is expected that biotic processes will initiate themselves as a site revegetates and soil formation (pedogenesis) begins. [2] Biotic processes are critical in the aggregation of soil particles and development of stable soil structure, [7] something which constructed soils typically lack. The selection of plants for revegetation will impact the soil biome progression. There have also been recent developments in inoculating the soil with specific organisms through methods like direct vegetation transfer. [14] Improved understanding of soil quality in stockpiles over time also has the potential to increase the retention of soil microorganisms. [15]

Related Research Articles

<span class="mw-page-title-main">Humus</span> Organic matter in soils resulting from decay of plant and animal materials

In classical soil science, humus is the dark organic matter in soil that is formed by the decomposition of plant and animal matter. It is a kind of soil organic matter. It is rich in nutrients and retains moisture in the soil. Humus is the Latin word for "earth" or "ground".

<span class="mw-page-title-main">Soil</span> Mixture of organic matter, minerals, gases, liquids, and organisms that together support life

Soil, also commonly referred to as earth or dirt, is a mixture of organic matter, minerals, gases, liquids, and organisms that together support the life of plants and soil organisms. Some scientific definitions distinguish dirt from soil by restricting the former term specifically to displaced soil.

Soil formation, also known as pedogenesis, is the process of soil genesis as regulated by the effects of place, environment, and history. Biogeochemical processes act to both create and destroy order (anisotropy) within soils. These alterations lead to the development of layers, termed soil horizons, distinguished by differences in color, structure, texture, and chemistry. These features occur in patterns of soil type distribution, forming in response to differences in soil forming factors.

<span class="mw-page-title-main">Topsoil</span> Top layer of soil

Topsoil is the upper layer of soil. It has the highest concentration of organic matter and microorganisms and is where most of the Earth's biological soil activity occurs.

The pedosphere is the outermost layer of the Earth that is composed of soil and subject to soil formation processes. It exists at the interface of the lithosphere, atmosphere, hydrosphere and biosphere. The pedosphere is the skin of the Earth and only develops when there is a dynamic interaction between the atmosphere, biosphere, lithosphere and the hydrosphere. The pedosphere is the foundation of terrestrial life on Earth.

Organic matter, organic material, or natural organic matter refers to the large source of carbon-based compounds found within natural and engineered, terrestrial, and aquatic environments. It is matter composed of organic compounds that have come from the feces and remains of organisms such as plants and animals. Organic molecules can also be made by chemical reactions that do not involve life. Basic structures are created from cellulose, tannin, cutin, and lignin, along with other various proteins, lipids, and carbohydrates. Organic matter is very important in the movement of nutrients in the environment and plays a role in water retention on the surface of the planet.

<span class="mw-page-title-main">Podzol</span> Typical soils of coniferous or boreal forests

In soil science, podzols, also known as podosols, spodosols, or espodossolos, are the typical soils of coniferous or boreal forests and also the typical soils of eucalypt forests and heathlands in southern Australia. In Western Europe, podzols develop on heathland, which is often a construct of human interference through grazing and burning. In some British moorlands with podzolic soils, cambisols are preserved under Bronze Age barrows.

Tilth is a physical condition of soil, especially in relation to its suitability for planting or growing a crop. Factors that determine tilth include the formation and stability of aggregated soil particles, moisture content, degree of aeration, soil biota, rate of water infiltration and drainage. Tilth can change rapidly, depending on environmental factors such as changes in moisture, tillage and soil amendments. The objective of tillage is to improve tilth, thereby increasing crop production; in the long term, however, conventional tillage, especially plowing, often has the opposite effect, causing the soil carbon sponge to oxidize, break down and become compacted.

A soil horizon is a layer parallel to the soil surface whose physical, chemical and biological characteristics differ from the layers above and beneath. Horizons are defined in many cases by obvious physical features, mainly colour and texture. These may be described both in absolute terms and in terms relative to the surrounding material, i.e. 'coarser' or 'sandier' than the horizons above and below.

<span class="mw-page-title-main">World Reference Base for Soil Resources</span> International soil classification system

The World Reference Base for Soil Resources (WRB) is an international soil classification system for naming soils and creating legends for soil maps. The currently valid version is the fourth edition 2022. It is edited by a working group of the International Union of Soil Sciences (IUSS).

Claypan is a dense, compact, slowly permeable layer in the subsoil. It has a much higher clay content than the overlying material, from which it is separated by a sharply defined boundary. The dense structure restricts root growth and water infiltration. Therefore, a perched water table might form on top of the claypan. In the Canadian classification system, claypan is defined as a clay-enriched illuvial B (Bt) horizon.

<span class="mw-page-title-main">Detritus</span> Dead particulate organic material

In biology, detritus is dead particulate organic material, as distinguished from dissolved organic material. Detritus typically includes the bodies or fragments of bodies of dead organisms, and fecal material. Detritus typically hosts communities of microorganisms that colonize and decompose it. In terrestrial ecosystems it is present as leaf litter and other organic matter that is intermixed with soil, which is denominated "soil organic matter". The detritus of aquatic ecosystems is organic substances that is suspended in the water and accumulates in depositions on the floor of the body of water; when this floor is a seabed, such a deposition is denominated "marine snow".

In biogeochemistry, remineralisation refers to the breakdown or transformation of organic matter into its simplest inorganic forms. These transformations form a crucial link within ecosystems as they are responsible for liberating the energy stored in organic molecules and recycling matter within the system to be reused as nutrients by other organisms.

Soil chemistry is the study of the chemical characteristics of soil. Soil chemistry is affected by mineral composition, organic matter and environmental factors. In the early 1870s a consulting chemist to the Royal Agricultural Society in England, named J. Thomas Way, performed many experiments on how soils exchange ions, and is considered the father of soil chemistry. Other scientists who contributed to this branch of ecology include Edmund Ruffin, and Linus Pauling.

Soil organic matter (SOM) is the organic matter component of soil, consisting of plant and animal detritus at various stages of decomposition, cells and tissues of soil microbes, and substances that soil microbes synthesize. SOM provides numerous benefits to the physical and chemical properties of soil and its capacity to provide regulatory ecosystem services. SOM is especially critical for soil functions and quality.

<span class="mw-page-title-main">Soil carbon</span> Solid carbon stored in global soils

Soil carbon is the solid carbon stored in global soils. This includes both soil organic matter and inorganic carbon as carbonate minerals. It is vital to the soil capacity in our ecosystem. Soil carbon is a carbon sink in regard to the global carbon cycle, playing a role in biogeochemistry, climate change mitigation, and constructing global climate models. Natural variation such as organisms and time has affected the management of carbon in the soils. The major influence has been that of human activities which has caused a massive loss of soil organic carbon. An example of human activity includes fire which destroys the top layer of the soil and the soil therefore get exposed to excessive oxidation.

<span class="mw-page-title-main">Soil regeneration</span> Creation of new soil and rejuvenation of soil health

Soil regeneration, as a particular form of ecological regeneration within the field of restoration ecology, is creating new soil and rejuvenating soil health by: minimizing the loss of topsoil, retaining more carbon than is depleted, boosting biodiversity, and maintaining proper water and nutrient cycling. This has many benefits, such as: soil sequestration of carbon in response to a growing threat of climate change, a reduced risk of soil erosion, and increased overall soil resilience.

<span class="mw-page-title-main">Particulate organic matter</span>

Particulate organic matter (POM) is a fraction of total organic matter operationally defined as that which does not pass through a filter pore size that typically ranges in size from 0.053 millimeters (53 μm) to 2 millimeters.

The soil matrix is the solid phase of soils, and comprise the solid particles that make up soils. Soil particles can be classified by their chemical composition (mineralogy) as well as their size. The particle size distribution of a soil, its texture, determines many of the properties of that soil, in particular hydraulic conductivity and water potential, but the mineralogy of those particles can strongly modify those properties. The mineralogy of the finest soil particles, clay, is especially important.

Seventeen elements or nutrients are essential for plant growth and reproduction. They are carbon (C), hydrogen (H), oxygen (O), nitrogen (N), phosphorus (P), potassium (K), sulfur (S), calcium (Ca), magnesium (Mg), iron (Fe), boron (B), manganese (Mn), copper (Cu), zinc (Zn), molybdenum (Mo), nickel (Ni) and chlorine (Cl). Nutrients required for plants to complete their life cycle are considered essential nutrients. Nutrients that enhance the growth of plants but are not necessary to complete the plant's life cycle are considered non-essential, although some of them, such as silicon (Si), have been shown to improve nutrent availability, hence the use of stinging nettle and horsetail macerations in Biodynamic agriculture. With the exception of carbon, hydrogen and oxygen, which are supplied by carbon dioxide and water, and nitrogen, provided through nitrogen fixation, the nutrients derive originally from the mineral component of the soil. The Law of the Minimum expresses that when the available form of a nutrient is not in enough proportion in the soil solution, then other nutrients cannot be taken up at an optimum rate by a plant. A particular nutrient ratio of the soil solution is thus mandatory for optimizing plant growth, a value which might differ from nutrient ratios calculated from plant composition.

References

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