Soil structure

In geotechnical engineering, soil structure describes the arrangement of the solid parts of the soil and of the pore space located between them. It is determined by how individual soil granules clump, bind together, and aggregate, resulting in the arrangement of soil pores between them. Soil has a major influence on water and air movement, biological activity, root growth and seedling emergence. There are several different types of soil structure. It is inherently a dynamic and complex system that is affected by different factors.

Overview

Soil structure describes the arrangement of the solid parts of the soil and of the pore spaces located between them (Marshall & Holmes, 1979).

hydrophobic

bonding).

The quality of soil structure will decline under most forms of

oxidation.^[3] A further consequence of continued cultivation and traffic is the development of compacted

, impermeable layers or 'pans' within the profile.

The decline of soil structure under

cations attached to the clays. High sodium levels (compared to high calcium

levels) cause particles to repel one another when wet, and the associated aggregates to disaggregate and disperse. The ESP will increase if irrigation causes salty water (even of low concentration) to gain access to the soil.

A wide range of practices are undertaken to preserve and improve soil structure. For example, the NSW Department of Land and Water Conservation advocates: increasing organic content by incorporating pasture phases into cropping rotations; reducing or eliminating tillage and cultivation in cropping and pasture activities; avoiding soil disturbance during periods of excessive dry or wet when soils may accordingly tend to shatter or smear; and ensuring sufficient ground cover to protect the soil from raindrop impact. In irrigated agriculture, it may be recommended to: apply gypsum (calcium sulfate) to displace sodium cations with calcium and so reduce ESP or sodicity, avoid rapid wetting, and avoid disturbing soils when too wet or dry.^[4]

Types

Platy – The units are flat and platelike. They are generally oriented horizontally.^[5]

Prismatic – The individual units are bounded by flat to rounded vertical faces. Units are distinctly longer vertically, and the faces are typically casts or molds of adjoining units. Vertices are angular or subrounded; the tops of the prisms are somewhat indistinct and normally flat.^[5]

Columnar – The units are similar to prisms and bounded by flat or slightly rounded vertical faces. The tops of columns, in contrast to those of prisms, are very distinct and normally rounded.^[5]

Blocky – The units are blocklike or polyhedral. They are bounded by flat or slightly rounded surfaces that are casts of the faces of surrounding peds. Typically, blocky structural units are nearly equidimensional but grade to prisms and plates. The structure is described as angular blocky if the faces intersect at relatively sharp angles and as subangular blocky if the faces are a mixture of rounded and plane faces and the corners are mostly rounded.^[5]

Granular – The units are approximately spherical or polyhedral. They are bounded by curved or very irregular faces that are not casts of adjoining peds.^[5]

Wedge – The units are approximately elliptical with interlocking lenses that terminate in acute angles. They are commonly bounded by small slickensides.^[5]

Lenticular —The units are overlapping lenses parallel to the soil surface. They are thickest in the middle and thin towards the edges. Lenticular structure is commonly associated with moist soils, texture classes high in silt or very fine sand (e.g., silt loam), and high potential for frost action.^[5]

Improving soil structure

The benefits of improving soil structure for the growth of plants, particularly in an agricultural setting, include: reduced erosion due to greater soil aggregate strength and decreased overland flow; improved root penetration and access to soil moisture and nutrients; improved emergence of seedlings due to reduced crusting of the surface; and greater water infiltration, retention and availability due to improved porosity.

Productivity from irrigated no-tillage or minimum tillage soil management in horticulture usually decreases over time due to degradation of the soil structure, inhibiting root growth and water retention. There are a few exceptions, why such exceptional fields retain structure is unknown, but it is associated with high organic matter. Improving soil structure in such settings can increase yields significantly.^[6] The NSW Department of Land and Water Conservation suggests that in cropping systems, wheat yields can be increased by 10 kg/ha for every extra millimetre of rain that is able to infiltrate due to soil structure.^[4]

Hardsetting soil

Hardsetting soils lose their structure when wet and then set hard as they dry out to form a structureless mass that is very difficult to cultivate. They can only be tilled when their moisture content is within a limited range. When they are tilled the result is often a very cloddy surface (poor tilth). As they dry out the high soil strength often restricts seedling and root growth. Infiltration rates are low and runoff of rain and irrigation limits the productivity of many hardsetting soils.^[7]

Definition

Hardsetting has been defined this way: "A hardsetting soil is one that sets to an almost homogeneous mass on drying. It may have occasional cracks, typically at a spacing of >0.1 m. Air dry hardset soil is hard and brittle, and it is not possible to push a forefinger into the profile face. Typically, it has a tensile strength of 90 kN^–2. Soils that crust are not necessarily hardsetting since a hardsetting horizon is thicker than a crust. (In cultivated soils the thickness of the hardsetting horizon is frequently equal to or greater than that of the cultivated layer.) Hardsetting soil is not permanently cemented and is soft when wet. The clods in a hardsetting horizon that has been cultivated will partially or totally disintegrate upon wetting. If the soil has been sufficiently wetted, it will revert to its hardset state on drying. This can happen after flood irrigation or a single intense rainfall event."^[8]

Soil structure dynamics

Soil structure is inherently a

thermal conductivity and electrical conductivity, traffic bearing capacity, and many other aspects in relation with soil. Ignoring soil structure or viewing it as "static" can lead to poor predictions of soil properties and might significantly affect the soil management.^[9]

References

^
doi:10.1016/0167-1987(88)90002-5
.

PMID 26783947
.

^ Young, A & Young R 2001, Soils in the Australian landscape, Oxford University Press, Melbourne. ^{[page needed]}

^ ^a ^b Department of Land and Water Conservation 1991, "Field indicators of soil structure decline" Archived 2007-09-14 at the Wayback Machine, viewed May 2007

^ ^a ^b ^c ^d ^e ^f ^g C. Ditzler; K. Scheffe; H.C. Monger, eds. (2017). "Examination and Description of Soil Profiles §Soil structure". USDA Soil Survey Manual. Washington, D.C.: Government Printing Office. Archived from the original on 2018-09-07. Retrieved 2 November 2019.

doi:10.1071/SR99079
.

doi:10.1071/SR11102
.

ISBN 978-0-8493-7443-2
. Retrieved 18 August 2016.

ISSN 2163-2790
.

Sources

This article incorporates public domain material from the United States Government

Australian Journal of Soil Research, 38(1) 61 – 70. Cited in: Land and Water Australia 2007, ways to improve soil structure and improve the productivity of irrigated agriculture, viewed May 2007, <https://web.archive.org/web/20070930071224/http://npsi.gov.au/>

Department of Land and Water Conservation 1991, "Field indicators of soil structure decline", viewed May 2007

Leeper, GW & Uren, NC 1993, 5th edn, Soil science, an introduction, Melbourne University Press, Melbourne

Marshall, TJ & Holmes JW, 1979, Soil Physics, Cambridge University Press

Soil Survey Division Staff (1993). "Examination and Description of Soils". Handbook 18. Soil survey manual. Soil Conservation Service. U.S. Department of Agriculture. Archived from the original on 2011-05-14. Retrieved 2006-04-11.

Charman, PEV & Murphy, BW 1998, 5th edn, Soils, their properties and management, Oxford University Press, Melbourne

Firuziaan, M. and Estorff, O., (2002), "Simulation of the Dynamic Behavior of Bedding-Foundation-Soil in the Time Domain", Springer Verlag.

External links

"Soils - Part 2: Physical Properties of Soil and Soil Water". unl.edu.

Jordán, Antonio. 2013. What is soil structure? European Geosciences Union Blog. Accessed 11 June 2017.

Soil Survey Division Staff. 1993. syu tycid=nrcs142p2_054253 Soil Survey Manual, Chapter 3: Examination and Description of Soils. USDA NRCS. Accessed 11 June 2017.

v
t
e
Soil science

History

Index

Main fields

Pedology

Edaphology

Soil biology

Soil microbiology

Soil zoology

Soil ecology

Soil physics

Soil mechanics

Soil chemistry

Environmental soil science

Agricultural soil science

Soil topics

Soil

Pedosphere
Soil morphology

Pedodiversity

Soil formation

Soil erosion

Soil contamination

Soil retrogression and degradation

Soil compaction
Soil compaction (agriculture)

Soil sealing

Soil salinity
Alkali soil

Soil pH
Soil acidification

Soil health

Soil life

Soil biodiversity

Soil quality

Soil value

Soil fertility

Soil resilience

Soil color

Soil texture

Soil structure
Pore space in soil

Pore water pressure

Soil crust

Soil horizon

Soil biomantle

Soil carbon

Soil gas
Soil respiration

Soil organic matter

Soil moisture
Soil water (retention)

Soil type
v
t
e
Soil classification
World Reference Base
for Soil Resources (1998–)

Acrisols

Alisols

Andosols

Anthrosols

Arenosols

Calcisols

Cambisols

Chernozem

Cryosols

Durisols

Ferralsols

Fluvisols

Gleysols

Gypsisols

Histosol

Kastanozems

Leptosols

Lixisols

Luvisols

Nitisols

Phaeozems

Planosols

Plinthosols

Podzols

Regosols

Retisols

Solonchaks

Solonetz

Stagnosol

Technosols

Umbrisols

Vertisols

USDA soil taxonomy

Alfisols

Andisols

Aridisols

Entisols

Gelisols

Histosols

Inceptisols

Mollisols

Oxisols

Spodosols

Ultisols

Vertisols

Other systems

FAO soil classification (1974–1998)

Unified Soil Classification System

AASHTO Soil Classification System

Référentiel pédologique (French classification system)

Canadian system of soil classification

Australian Soil Classification

Polish Soil Classification

1938 USDA soil taxonomy

List of U.S. state soils

List of vineyard soil types

Non-systematic soil types

Sand

Silt

Clay

Loam

Topsoil

Subsoil

Soil crust

Claypan

Hardpan

Gypcrust

Caliche

Parent material

Pedosphere

Laimosphere

Rhizosphere

Bulk soil

Alkali soil

Bay mud

Blue goo

Brickearth

Brown earth

Calcareous grassland

Dark earth

Dry quicksand

Duplex soil

Eluvium

Expansive clay

Fill dirt

Fuller's earth

Hydrophobic soil

Loess

Lunar soil

Martian soil

Mud

Muskeg

Paleosol

Peat

Prime farmland

Serpentine soil

Spodic soil

Stagnogley

Subaqueous soil

Takir

Terra preta

Terra rossa

Tropical peat

Yedoma

Types of soil
Applications

Soil conservation

Soil management

Soil guideline value

Soil survey

Soil test

Soil governance

Soil value

Soil salinity control

Erosion control

Agroecology

Liming (soil)

Related fields

Geology

Geochemistry

Petrology

Geomorphology

Geotechnical engineering

Hydrology

Hydrogeology

Biogeography

Earth materials

Archaeology

Agricultural science
Agrology

Societies, Initiatives

Australian Society of Soil Science Incorporated

Canadian Society of Soil Science

Central Soil Salinity Research Institute (India)

German Soil Science Society

Indian Institute of Soil Science

International Union of Soil Sciences

International Year of Soil

National Society of Consulting Soil Scientists (US)

OPAL Soil Centre (UK)

Soil Science Society of Poland

Soil and Water Conservation Society (US)

Soil Science Society of America

World Congress of Soil Science

Scientific journals

Acta Agriculturae Scandinavica B

Journal of Soil and Water Conservation

Plant and Soil

Pochvovedenie

Soil Research

Soil Science Society of America Journal

See also

Land use

Land conversion

Land management

Vegetation

Infiltration (hydrology)

Groundwater

Crust (geology)

Impervious surface/Surface runoff

Petrichor

Wikipedia:WikiProject Soil

Category soil

Category soil science

List of soil scientists

Authority control databases: National

Germany

Israel

United States

Latvia

Retrieved from "https://en.wikipedia.org/w/index.php?title=Soil_structure&oldid=1204415929"

[Dexter1988-1] 
doi:10.1016/0167-1987(88)90002-5
.

[2] PMID 26783947
.

[3] Young, A & Young R 2001, Soils in the Australian landscape, Oxford University Press, Melbourne. ^{[page needed]}

[NSW1991-4] Department of Land and Water Conservation 1991, "Field indicators of soil structure decline" Archived 2007-09-14 at the Wayback Machine, viewed May 2007

[USDA-5] ^ ^a ^b ^c ^d ^e ^f ^g C. Ditzler; K. Scheffe; H.C. Monger, eds. (2017). "Examination and Description of Soil Profiles §Soil structure". USDA Soil Survey Manual. Washington, D.C.: Government Printing Office. Archived from the original on 2018-09-07. Retrieved 2 November 2019.

[6] :10.1071/SR99079
.

[Daniells2012-7] :10.1071/SR11102
.

[Mullins1997-8] ISBN 978-0-8493-7443-2
. Retrieved 18 August 2016.

[9] ISSN 2163-2790
.

[3]

[4]

[5]

[6]

[7]

[8]

[9]