There are hundreds of soil tests that can be conducted, both in the field or laboratory. This page provides an overview of more common soil tests, links to information on sampling, and links to test methods.
Soil sample collection methods vary and covering all acceptable methods is beyond the scope of this page. Below are links to sampling methods, including videos.
Documents
Videos of sample collection for lab analysis
Most chemical tests are conducted in the laboratory on samples collected in the field.
For more information link here.
Soil macronutrients include phosphorus, nitrogen, potassium, sulfur, calcium, and magnesium. Phosphorus is an important pollutant of concern in surface water, particularly lakes. Though there are several forms of phosphorus, they can roughly be divided into dissolved phosphorus (includes orthophosphate and soluble phosphorus) and particulate phosphorus, with dissolved phosphorus being much more bioavailable than particulate forms. Dissolved phosphorus is typically identified as phosphorus passing through a 0.45 micron filter. For a detailed discussion of phosphorus, link here.
Nitrogen is also an important nutrient in both surface water and groundwater. Nitrogen concentrations in stormwater are typically below levels of concern for receiving waters.
Potassium, sulfur, calcium, and magnesium are typically not pollutants of concern in stormwater runoff, but they may be deficient in some soils and therefore potentially impact vegetation.
The primary sources of metals in stormwater runoff are associated with automobiles, both from fluids and wear of parts, including tires. Concentrations of metals in stormwater runoff are generally below aquatic life and drinking water criteria, though concentrations may exceed criteria for sensitive species and in specific land uses, such as high traffic transportation areas. Metals of greatest concern include copper, zinc, nickel, cadmium, and lead.
Samples are typically collected for total metals, meaning samples are not filtered. For dissolved metal concentrations, samples are filtered using a 0.45 micron filter. From an environmental perspective, dissolved metal concentrations more accurately reflect potential risk to receptors, since most metal bound to particles is retained in stormwater bmps. Lab methods include the following.
Soil pH typically ranges from 6 to 8. Soils with elevated organic matter concentrations may have lower pH. Soil pH affects biologic activity and chemical reactions, particularly of some metals. Soil pH is generally not a concern, though some amendments, such as lime (increases pH), may lead to soil pH values that adversely affect soil biology, vegetation, mobilize metals, or bind up nutrients. Recommended lab methods include the following.
By itself, organic matter is not generally a pollutant of concern unless it contains bound pollutants at levels of concern (e.g. metals, organic pollutants such as oil and pesticides). Organic matter can create oxygen demand in receiving waters and, as mentioned above, transport attached chemicals that may become a concern in receiving waters, including nutrients, metals , and organic pollutants. Organic matter also provides a food source for bacteria and pathogens.
Exchange capacity affects the fate of other soil chemicals, including nutrients and pollutants, and provides a buffer against soil acidification.
Enzymes in soil mediate numerous chemical reactions involved in soil nutrient cycling, transformation of plant and microbial debris, mineralization and transformation of organic matter within the carbon cycle, and transformation and degradation of potentially hazardous pollutants.
Specific recommended procedures are not provided as there is a wide range of methods depending on objectives of the sampling. This video provides a discussion of enzymes and soil enzymes, including sample collection and measurement (starting at about the 39 minute mark). This website provides a discussion of soil enzymes including limitations of testing methods. Additional references include the following.
Field methods for soil chemical testing are generally not recommended, though they can be useful in providing general information. Typically field tests involve the use of test strips or probes. Portable laboratories can be used to conduct some of the analyses described above. Although these tests are conducted in the field, they utilize laboratory methods and are therefore more appropriately considered lab tests.
Here are some links to information on soil chemical field tests.
Most soil physical and hydrologic tests can be done in the field, but some require additional procedures performed in the laboratory.
Laboratory analysis of soil water content is recommended for point-in-time measurements. Lab methods involve weighing a soil sample prior to drying, then drying to constant weight in oven at temperature between 100–110oC (105oC is typical). The difference in weight represents the mass of water in the sample. The water content is then expressed on a mass basis (g of water to g of dry soil), or if the bulk density is known, the volume of water to volume of soil. It is important that samples collected in the field be properly stored to avoid water loss prior to analysis. For further reading see [4].
For continuous measurements, field methods must be employed. Field methods are summarized below. The most common methods are electrical resistance (e.g. time domain reflectometry), tensiometric, and radioactive (e.g. neutron probe). This document and this document provide discussions of methods for measuring soil water content. This one hour video provides an overview of soil water measurement.
Available water capacity is the maximum amount of plant available water a soil can provide, often calculated as water available between field capacity and the wilting point.
This link provides a discussion of methods for determining available water capacity.
Soil bulk density is an important measurement for determining soil infiltration and plant rooting properties. Measuring bulk density involves proper sample collection and laboratory analysis. Below are links to videos demonstrating methods for collecting bulk density samples.
Methods for measuring bulk density are provided in the following documents.
Infiltration rates should be measured in the field. This page provides information on measuring soil infiltration rates.
Videos illustrating measurement of infiltration rates.
Soil compaction results from repeated traffic, generally from machinery, or repeated tillage at the same depth, which results in a compacted layer at the tillage depth. Compaction inhibits infiltration, gas and water movement, may impede root growth, disrupts habitat for soil biota, and affects nutrient cycling. There are several field methods for determining soil compaction or penetration resistance.
For additional information on measuring soil compaction, see [11], [12], and [13].
Non-granular soils (e.g. clays) form aggregates that are important in maintaining soil physical, chemical, and biologic processes. Methods for assessing aggregate stability are somewhat qualitative and different methods do not correlate well. The method selected should simulate field processes likely to affect aggregate stability (e.g. rainfall impact, ponded (flooded) conditions, tillage).
Further reading
Videos
Soil texture is determined with one of the following methods.
Other methods, which employ qualitative approaches, include the feel method, ball and ribbon methods, and ball throwing method. These are described here.
Measurement of soil structure typically focuses on determining soil stability and texture. See the methods above for measuring these properties. Additional references and links are provided below.
Structural soil crusts are relatively thin, dense, somewhat continuous layers of non-aggregated soil particles on the surface of tilled and exposed soils. A surface crust indicates poor infiltration, a problematical seedbed, and reduced air exchange between the soil and atmosphere. It can also indicate that a soil has a high sodium content that increases soil dispersion when it is wetted by rainfall or irrigation. Tests typically are based on applying pressure to determine the strength of a crust, or methods to determine stability of the surface crust.
Below are resources for measuring soil crusting and strength of crusts.
In soils with significant macroporosity, a high percentage of annual water and solute movement can occur within the macropores. This can lead to rapid movement of solutes, including pollutants of concern, deep into the soil profile and eventually into groundwater. Soil macroporosity can be measured directly in the field by physically excavating soil, typically in layers, and quantifying soil macropores. Colored or fluorescent dyes are often used, as well as imaging equipment. Examples of this methodology are provided at the following links.
Macroporosity can also be estimated using indirect methods, such as those based on bulk density, water content, particle size distribution, and infiltration. Examples are provided at the following links.
There are currently two types of tests that can be performed to determine soil diversity: Tests that analyze and classify parts of the microbial material itself (‘taxonomic tests’), and tests that look at the metabolic products of microbes (‘functional tests’). Below are links to websites and videos that provide information on testing for biotic diversity, including testing methods.