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 Update 2015 of the third edition 2014. It is edited by a working group of the International Union of Soil Sciences (IUSS).
Since the 19th century, several countries developed national soil classification systems. During the 20th century, the need for an international soil classification system became more and more obvious.
From 1971 to 1981, the Food and Agriculture Organization (FAO) and UNESCO published the Soil Map of the World, 10 volumes, scale 1 : 5 M. The Legend for this map, published in 1974 under the leadership of Rudi Dudal, became the FAO soil classification. Many ideas from national soil classification systems were brought together in this worldwide-applicable system, among them the idea of diagnostic horizons as established in the '7th approximation to the USDA soil taxonomy' from 1960. The next step was the Revised Legend of the Soil Map of the World, published in 1988.
In 1982, the International Soil Science Society (ISSS; now: International Union of Soil Sciences, IUSS) established a working group named International Reference Base for Soil Classification (IRB). Chair of this working group was Ernst Schlichting. Its mandate was to develop an international soil classification system that should better consider soil-forming processes than the FAO soil classification. Drafts were presented in 1982 and 1990.
In 1992, the IRB working group decided to develop a new system named World Reference Base for Soil Resources (WRB) that should further develop the Revised Legend of the FAO soil classification and include some ideas of the more systematic IRB approach. Otto Spaargaren (International Soil Reference and Information Centre) and Freddy Nachtergaele (FAO) were nominated to prepare a draft. This draft was presented at the 15th World Congress of Soil Science in Acapulco in 1994. At the same congress, the WRB was established as an ISSS working group replacing the IRB. At the 16th World Congress of Soil Science in Montpellier in 1998, the first edition of the WRB was published. At the same congress, the ISSS endorsed the WRB as its correlation system for soil classification. (In 2014, the USDA soil taxonomy also received the status of a correlation system.) At the 18th World Congress of Soil Science in Philadelphia in 2006, the second edition of the WRB was presented, and at the 20th World Congress of Soil Science in Jeju in 2014, the third edition. An update of the third edition was issued in 2015. Whereas the second edition was only suitable for naming soils, the third edition can additionally be used for creating map legends.
The WRB has only two hierarchical levels (see below) and has in that sense a similar approach as the French référencial pédologique (1992, 1995, 2008). Contrary to that, the USDA soil taxonomy is strongly hierarchical and has six levels. The classification in WRB is based mainly on soil morphology (field and laboratory data) as an expression of pedogenesis. Another difference with USDA soil taxonomy is that soil climate is regarded only as a soil-forming factor and not as a soil characteristic. The WRB is not meant to replace national soil classification systems, which, for their area, may be more detailed than the WRB.
The WRB is edited by a working group of the International Union of Soil Sciences (IUSS). The current chair of the working group is Peter Schad (Technical University of Munich, Germany, since 2010). The current vice-chair is Stephan Mantel (International Soil Reference and Information Centre, The Netherlands, since 2018).
Chairs of the WRB working group and responsible first authors of the WRB editions are: Seppe Deckers (Belgium, 1st edition 1998), Erika Michéli (Hungary, 2nd edition 2006) and Peter Schad (Germany, 3rd edition 2014).
The classification is based on diagnostic horizons, diagnostic properties and diagnostic materials, altogether called diagnostics. Diagnostic materials are materials that significantly influence soil-forming processes (pedogenesis). They are either inherited from the parent material or the result of soil-forming processes. Diagnostic properties are typical results of soil-forming processes or reflect specific conditions of soil formation. Diagnostic horizons are typical results of soil-forming processes that show a minimum thickness and therefore a horizontal appearance.
The diagnostics have names (e. g. argic horizon, stagnic properties, fluvic material). The WRB does not use horizons symbols (A horizons, B horizons). Therefore, horizons that are not diagnostic, do not have names. Instead, WRB recommends using the horizon symbols provided by the FAO Guidelines for Soil Description (2006).
The classification comprises two levels:
The first level has 32 Reference Soil Groups (RSGs).
At the second level, for further differentiation a set of qualifiers is added to the name of the RSG. There are 185 qualifiers in total. For every RSG, there is a list of available qualifiers, which are subdivided into two types:
The names of the RSGs and the qualifiers start with capital letters. They must be given in English and must not be translated into any other language in order to guarantee that a certain soil has the same name all over the world.
A key is used for allocating a soil to a certain RSG. In a defined sequence, the key asks for the presence or absence of certain diagnostics in a certain depth range. In addition, the key asks for single characteristics, e. g., a certain clay content or a certain base saturation. The soil belongs to the first RSG, for which it fulfils the set of criteria.
The qualifiers available for use with a particular RSG are listed in the key, along with the RSG. Their number is from 35 to 68. All applying qualifiers must be added to the soil name. The principal qualifiers are added before the name of the RSG. The sequence is from right to left, i.e. the uppermost qualifier in the list is placed closest to the name of the RSG. The supplementary qualifiers are added in brackets after the name of the RSG and are separated from each other by commas. The sequence is from left to right, i.e. the first qualifier according to the alphabet is placed closest to the name of the RSG. If no other principal qualifier applies, the Haplic qualifier is used. If two or more qualifiers in the list are separated by a slash (/) only one of them can be used. The slash signifies that these qualifiers are either mutually exclusive (e.g. Dystric and Eutric) or one of them is redundant with the redundant qualifier(s) listed after the slash(es). In the soil name, supplementary qualifiers are always placed in the order of the alphabet, even if their position in the list differs from alphabetical sequence due to the use of the slash. It is a general rule that qualifiers conveying redundant information are not used. Example: If a soil has the Calcaric qualifier (carbonates present) the Eutric qualifier (high base saturation) is not used.
Qualifiers may be combined with specifiers (e.g. Epi-, Proto-) to form subqualifiers (e.g. Epiarenic, Protocalcic). The depth-related specifiers are of special importance, although their use is optional:
The number of qualifiers used in a map legend depends on the scale. The WRB distinguishes four map scale levels:
Correlating the map scale levels with concrete scales (e.g. fourth map scale level from 1 : 250 000 to 1 : 1 000 000) is difficult because selecting a map scale level depends very much from the homogeneity/heterogeneity of the landscape.
The principal qualifiers are added before the name of the RSG following the rules explained for naming a soil. Depending on the purpose of the map or according to national traditions, at any scale level, further qualifiers may be added optionally. They may be additional principal qualifiers from further down the list and not already used in the soil name, or they may be supplementary qualifiers. They are placed using the above-mentioned rules for supplementary qualifiers; principal qualifiers first, then supplementary qualifiers.
The WRB recommends that on a map unit not just one soil is indicated but an association of soils. For this purpose, WRB uses the following nomenclature:
For codominant and associated soils, it is allowed to use less principal qualifiers than would correspondent to the used map scale level. The use of specifiers is not recommended due to the generalization that is required when making maps. In map legends, the names of the RSGs are given in plural; in all other cases they are given in singular.
The WRB Manual comprises five chapters and four annexes.
Chapter 1 reports on background and basics. It includes tables of the diagnostics and of the RSGs. The latter is given below. Chapter 2 provides the rules for classifying soils and creating map legends. It is highly recommended to read this short chapter before using the WRB. Chapter 3 presents the diagnostic horizons, properties and materials, each with a general description, the diagnostic criteria and some additional information. For the decision, whether a diagnostic is present or absent in a soil, only the diagnostic criteria are relevant. Chapter 4 provides the key to the RSGs and for every RSG a list with the available principal and supplementary qualifiers. Chapter 5 gives the definitions of the qualifiers. These five chapters are concluded with a list of references.
They are followed by four annexes. Annex 1 briefly describes the 32 RSGs. Annex 2 lists the laboratory methods. This is only a list; it is not a laboratory manual. Annex 3 gives the codes for the RSGs, the qualifiers and the specifiers and the rules for the sequence of the codes for naming soils and creating map legends. Annex 4 provides a texture triangle, in which the ranges of the texture-related qualifiers are marked with different grey shades.
This is the list of the 32 Reference Soil Groups in the sequence of the key (Chapter 4 of the WRB Manual), including the codes (Annex 3 of the WRB Manual). This list is mainly taken from Table 2 (Chapter 1) of the WRB Manual.
Soils with thick organic layers
Soils with strong human influence
Soils with limitations to root growth
Soils distinguished by Fe/Al chemistry
Pronounced accumulation of organic matter in the mineral topsoil
Accumulation of moderately soluble salts or non-saline substances
Soils with clay-enriched subsoil
Soils with little or no profile differentiation
Our example soil has the following characteristics:
Field characteristics: A soil developed from loess shows a marked clay increase in around 60 cm depth and clay coatings in the clay-richer horizon. According to the landscape setting, we presume that high-activity clays dominate. In the field, a pH value of 6 is measured in the subsoil. The lower part of the clay-poorer topsoil is bleached. In the clay-richer horizon, we observe a mottling; the oximorphic and the reductimorphic colours sum up to 30% of the exposed area, the intensive colours in the interiors of the aggregates. In spring time, reducing conditions occur. The soil is ploughed regularly. Organic matter concentrations in the topsoil are small.
Laboratory characteristics: The laboratory analyses confirm the high cation exchange capacity per kg clay in the clay-richer horizon and the high base saturation in the subsoil. In the topsoil, we find 20% clay, 10% sand and 70% silt, in the subsoil 35% clay, 10% sand and 55% silt.
The naming of the soil consists of four steps.
Question 1: Does the soil have diagnostic horizons, properties and materials?
The soil has the following diagnostics:
Question 2: To which RSG does the soil belong?
We have to go through the key RSG for RSG. This soil is not a Histosol, not an Anthrosol, not a Technosol etc. Finally, we end up with the Luvisols. This is the first RSG in the key, the criteria of which our soil completely fulfils.
Question 3: Which qualifiers apply?
From the list of the principal qualifiers, Stagnic (stagnic properties and reducing conditions) and Albic (light colours) apply. Stagnic is found further up in the list. Therefore, the soil has to be named up till now Albic Stagnic Luvisol. From the list of the supplementary qualifiers, Siltic (silty from 0 to 60 cm), Loamic (loamy from 60 cm downwards), Aric (ploughed), Cutanic (clay coatings) und Ochric (small concentrations of organic carbon) apply. Bringing the supplementary qualifiers into the alphabetical order, the soil is an Albic Stagnic Luvisol (Aric, Cutanic, Loamic, Ochric, Siltic).
Question 4: Which specifiers can be used to form subqualifiers?
The soil is Siltic from 0 to 60 cm and Loamic from 60 cm downwards. We can use the depth-related specifiers Ano- and Endo- to construct the subqualifiers Anosiltic and Endoloamic. The stagnic properties occur only in the subsoil and the albic material only around 50 cm. This means that we can use the subqualifiers Endostagnic and Amphialbic.
Now, the soil name is: Amphialbic Endostagnic Luvisol (Aric, Cutanic, Endoloamic, Ochric, Anosiltic).
Using the codes of Annex 3 of the WRB Manual gives us the following short name: LV-stn.abm-ai.ct.lon.oh.sia.
Let's say that our example soil Amphialbic Endostagnic Luvisol (Aric, Cutanic, Endoloamic, Ochric, Anosiltic) covers 60% of the area of a map unit. The other 40% are covered by a Eutric Endoluvic Amphialbic Stagnosol (Humic, Endoloamic, Anosiltic). The map unit will be named as follows:
First map scale level:
Second map scale level:
Third map scale level:
Fourth map scale level:
Remarks: The use of the depth-related specifiers is not recommended in map legends, where generalization is required. The fourth scale level would allow three principal qualifiers, but the dominant soil in our example has only two.
At every scale level, optional qualifiers may be added. If one wants to give information about organic carbon, one can do that even at the first map scale level and write:
If somebody wants to give additional information on soil genesis, this can also be done on the first map scale level:
Both in combination would read, e. g., at the second map scale level: