SIST EN ISO 19258:2011

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.Bodenbeschaffenheit - Leitfaden zur Bestimmung von Hintergrundwerten (ISO 19258:2005)Qualité du sol - Guide pour la détermination des valeurs de bruit de fond (ISO 19258:2005)Soil quality - Guidance on the determination of background values (ISO 19258:2005)13.080.99Drugi standardi v zvezi s kakovostjo talOther standards related to soil qualityICS:Ta slovenski standard je istoveten z:FprEN ISO 19258kSIST FprEN ISO 19258:2011en,fr,de01-april-2011kSIST FprEN ISO 19258:2011SLOVENSKI
STANDARD



kSIST FprEN ISO 19258:2011



EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM
FINAL DRAFT
FprEN ISO 19258
December 2010 ICS 13.080.99 English Version
Soil quality - Guidance on the determination of background values (ISO 19258:2005)
Qualité du sol - Guide pour la détermination des valeurs de bruit de fond (ISO 19258:2005)
Bodenbeschaffenheit - Leitfaden zur Bestimmung von Hintergrundwerten (ISO 19258:2005) This draft European Standard is submitted to CEN members for unique acceptance procedure. It has been drawn up by the Technical Committee CEN/TC 345.
If this draft becomes a European Standard, CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration.
This draft European Standard was established by CEN in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC Management Centre has the same status as the official versions.
CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland and United Kingdom.
Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are aware and to provide supporting documentation.
Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without notice and shall not be referred to as a European Standard.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION EUROPÄISCHES KOMITEE FÜR NORMUNG
Management Centre:
Avenue Marnix 17,
B-1000 Brussels © 2010 CEN All rights of exploitation in any form and by any means reserved worldwide for CEN national Members. Ref. No. FprEN ISO 19258:2010: EkSIST FprEN ISO 19258:2011



FprEN ISO 19258:2010 (E) 2 Contents Page Foreword .3 kSIST FprEN ISO 19258:2011



FprEN ISO 19258:2010 (E) 3 Foreword The text of ISO 19258:2005 has been prepared by Technical Committee ISO/TC 190 “Soil quality” of the International Organization for Standardization (ISO) and has been taken over as FprEN ISO 19258:2010 by Technical Committee CEN/TC 345 “Characterization of soils” the secretariat of which is held by NEN. This document is currently submitted to the Unique Acceptance Procedure. Endorsement notice The text of ISO 19258:2005 has been approved by CEN as a FprEN ISO 19258:2010 without any modification.
kSIST FprEN ISO 19258:2011



kSIST FprEN ISO 19258:2011



Reference numberISO 19258:2005(E)© ISO 2005
INTERNATIONAL STANDARD ISO19258First edition2005-12-15Soil quality — Guidance on the determination of background values Qualité du sol — Guide pour la détermination des valeurs de bruit de fond
kSIST FprEN ISO 19258:2011



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ii © ISO 2005 – All rights reserved
kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) © ISO 2005 – All rights reserved iiiContents Page Foreword.iv 1 Scope.1 2 Normative references.1 3 Terms and definitions.1 4 General.3 5 Procedures.3 5.1 General.3 5.2 Objectives and technical approaches.4 5.2.1 General.4 5.2.2 Substances and parameters.4 5.2.3 Study area.6 5.2.4 Time period.7 5.2.5 Scale of sampling (Support).7 5.3 Evaluation of existing data.7 5.3.1 General.7 5.3.2 Completeness of data sets/minimum requirements.8 5.3.3 Comparability of data (Sampling, nomenclatures, analyses).8 5.3.4 Elimination of outliers.9 5.4 Collection of new data.9 5.4.1 Sampling.9 5.4.2 Soil analysis.12 5.5 Data processing and presentation.13 5.5.1 Statistical evaluation of data.13 5.5.2 Data presentation and reporting.14 6 Data handling/quality control.15 Annex A (informative)
Scale of sampling.17 Annex B (informative)
Outlier tests.19 Bibliography.23
kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) iv © ISO 2005 – All rights reserved Foreword ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies (ISO member bodies). The work of preparing International Standards is normally carried out through ISO technical committees. Each member body interested in a subject for which a technical committee has been established has the right to be represented on that committee. International organizations, governmental and non-governmental, in liaison with ISO, also take part in the work. ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization. International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 2. The main task of technical committees is to prepare International Standards. Draft International Standards adopted by the technical committees are circulated to the member bodies for voting. Publication as an International Standard requires approval by at least 75 % of the member bodies casting a vote. Attention is drawn to the possibility that some of the elements of this document may be the subject of patent rights. ISO shall not be held responsible for identifying any or all such patent rights. ISO 19258 was prepared by Technical Committee ISO/TC 190, Soil quality, Subcommittee SC 7, Soil and site assessment.
kSIST FprEN ISO 19258:2011



INTERNATIONAL STANDARD ISO 19258:2005(E) © ISO 2005 – All rights reserved 1Soil quality — Guidance on the determination of background values 1 Scope This International Standard provides guidance on the principles and main methods for the determination of pedo-geochemical background values and background values for inorganic and organic substances in soils. This International Standard gives guidance on strategies for sampling and data processing and identifies methods for sampling and analysis. This International Standard does not give guidance on the determination of background values for groundwater and sediments. 2 Normative references The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies. ISO 10381-1, Soil quality — Sampling — Part 1: Guidance on the design of sampling programmes ISO 10381-5, Soil quality — Sampling — Part 5: Guidance on the procedure for the investigation of urban and industrial sites with regard to soil contamination ISO 11074:2005, Soil quality — Vocabulary 3 Terms and definitions For the purposes of this document, the terms and definitions given in ISO 11074 and the following apply. 3.1 background content content of a substance in a soil resulting from both natural geological and pedological processes and including diffuse source inputs 3.2 background value statistical characteristic (3.8) of the background content 3.3 contaminant substance or agent present in the soil as a result of human activity NOTE There is no assumption in this definition that harm results from the presence of the contaminant. kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) 2 © ISO 2005 – All rights reserved 3.4 diffuse source input input of a substance emitted from moving sources, from sources with a large area or from many sources NOTE 1 The sources can be cars, application of substances through agricultural practices, emissions from town or region, deposition through flooding of a river. NOTE 2 Diffuse source input usually leads to sites that are relatively uniformly contaminated. At some sites, the input conditions may nevertheless cause a higher local input such as near the source or where atmospheric deposition/rain is increased. [ISO 11074:2005] 3.5 pedo-geochemical content content of a substance in a soil resulting from natural geological and pedological processes, excluding any addition of human origin NOTE It may be hardly possible to determine the precise pedo-geochemical content of certain substances in a soil due to anthropogenic diffuse contamination. 3.6 pedo-geochemical background value statistical characteristic (3.8) of the pedo-geochemical content NOTE Any estimate of pedo-geochemical background value will be prone to a certain amount of error given the uncertainty associated with determining the pedo-geochemical content. 3.7 soil upper layer of the Earth's crust composed of mineral parts, organic substance, water, air and living organisms [ISO 11074:2005] 3.8 statistical characteristic numerical value calculated from a variate of a chosen parameter of the population EXAMPLE Examples of the statistical characteristics are the mean, the median, the standard deviation or the percentiles of the ordered frequency distribution. 3.9 study area three-dimensional definition of the area where samples are to be obtained from and thus for which the background value(s) are to be estimated 3.10 support size, shape and orientation of a soil sample NOTE For the purpose of analysing spatial variation in soils geostatistically (by estimation of the variogram of a soil property), the support should be the same at each sampling site. 3.11 variate set of observed values of a variable EXAMPLE A variate could for instance be the series of numbers of the concentration of a substance in soil or numerous, individual soil samples. kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) © ISO 2005 – All rights reserved 34 General Soils retain the evidence of their past history including impacts due to natural events or human activities. Chemical impacts related to human activities can be detected in soils all over the world, even in regions far from any source of contamination. For this reason, the background contents of inorganic and organic substances in soils consist of a pedo-geochemical fraction and an anthropogenic fraction. The ratio of these fractions varies widely depending on the type of substances, the type of soil and land use, and the kind and extent of external impacts. For many inorganic substances, the background content of unpolluted soils is dominated by the pedo-geochemical content and consequently by the mineralogical composition of the soils parent material. Pedogenetic processes may lead to a redistribution (enrichment/impoverishment) and consequently to a horizon-specific differentiation of the substances within a soil profile. Persistent organic substances in soils originate more often from non-natural sources and therefore the background content of soils is governed by the kind and extent of diffuse contamination from non-soil sources. In practice, it is often difficult to distinguish clearly between the pedo-geochemical and the anthropogenic fraction of the background content of soils. Nonetheless, a detailed knowledge of the background content as well as of its natural fraction for the substances of concern is essential both for any evaluation of the current status of soils for environmental or land use related aspects or just for scientific purposes within the scope of pedology or geochemistry. To this end, so-called background values in terms of the statistical characteristics of both, the pedo-geochemical and the anthropogenic fraction have to be determined. A variety of different objectives can be identified for the determination of background values of inorganic and/or organic substances in soils. The objectives themselves provide insufficient information to define the technical programme that will produce the desired background values. Thus a number of technical approaches have to be defined which together form the basis of the technical programme. This guidance provides essential aspects of sampling strategies and procedures, minimum requirements regarding the necessary steps and ways of sample pre-treatment, analytical methods and statistical evaluation procedures for determining sound and comparable background values. Guidance is given for a) evaluating existing data from different data sources and b) setting up complete investigation programs aiming to compile background values for a clearly defined three-dimensional picture of the soil. These situations are representing the two extreme starting positions for the process of compiling background values. In practice, a third intermediate situation may be dealt with when additional data need to be collected because the quantity or quality of the existing data is insufficient. 5 Procedures 5.1 General The procedures to determine background values encompass aspects of sampling (strategy, procedure), soil analysis (pre-treatment, extraction and measurement), data processing and presentation. In general, two starting positions can be distinguished, namely a) the evaluation of existing data mostly from different data sources, and b) the collection of new data based on an appropriate investigation strategy. kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) 4 © ISO 2005 – All rights reserved 5.2 Objectives and technical approaches 5.2.1 General Before commencing any survey on background values in soils it is of crucial importance to define the objective of the survey and the related technical approach. The objective is, in general terms, the definition of 'why' background values are to be determined. The technical approaches describe aspects like the 'where', 'what', 'how' and 'when'. Together the technical approaches determine the technical programme that will provide the required background values. NOTE It should be noted that a technical approach that is fit for one objective, will often be unfit for other objectives. The objectives for defining background values might be: ⎯ to identify the current contents of substances in soils, e.g. in the context of soil-related directives; ⎯ to assess the degree of contamination by human activities; ⎯ to derive reference values for soil protection; ⎯ to define soil values for reuse of soil material and waste; ⎯ to calculate critical levels and tolerable additional critical loads; ⎯ to identify areas/sites with atypically enhanced levels of element contents due to geogenic reasons or human impact; ⎯ etc. In order to meet the objective, the technical approaches might include the following. ⎯ Definition of the substances and parameters ⎯ For example, the background values to be estimated may be the total heavy metal content or the bioavailable heavy metal content. (See 5.2.2) ⎯ Definition of the study area ⎯ The (three-dimensional) definition of the area where samples are to be obtained from. This has to be a detailed description of what is to be considered as the study area, and what is not. (See 5.2.3.) ⎯ Definition of the time period of interest: ⎯ Are the historical or current contents relevant for the objective? (See 5.2.4.) ⎯ Definition of the size and geometry (support) of the area sampled at a sampling location. (See 5.2.5.) 5.2.2 Substances and parameters Background values can be determined for all kinds of inorganic and organic substances in soils as well as soil characteristics. In practice, the more persistent and immobile compounds are of primary interest because of their potential to adsorb and accumulate in soil, whereas remobilization and intrinsic biodegradation are of less significance. As well as the substances of concern, basic soil parameters and site characteristics (see 5.4.1.3) need to be provided to assist in interpretation of the contents of substances. A number of so-called basic soil parameters influence soil processes that affect the contents of inorganic and organic substances. Table 1 lists these parameters which should be analysed according to the given International Standards. kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) © ISO 2005 – All rights reserved 5Within the group of inorganic substances, trace elements (e.g. heavy metals, micronutrients) are most often analysed (Table 2). Concerning the analytical methods, a distinction has to be drawn between different extraction/preparation methods (Table 2), whereof very few determine the total content which may be needed for instance for calculating element stocks. Besides total contents, the (eco-) toxicologically more relevant mobile fractions (Table 2) are of increasing interest, e.g. if pathway-related questions are to be examined. Analysis of parameters in Table 2 should be carried out according to International Standards given in Table 2. Table 1 — Basic soil parameters Parameter Method ISO International StandardTexture Sieving, sedimentation ISO 11277 Fraction of coarse material Sieving ISO 11277 Amount of non-soil material Sieving/visual control ISO 11259, ISO 11277 Bulk density Direct measurement of undisturbed soil samples, estimation form soil water retention curves ISO 11272 pH pH-electrode ISO 10390 Content of organic carbon Dry combustion ISO 14235 BASECOMP ISO 11260 Cation exchange capacity, exchangeable cations BaCl2 ISO 13536 Carbonate content CO2-evolution ISO 10693 Table 2 — Examples for the analysis of inorganic substances ISO International Standard Parameter Speciation/form Extraction/preparation Method Extraction/preparation Determination Metalloids, e.g. ISO 14869-1 ISO 14869-1 arsenic and selenium Total Alkaline fusion + X-ray fluorescence HF + HCIO4 ISO 14869-2 ISO 11047 Metals, Pseudo total aqua regia ISO 11466 ISO 11047 barium, cadmium, EDTA
chromium, cobalt, Complexing DTPA ISO 14870 ISO 11047 copper, iron, lead, NaNO3 manganese, mercury, NH4NO3 molybdenum, nickel,
CaCl2 thallium, zinc Exchangeable KCl
Cyanides Water soluble H2O, leaching tests See NOTE. See NOTE. NOTE There are a variety of extraction and analytical methods for soil-water in the series of International Standards on water quality which may also be applicable. However, it is important to confirm that they will work with the extracts obtained form particular soil material. Surveys on organic substances usually refer to persistent compounds. The persistent organic contaminants listed in Table 3 are some of the more commonly encountered, but the list is not complete. Analysis should be carried out according to International Standards listed in Table 3. Various methods are used for the analysis of organic substances. The aim of these methods is usually to extract the greatest possible quantity of organic substances from soils. It is important to recognize that organic compounds may be extracted from naturally occurring organic materials (e.g. organic matter, decaying vegetation, peat, charcoal), and that non-specific analyses in particular may, therefore, give misleading results. kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) 6 © ISO 2005 – All rights reserved Table 3 — Examples for the analysis of organic substances Substance/groups of substances Method ISO International Standard PAH Soxhlet/HPLC/UV ISO 13877
Thin-layer chromatography ISO 7981-1
RP C-18/HPLC ISO 7981-2
GC/MS ISO 18287 Dioxins/Furane
Chlorophenols Hexane/GC/ECD ISO 8165-1 Chlorpesticides RP C-18/HPLC/UV ISO 11369 PCBs GC-ECD ISO 10382 Chlornaphthalene
Chlorparafin
Bromodiphenylethers
NOTE There are a variety of extraction and analytical methods for water in the series of International Standards on water quality which may also be applicable. However it is important to confirm that they will work with the extracts obtained from a particular soil material. When collecting new data for determining background values, it is recommended that the investigation program be designed with regard to additional questions that could arise in future. In most cases, carrying out new sampling campaigns is much more expensive than analysing additional substances in the first place. To this end, a suitable storage of soil samples for subsequent analyses of organic or inorganic substances is of crucial importance. Besides the substances of concern (Tables 2 and 3) and additional soil parameters (Table 1), it is essential to provide a comprehensive site description (see 5.4.1.3) for interpretation purposes. The documentation of all the actions taken is of utmost importance if the data measured is to be of use for other assessments in future investigations. 5.2.3 Study area The definition of the study area (3.9) can be based on two different principles, that is: ⎯ a purely spatial definition (X, Y, Z), defining the contours of the study area by the coordinates within which the study area lies. Apart from the definition in a horizontal plane, the soil depth that is to be studied should also be defined; ⎯ a typological definition of the study area, based on one or more characteristic(s), e.g. soil type (for example, the A-horizon of a specific soil type), land use (also considering the potential effects on the background values), elevation level, etc. Of course, it is possible to mix the spatial and typological definition of the study area. EXAMPLE Examples of a mix of the spatial and typological definition of the study area might be:
— the grassland in a county or province;
— the A-horizon in an area defined by X- and Y-coordinates. The definition of the study area must be detailed at a level where there cannot be any misinterpretation on what is and what is not part of the study area. For an unambiguous definition of the study area, all actual point and diffuse sources within the study area need to be defined. As the general objective is to determine background values, a safety zone around that (type of) source might be defined and thereby excluding parts of the more generally defined study area. It might also result in specific zones for which the data is to be considered separately from the rest of the study area. kSIST FprEN ISO 19258:2011



ISO 19258:2005(E) © ISO 2005 – All rights reserved 7The definition of the study area as described is independent of whether the soil samples are still to be taken, or whether already existing soil samples (or results) are to be used. In the latter situation, the detailed definition of the study area will define which samples/results are to be included or excluded. 5.2.4 Time period Background values are influenced both by the natural processes (pedogenesis, biogeochemical cycles) as well as by diffuse source input. Two different time scales can be distinguished: ⎯ the period in which the background value may significantly vary due to natural processes; ⎯ the period in which the background value will most probably only change due to human influences (except for large scale natural phenomena). The second period is generally smaller than the first one. It might be that a specific historic period is of interest when measuring background values. When a soil layer is formed during this same period, it is indeed possible to determine background values for a certain time period. When background values are to be re-determined after a period of time in order to determine if changes occur, the time period between measurements should be based on (see also ISO 16133): ⎯ the expected enrichment of substances in soils (accumulation for example due to diffuse source input); ⎯ the expected loss of substances in soils (for example, due to leaching, biodegradation or plant uptake); ⎯ changes in concentration level that can be determined both analytically and statistically. 5.2.5 Scale of sampling (Support) Variability in concentrations is by definition a scale-related characteristic. Depending on the volume for which an analytical result is to be considered representative, the variability in concentrations encountered might be different. The scale — or in more technical terms the (geo-statistical) support (3.10) — is therefore an important technical aspect on which a decision is to be made prior to data collection. For (mainly) two-dimensional surveys, the support is the size (and geometry) of the area sampled at a sampling location. The study will always involve a certain soil layer of depth. However, as in the horizontal plane, the dimensions are much larger than in the vertical plane, the support in soil surveys is most often defined in a two-dimensional way. More information on support is given in Annex A. 5.3 Evaluation of existing data 5.3.1 General When using existing data, specific care must be taken concerning the quality and comparability of data particularly if the data originate from dif
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