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ASTM D4096-17(2023)

(Test Method)

Standard Test Method for Determination of Total Suspended Particulate Matter in the Atmosphere (High–Volume Sampler Method)

Standard Test Method for Determination of Total Suspended Particulate Matter in the Atmosphere (High–Volume Sampler Method)

SIGNIFICANCE AND USE
5.1 The Hi-Vol sampler is commonly used for the collection of the airborne particulate component of the atmosphere. Some physical and chemical parameters of the collected particulate matter are dependent upon the physical characteristics of the collection system and the choice of filter media. A variety of options available for the Hi-Vol sampler give it broad versatility and allow the user to develop information about the size and quantity of airborne particulate material and, using subsequent chemical analytical techniques, information about the chemical properties of the particulate matter.  
5.2 This test method presents techniques that when uniformly applied, provide measurements suitable for intersite comparisons.  
5.3 This test method measures the atmosphere presented to the sampler with good precision, but the actual dust levels in the atmosphere can vary widely from one location to another. This means that sampler location may be of paramount importance, and may impose far greater variability of results than any lack of precision in the method of measurement. In particular, localized dust sources may exert a major influence over a very limited area immediately adjacent to such sources. Examples include unpaved streets, vehicle traffic on roadways with a surface film of dust, building demolition and construction activity, or nearby industrial plants with dust emissions. In some cases, dust levels measured close to such sources may be several times the community wide levels exclusive of such localized effects (see Practice D1357).
SCOPE
1.1 This test method provides for sampling a large volume of atmosphere, 1600 m3 to 2400 m3 (55 000 ft3 to 85 000 ft3), by means of a high flow-rate vacuum pump at a rate of 1.13 m3/min to 1.70 m3/min (40 ft3/min to 60 ft3/min) (1-4).2  
1.2 This flow rate allows suspended particles having diameters of less than 100 μm (stokes equivalent diameter) to be collected. However, the collection efficiencies for particles larger than 20 μm decreases with increasing particle size and it varies widely with the angle of the wind with respect to the roof ridge of the sampler shelter and with increasing speed (5). When glass fiber filters are used, particles within the size range of 100 μm to 0.1 μm diameters or less are ordinarily collected.  
1.3 The upper limit of mass loading will be determined by plugging of the filter medium with sample material, which causes a significant decrease in flow rate (see 6.4). For very dusty atmospheres, shorter sampling periods will be necessary. The minimum amount of particulate matter detectable by this method is 3 mg (95 % confidence level). When the sampler is operated at an average flow rate of 1.70 m3/min (60 ft3/min) for 24 h, this is equivalent to 1 μg/m3 to 2 μg/m3 (3).  
1.4 The sample that is collected may be subjected to further analyses by a variety of methods for specific constituents.  
1.5 The values stated in SI units are to be regarded as standard. The values given in parentheses are mathematical conversions to inch-pound units that are provided for information only and are not considered standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

General Information

Status
Published
Publication Date
31-Oct-2023
ICS
13.040.01 - Air quality in general
Technical Committee
D22 - Air Quality
Drafting Committee
D22.03 - Ambient Atmospheres and Source Emissions
Current Stage
Ref Project

Relations

Replaces
ASTM D4096-17 - Standard Test Method for Determination of Total Suspended Particulate Matter in the Atmosphere (High–Volume Sampler Method)
Effective Date
01-Nov-2023
Referred By
ASTM D1356-20a - Standard Terminology Relating to Sampling and Analysis of Atmospheres
Effective Date
01-Nov-2023
Referred By
ASTM D6552-06(2021) - Standard Practice for Controlling and Characterizing Errors in Weighing Collected Aerosols
Effective Date
01-Nov-2023

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ASTM D4096-17(2023) - Standard Test Method for Determination of Total Suspended Particulate Matter in the Atmosphere (High–Volume Sampler Method)ASTM D4096-17(2023) - Standard Test Method for Determination of Total Suspended Particulate Matter in the Atmosphere (High–Volume Sampler Method)
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ASTM D4096-17(2023) - Standard Test Method for Determination of Total Suspended Particulate Matter in the Atmosphere (High–Volume Sampler Method)
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This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
Designation: D4096 − 17 (Reapproved 2023)
Standard Test Method for
Determination of Total Suspended Particulate Matter in the
Atmosphere (High–Volume Sampler Method)
This standard is issued under the fixed designation D4096; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 1.7 This international standard was developed in accor-
dance with internationally recognized principles on standard-
1.1 This test method provides for sampling a large volume
3 3 3 3 ization established in the Decision on Principles for the
of atmosphere, 1600 m to 2400 m (55 000 ft to 85 000 ft ),
Development of International Standards, Guides and Recom-
by means of a high flow-rate vacuum pump at a rate of
3 3 3 3 2 mendations issued by the World Trade Organization Technical
1.13 m /min to 1.70 m /min (40 ft /min to 60 ft /min) (1-4).
Barriers to Trade (TBT) Committee.
1.2 This flow rate allows suspended particles having diam-
eters of less than 100 μm (stokes equivalent diameter) to be
2. Referenced Documents
collected. However, the collection efficiencies for particles
2.1 ASTM Standards:
larger than 20 μm decreases with increasing particle size and it
D1356 Terminology Relating to Sampling and Analysis of
varies widely with the angle of the wind with respect to the
Atmospheres
roof ridge of the sampler shelter and with increasing speed (5).
D1357 Practice for Planning the Sampling of the Ambient
When glass fiber filters are used, particles within the size range
Atmosphere
of 100 μm to 0.1 μm diameters or less are ordinarily collected.
D2986 Practice for Evaluation of Air Assay Media by the
1.3 The upper limit of mass loading will be determined by
Monodisperse DOP (Dioctyl Phthalate) Smoke Test
plugging of the filter medium with sample material, which
(Withdrawn 2004)
causes a significant decrease in flow rate (see 6.4). For very
D3631 Test Methods for Measuring Surface Atmospheric
dusty atmospheres, shorter sampling periods will be necessary.
Pressure
The minimum amount of particulate matter detectable by this
E1 Specification for ASTM Liquid-in-Glass Thermometers
method is 3 mg (95 % confidence level). When the sampler is
2.2 Other Documents:
3 3
operated at an average flow rate of 1.70 m /min (60 ft /min) for
EPA-600/9-76-005 Quality Assurance Handbook for Air
3 3
24 h, this is equivalent to 1 μg ⁄m to 2 μg ⁄m (3).
Pollution Measurement Systems, Vol I, Principles (De-
cember 1984 Rev.)
1.4 The sample that is collected may be subjected to further
EPA-600/4-77-027a Quality Assurance Handbook for Air
analyses by a variety of methods for specific constituents.
Pollution Measurement Systems, Vol II, Ambient Air
1.5 The values stated in SI units are to be regarded as
Specific Methods
standard. The values given in parentheses are mathematical
conversions to inch-pound units that are provided for informa-
3. Terminology
tion only and are not considered standard.
3.1 Definitions—For definitions of other terms used in this
1.6 This standard does not purport to address all of the
test method, refer to Terminology D1356.
safety concerns, if any, associated with its use. It is the
3.2 Definitions of Terms Specific to This Standard:
responsibility of the user of this standard to establish appro-
3.2.1 absolute filter, n—a filter or filter medium of ultra-high
priate safety, health, and environmental practices and deter-
collection efficiency for very small particles (submicrometre
mine the applicability of regulatory limitations prior to use.
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
This test method is under the jurisdiction of ASTM Committee D22 on Air contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Quality and is the direct responsibility of Subcommittee D22.03 on Ambient Standards volume information, refer to the standard’s Document Summary page on
Atmospheres and Source Emissions. the ASTM website.
Current edition approved Nov. 1, 2023. Published December 2023. Originally The last approved version of this historical standard is referenced on
approved in 1982. Last previous edition approved in 2017 as D4096 – 17. DOI: www.astm.org.
10.1520/D4096-17R23. Available from United States Environmental Protection Agency (EPA), William
The boldface numbers in parentheses refer to a list of references at the end of Jefferson Clinton Bldg., 1200 Pennsylvania Ave., NW, Washington, DC 20460,
this standard. http://www.epa.gov.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
D4096 − 17 (2023)
size) so that essentially all particles of interest or of concern are physical and chemical parameters of the collected particulate
collected. Commonly, the efficiency is in the region of 99.95 % matter are dependent upon the physical characteristics of the
or higher for a standard aerosol of 0.3 μm diameter (see collection system and the choice of filter media. A variety of
Practice D2986). options available for the Hi-Vol sampler give it broad versa-
tility and allow the user to develop information about the size
3.2.2 constant flow high-volume sampler, n—a high volume
and quantity of airborne particulate material and, using subse-
sampler that is equipped with a constant flow control device.
quent chemical analytical techniques, information about the
3.2.3 Hi-Vol (the high-volume air sampler), n—a device for
chemical properties of the particulate matter.
sampling large volumes of an atmosphere, collection of the
contained particulate matter by filtration, and consisting of a
5.2 This test method presents techniques that when uni-
high-capacity air mover, a filter to collect suspended particles,
formly applied, provide measurements suitable for intersite
and means for measuring, or controlling, or both, the flow rate. comparisons.
3.2.4 primary flow-rate standard, n—a device or means of
5.3 This test method measures the atmosphere presented to
measuring flow rate based on direct primary observations, such
the sampler with good precision, but the actual dust levels in
as time and physical dimensions.
the atmosphere can vary widely from one location to another.
3.2.5 secondary flow-rate standard, n—a flow-rate-
This means that sampler location may be of paramount
measuring device, such as an orifice meter, that has been
importance, and may impose far greater variability of results
calibrated against a primary standard.
than any lack of precision in the method of measurement. In
particular, localized dust sources may exert a major influence
3.2.6 spirometer, n—a displacement gasometer consisting of
an inverted bell resting upon or sealed by liquid (or other over a very limited area immediately adjacent to such sources.
Examples include unpaved streets, vehicle traffic on roadways
means) and capable of showing the amount of gas added to or
withdrawn from the bell by the displacement (rise or fall) of the with a surface film of dust, building demolition and construc-
tion activity, or nearby industrial plants with dust emissions. In
bell.
some cases, dust levels measured close to such sources may be
3.2.7 working flow-rate standard, n—a flow rate measuring
several times the community wide levels exclusive of such
device, such as an orifice meter, that has been calibrated
localized effects (see Practice D1357).
against a secondary flow-rate standard. The working flow-rate
standard is used to calibrate a flow measuring or flow rate
6. Interferences
indicating instrument.
6.1 Large extraneous objects, such as insects, may be swept
4. Summary of Test Method
into the filter and become weighed unnoticed.
4.1 This test method describes typical equipment, opera-
6.2 Liquid aerosols, such as oil mists and fog droplets, are
tional procedures, and a means of calibration of the equipment
using an orifice flowrate meter. (See also Annex A1.) retained by the filter. If the amount of liquid so collected is
sizable, the filter can become wet and its function and mass
4.2 Air is drawn into a covered housing and through a filter
impaired.
by means of a high-flow-rate air mover, so that particulate
material collects on the filter surface.
6.3 Any gaseous or vaporous constituent of the atmosphere
under test that is reactive with or sorptive upon the filter or its
4.3 The amount of particulate matter accumulated on the
collected matter will be retained and weighed as particulate
filter over a specified period of time is measured by weighing
matter.
a preweighed filter after exposure. The flow rate of air sampled
is measured over the test period. The result is expressed in
6.4 As the filter becomes loaded with collected matter, the
terms of particulate mass collected (or loading) per unit volume
sampling rate is reduced. If a significant drop in flow rate
of air sampled, usually as micrograms per cubic metre (μg/m ).
occurs, the average of the initial and final flow rate calculated
The volume of air sampled is recorded by measurement of the
in 10.1 will not give an accurate estimate of total flow during
device flow rate(s).
the sampling period. The magnitude of such errors will depend
4.4 The volume of air sampled is determined by means of a
on the amount of reduction of airflow rate and on the variation
flow-rate indicator. The instrument flow-rate indicator is cali-
of the mass concentration of dust with time during the 24-h
brated against a reference orifice meter. The latter is a working
sampling period. As an approximate guideline, any sample
standard which, in turn, has been calibrated against a secondary
should be suspect if the final flow rate is less than one half the
flow meter certified by the U.S. National Institute of Standards
initial rate. A continuous record of flow rate will indicate the
and Technology.
occurrence of this problem, or a constant-flow high-volume
sampler may be used to eliminate the problem.
4.5 Airborne particulate matter retained on the filter may be
examined or analyzed by a variety of methods. Specific
6.5 The possibility of power failure or voltage change
procedures are not included in this method but are the subject
during the test period would lead to an error, depending on the
of separate standard methods.
extent and time duration of such failure. A continuous record of
flow rate is desirable.
5. Significance and Use
5.1 The Hi-Vol sampler is commonly used for the collection 6.6 The passive loading of the filter that can occur if it is left
of the airborne particulate component of the atmosphere. Some in place for any time prior to or following a sampling period
D4096 − 17 (2023)
can introduce significant error. For unattended operation, a five flow-control plates. These kits are available from most
sampler equipped with shutters shall be used. supply houses that deal in apparatus for air sampling and
analysis.
6.7 If two or more samplers are used at a given location,
they should be placed at least 2 m (6 ft) apart so that one
7.3 A large desiccator or air conditioned room is required
sampler will not affect the results of an adjacent sampler.
for filter conditioning, storage, and weighing. Filters must be
stored and conditioned at a temperature of 15 °C to 27 °C and
6.8 Wind tunnel studies have shown significant possible
a relative humidity between 0 % and 50 %.
sampling errors as a function of sampler orientation in atmo-
spheres containing high relative concentrations of large par-
7.4 An analytical balance capable of reading to 0.1 mg, and
ticles (5).
having a capacity of at least 5 g is necessary. It is very desirable
to have a weighing chamber of adequate size with a support
6.9 Metal dusts from motors, especially copper, may sig-
nificantly contaminate samples under some conditions. that is capable of accommodating the filter without rolling or
folding it or exposing it to drafts during the weighing opera-
6.10 Under some conditions, atmospheric SO and NO
2 x
tion.
may interfere with the total mass determination (6).
7.5 Barograph or Barometer, capable of measuring to the
7. Apparatus
nearest 0.1 kPa (1 mm Hg) meeting the requirements of Test
Methods D3631.
7.1 The essential features of a typical high-volume sampler
are shown in the diagram of Fig. 1 and Fig. 2. It is a compact
7.6 Thermometer—ASTM Thermometer 33C, meeting the
unit consisting of a protective housing, an electric motor-
requirements of Specification E1.
driven, high-speed, high-volume air mover, a filter holder
7.7 Clock, capable of indicating 24 h 6 2 min.
capable of supporting a 203 mm by 254 mm (8-in. by 10-in.)
filter at the forward or entrance end, and at the exit end, means
7.8 Flow-Rate Recorder, capable of recording to the nearest
for either indicating or controlling the air flow rate, or both, 3 3
0.03 m /min (1.0 ft /min).
3 3 3
over the range of 1.13 m /min to 1.70 m /min (40 ft /min to
7.9 Differential Manometer, capable of measuring to 4 kPa
60 ft /min). Designs also exist in which a flow controller is
(40 mm Hg).
located between the filter and the blower. For unattended
operation, a sampler equipped with shutters to protect the filter
8. Reagents and Materials
is required.
7.2 A calibrator kit is required. This contains a working
8.1 Filter Medium:
flow-rate standard of appropriate range in the form of an orifice
8.1.1 In general, the choice of a filter medium will depend
with its own calibration curve. The kit includes also a set of
on the purpose of the test. For any given standard test method
the appropriate medium will be specified. However, it is
important to be aware of certain filter characteristics that can
affect selection and use.
8.1.2 Glass-Fiber Filter Medium—This type is most widely
used for determination of mass loading. Weight stability with
respect to moisture is an attractive feature. High-efficiency or
absolute types are preferred and will collect all airborne
particles of practically every size and description. The follow-
ing characteristics are typical:
Fiber content All-glass-usually mixed sizes
Binder Below 5 % (zero for binderless types)
Thickness Approximately 0.5 mm
Pinholes None
DOP smoke test (Practice 0.05 % penetration, 981 Pa (100 mm of water)
D2986) at 8.53 m/min (28 ft/min)
Particulate matter collected on glass-fiber medium can be
analyzed for many constituents. If chemical analysis is con-
templated binderless filters should be used. It must be borne in
mind, however, that glass is a commercial
...

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5.1 This test method is applicable to the measurement of airborne asbestos in a wide range of ambient air situations and for detailed evaluation of any atmosphere for asbestos structures. Most fibers in ambient atmospheres are not asbestos, and therefore, there is a requirement for fibers to be identified. Most of the airborne asbestos fibers in ambient atmospheres have diameters below the resolution limit of the light microscope. This test method is based on transmission electron microscopy, which has adequate resolution to allow detection of small thin fibers and is currently the only technique capable of unequivocal identification of the majority of individual fibers of asbestos. Asbestos is often found, not as single fibers, but as very complex, aggregated structures, which may or may not also be aggregated with other particles. The fibers found suspended in an ambient atmosphere can often be identified unequivocally if sufficient measurement effort is expended. However, if each fiber were to be identified in this way, the analysis would become prohibitively expensive. Because of instrumental deficiencies or because of the nature of the particulate matter, some fibers cannot be positively identified as asbestos even though the measurements all indicate that they could be asbestos. Therefore, subjective factors contribute to this measurement, and consequently, a very precise definition of the procedure for identification and enumeration of asbestos fibers is required. The method defined in this test method is designed to provide a description of the nature, numerical concentration, and sizes of asbestos-containing particles found in an air sample. The test method is necessarily complex because the structures observed are frequently very complex. The method of data recording specified in the test method is designed to allow reevaluation of the structure-counting data as new applications for measurements are developed. All of the feasible specimen preparation techn...
SCOPE
1.1 This test method2 is an analytical procedure using transmission electron microscopy (TEM) for the determination of the concentration of asbestos structures in ambient atmospheres and includes measurement of the dimension of structures and of the asbestos fibers found in the structures from which aspect ratios are calculated.  
1.1.1 This test method allows determination of the type(s) of asbestos fibers present.  
1.1.2 This test method cannot always discriminate between individual fibers of the asbestos and non-asbestos analogues of the same amphibole mineral.  
1.2 This test method is suitable for determination of asbestos in both ambient (outdoor) and building atmospheres.  
1.2.1 This test method is defined for polycarbonate capillary-pore filters or cellulose ester (either mixed esters of cellulose or cellulose nitrate) filters through which a known volume of air has been drawn and for blank filters.  
1.3 The upper range of concentrations that can be determined by this test method is 7000 s/mm2. The air concentration represented by this value is a function of the volume of air sampled.  
1.3.1 There is no lower limit to the dimensions of asbestos fibers that can be detected. In practice, microscopists vary in their ability to detect very small asbestos fibers. Therefore, a minimum length of 0.5 μm has been defined as the shortest fiber to be incorporated in the reported results.  
1.4 The direct analytical method cannot be used if the general particulate matter loading of the sample collection filter as analyzed exceeds approximately 10 % coverage of the collection filter by particulate matter.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropri...

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ASTM
ASTM D5953M-23(Test Method)
Standard Test Method for Determination of Non-methane Organic Compounds (NMOC) in Ambient Air Using Cryogenic Preconcentration and Direct Flame Ionization Detection

SIGNIFICANCE AND USE
5.1 Many regulators, industrial processes, and other stakeholders require determination of NMOC in atmospheres.  
5.2 Accurate measurements of ambient NMOC concentrations are critical in devising air pollution control strategies and in assessing control effectiveness because NMOCs are primary precursors of atmospheric ozone and other oxidants (7, 8).  
5.2.1 The NMOC concentrations typically found at urban sites may range up to 1 ppm C to 3 ppm C or higher. In order to determine transport of precursors into an area monitoring site, measurement of NMOC upwind of the site may be necessary. Rural NMOC concentrations originating from areas free from NMOC sources are likely to be less than a few tenths of 1 ppm C.  
5.3 Conventional test methods based upon gas chromatography and qualitative and quantitative species evaluation are relatively time consuming, sometimes difficult and expensive in staff time and resources, and are not needed when only a measurement of NMOC is desired. The test method described requires only a simple, cryogenic pre-concentration procedure followed by direct detection with an FID. This test method provides a sensitive and accurate measurement of ambient total NMOC concentrations where speciated data are not required. Typical uses of this standard test method are as follows.  
5.4 An application of the test method is the monitoring of the cleanliness of canisters.  
5.5 Another use of the test method is the screening of canister samples prior to analysis.  
5.6 Collection of ambient air samples in pressurized canisters provides the following advantages:  
5.6.1 Convenient collection of integrated ambient samples over a specific time period,  
5.6.2 Capability of remote sampling with subsequent central laboratory analysis,  
5.6.3 Ability to ship and store samples, if necessary,  
5.6.4 Unattended sample collection,  
5.6.5 Analysis of samples from multiple sites with one analytical system,  
5.6.6 Collection of replicate samples for ...
SCOPE
1.1 This test method2 presents a procedure for sampling and determination of non-methane organic compounds (NMOC) in ambient, indoor, or workplace atmospheres.  
1.2 This test method describes the collection of integrated whole air samples in silanized or other passivated stainless steel canisters, and their subsequent laboratory analysis.  
1.2.1 This test method describes a procedure for sampling in canisters at final pressures above atmospheric pressure (pressurized sampling).  
1.3 This test method employs a cryogenic trapping procedure for concentration of the NMOC prior to analysis.  
1.4 This test method describes the determination of the NMOC by the flame ionization detection (FID), without the use of gas chromatographic columns and other procedures necessary for species separation.  
1.5 The range of this test method is from 20 ppb C to 10 000 ppb C (1, 2).3  
1.6 This test method has a larger uncertainty for some halogenated or oxygenated hydrocarbons than for simple hydrocarbons or aromatic compounds. This is especially true if there are high concentrations of chlorocarbons or chlorofluorocarbons present.  
1.7 The values stated in SI units are to be regarded as standard. The values given in parentheses are mathematical conversions to inch-pound units that are provided for information only and are not considered standard.  
1.8 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.9 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Techn...

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ASTM
ASTM D8141-22(Guide)
Standard Guide for Selecting Volatile Organic Compounds (VOCs) and Semi-Volatile Organic Compounds (SVOCs) Emission Testing Methods to Determine Emission Parameters for Modeling of Indoor Environments

SIGNIFICANCE AND USE
4.1 Emissions of VOCs are typically controlled by internal mass-transfer limitations (for example, diffusion through the material), while emissions of SVOCs are typically controlled by external mass-transfer limitations (migration through the air immediately above the material). The emission of some chemicals may be controlled by both internal and external mass-transfer limitations. In addition, due to their lower vapor pressure, SVOCs generally adsorb to different media (chamber walls, building materials, particles, and other surfaces) at greater rates than VOCs. This sorption can increase the amount of time required to reach steady-state SVOC concentrations using conventional VOC emission test methods to months for a single test (2).  
4.2 Thus, existing methods for characterizing emissions of VOCs may not be appropriate or practical to properly characterize emission rates of SVOCs for use in modeling SVOC concentrations in indoor environments. A mass-transfer framework is needed to accurately assess emission rates of SVOCs when predicting the SVOC indoor air concentrations in indoor environments. The SVOC mass-transfer framework includes SVOC emission characteristics and its partition to multimedia including sorption to indoor surfaces, airborne particles, and settled dust. Once the SVOC emission parameters and partitioning coefficients have been determined, these values can be used to modeling SVOC indoor concentrations.
SCOPE
1.1 This guide is intended to serve as a foundation for understanding when to use emission testing methods designed for volatile organic compounds (VOCs) to determine area-specific emission rates that are typically used in modeling indoor air VOC concentrations and when to use emission testing methods designed for semi-volatile organic compounds (SVOCs) to determine mass transfer emission parameters that are typically used to model indoor air, dust, and surface SVOC concentrations.  
1.2 This guide discusses how organic chemicals are conventionally categorized with respect to volatility.  
1.3 This guide presents a simplified mass-transfer model describing organic chemical emissions from a material to bulk air. The values of the model parameters are shown to be specific to material/chemical/chamber combinations.  
1.4 This guide shows how to use a mass-transfer model to estimate whether diffusion of the chemical within the material or convective mass transfer of the chemical from the surface of the material to the overlying air limits chemical emissions from the material surface.  
1.5 This guide describes the range of different chambers that are available for emission testing. The chambers are classified as either dynamic or static and either conventional or sandwich. The chambers are categorized as being optimal to determine either the area-specific emission rate or mass-transfer emission parameters.  
1.6 This guide discusses the roles sorption and convective mass-transfer coefficients play in selecting the appropriate emission chamber and analysis method to accurately and efficiently characterize emissions from indoor materials for use in modeling indoor chemical concentrations.  
1.7 This guide recommends when to choose an emission test method that is optimized to determine either the area-specific emission rate or mass-transfer emission parameters. For chemicals where the controlling mass-transfer process is unknown, the guide outlines a procedure to determine if the chemical emission is controlled by convective mass transfer of the chemical from the material.  
1.8 This guide does not provide specific guidance for measuring emission parameters or conducting indoor exposure modeling.  
1.9 Mechanisms controlling emissions from wet and dry materials and products are different. This guide considers the emission of chemicals from dry materials and products. Examples of functional uses of VOCs and SVOCs that this guide applies to include blowing agents, ...

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ASTM
ASTM D8445-22a(Practice)
Standard Practice for Measuring Chemical Emissions from Spray Polyurethane Foam (SPF) Insulation Samples in a Large-scale Ventilated Enclosure

SIGNIFICANCE AND USE
5.1 The demand for SPF insulation in homes and commercial buildings has increased as emphasis on energy efficiency increases. In an effort to protect the health and safety of both trade workers and building occupants due to the application of SPF, it is essential that reentry/reoccupancy-times into the structure where SPF has been applied, be established.  
5.2 Concentrations of chemical emissions determined in large-scale ventilated enclosure studies conducted by this practice may be used to generate source emission terms for IAQ models.  
5.3 The emission factors determined using this practice may be used to evaluate comparability and scalability of emission factors determined in other environments.  
5.4 This practice was designed to determine emission factors for chemicals emitted by SPF insulation in a controlled room environment.  
5.5 New or existing formulations may be sprayed, and emissions may be evaluated by this practice. The user of this practice is responsible for ensuring analytical methods are appropriate for novel compounds present in new formulations (see Appendix X1 for target compounds and generic formulations).  
5.6 This practice may be useful for testing variations in emissions from non-ideal applications. Examples of non-ideal applications include those that are off-ratio, applied outside of recommended range of temperature and relative humidity, or applied outside of manufacturer recommendations for thickness.  
5.7 The determined emission factors are not directly applicable to all potential real-world applications of SPF. While this data can be used for VOCs to estimate indoor environmental concentrations beyond three days, the uncertainty in the predicted concentrations increases with increasing time. Estimating longer term chemical concentrations (beyond three days) for SVOCs is not recommended unless additional data (beyond this practice) is used, see (1).4  
5.8 During the application of SPF, chemicals deposited on the non-applie...
SCOPE
1.1 This practice describes procedures for measuring the chemical emissions of volatile and semi-volatile organic compounds (VOCs and SVOCs) from spray polyurethane foam (SPF) insulation samples in a large-scale ventilated enclosure.  
1.2 This practice is used to identify emission rates and factors during SPF application and up to three days following application.  
1.3 This practice can be used to generate emissions data for research activities or modeled for the purpose to inform potential reentry and reoccupancy times. Potential reentry and re-occupancy times only apply to the applications that meet manufacturer guidelines and are specific to the tested formulation.  
1.4 This practice describes emission testing at ambient room and substrate temperature and relative humidity conditions recognizing chemical emissions may differ at different room and substrate temperatures and relative humidity.  
1.5 This practice does not address all SPF chemical emissions. This practice addresses specific chemical compounds of potential health and regulatory concern including methylene diphenyl diisocyanate (MDI), polymeric MDI (MDI oligomeric polyisocyanates mixture), flame retardants, aldehydes, and VOCs including blowing agents, and catalysts. Although specific chemicals are discussed in this practice, other chemical compounds of interest can be quantified (see target compound and generic formulation list in Appendix X1). Other chemical compounds used in SPF such as polyols, emulsifiers, and surfactants are not addressed by this practice. Particulate sizing and distribution are also outside the scope of this practice.  
1.6 Emission rates during application are determined from air phase concentration measurements that may include particle bound chemicals. SVOC deposition to floors and ceilings is also quantified for post application modeling inputs. SVOC emission rates should only be used for modeling purposes for the durati...

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ASTM
ASTM D5110-22a(Practice)
Standard Practice for Calibration of Ozone Monitors and Certification of Ozone Transfer Standards Using Ultraviolet Photometry

SIGNIFICANCE AND USE
5.1 The reactivity and instability of O3 preclude the storage of O3 concentration standards for any practical length of time, and precludes direct certification of O3 concentrations as Standard Reference Materials (SRMs). Moreover, there is no available SRM that can be readily and directly adapted to the generation of O3 standards analogous to permeation devices and standard gas cylinders for sulfur dioxide and nitrogen oxides. Dynamic generation of O3 concentrations is relatively easy with a source of ultraviolet (UV) radiation. However, accurately certifying an O3 concentration as a primary standard requires assay of the concentration by a comprehensively specified analytical procedure, which must be performed every time a standard is needed (10).  
5.2 This practice is not designed for the routine calibration of O3 monitors at remote locations (see Practices D5011).
SCOPE
1.1 This practice covers a means for calibrating ambient, workplace, or indoor ozone monitors, and for certifying transfer standards to be used for that purpose.  
1.2 This practice describes means by which dynamic streams of ozone in air can be designated as primary ozone standards.  
1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. See Section 8 for specific precautionary statements.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM D6327-10(2021)(Test Method)
Standard Test Method for Determination of Radon Decay Product Concentration and Working Level in Indoor Atmospheres by Active Sampling on a Filter

SIGNIFICANCE AND USE
5.1 The test method provides a relatively simple method for determination of the concentration of RDP without the need for specialty equipment built expressly for such purposes.  
5.2 Using this test method will afford investigators of radon in dwellings a technique by which the RDP can be determined. The use of the results of this test method are generally for diagnostic purposes and are not necessarily indicative of results that might be obtained by longer term measurement methods.  
5.3 An improved understanding of the frequency of elevated radon in buildings and the health effect of exposure has increased the importance of knowledge of actual exposures. The measurement of RDP, which are the direct cause of potential adverse health effects, should be conducted in a manner that is uniform and reproducible; it is to this end that this test method is addressed.
SCOPE
1.1 This test method provides instruction for using the grab sampling filter technique to determine accurate and reproducible measurements of indoor radon decay product (RDP) concentrations and of the working level (WL) value corresponding to those concentrations.  
1.2 Measurements made in accordance with this test method will produce RDP concentrations representative of closed-building conditions. Results of measurements made under closed-building conditions will have a smaller variability and are more reproducible than measurements obtained when building conditions are not controlled. This test method may be utilized under non-controlled conditions, but a greater degree of variability in the results will occur. Variability in the results may also be an indication of temporal variability present at the sampling site.  
1.3 This test method utilizes a short sampling period and the results are indicative of the conditions only at the place and time of sampling. The results obtained by this test method are not necessarily indicative of longer terms of sampling and should not be confused with such results. The averaging of multiple measurements over hours and days can, however, provide useful screening information. Individual measurements are generally obtained for diagnostic purposes.  
1.4 The range of the test method may be considered from 0.0005 WL to unlimited working levels, and from 40 Bq/m3 to unlimited for each individual radon decay product.  
1.5 This test method provides information on equipment, procedures, and quality control. It provides for measurements within typical residential or building environments and may not necessarily apply to specialized circumstances, for example, clean rooms.  
1.6 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.7 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. See Section 9 for additional precautions  
1.8 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM D8407-21(Guide)
Standard Guide for Measurement Techniques for Formaldehyde in Air

SIGNIFICANCE AND USE
5.1 The objective of this guide is to provide the user with an information base on commercially available instruments and technologies that can be used to measure indoor air formaldehyde concentrations.  
5.2 This guide is intended as a repository for formaldehyde measurement technologies that other approved ASTM methods can reference to meet ASTM indoor air formaldehyde quantification needs.  
5.3 This guide does not discuss the equivalency of the technologies presented. Each technology may have positive or negative interferences that are unique to that technology. When using a new method, equivalence with old methods should be demonstrated for each matrix, measuring environment and media (that is, each type of wood for formaldehyde emission testing in chamber environments). This is especially true when the method is intended to generate regulatory compliance data. Demonstrating equivalence or compliance, or both, is beyond the scope of this method. For guidance equivalence see references such as 40 CFR § 136.6 and CEN Guide to the Demonstration of Equivalence of Ambient Air Monitoring Methods (1).5
SCOPE
1.1 This guide describes analytical methods for determining formaldehyde concentrations in air.  
1.2 The guide is primarily focused on formaldehyde measurement technologies applicable to indoor (including in vehicle and workplace) air and associated environments (that is, chambers or bags, or both, used for formaldehyde emission testing). The described technologies may be applicable to other environments (ambient outdoor).  
1.3 This guide reviews a range of commercially available technologies that can be used to measure indoor air formaldehyde concentrations. These technologies typically can measure airborne formaldehyde concentrations with detection limits in the range of 0.04 ppbv (0.05 µg m-3) to 10 ppbv (12 µg m-3). The described technologies are typically applied to research or regulatory applications and not consumer level uses.  
1.4 This guide describes the principles behind each method and their advantages and limitations.  
1.5 This guide does not attempt to differentiate between the effectiveness of the methods nor determine equivalence of the methods.  
1.6 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.7 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.8 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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