40 CFR Part 763 (EPA AHERA)_Part 8.pdf

Full Transcript

Environmental Protection Agency

Pt. 763, Subpt. E, App. C

the requirements of this MAP until the
State adopts an accreditation plan that is at
least as stringent as this MAP.
4. A State that had complied with an earlier version of the MAP, but fails to adopt a
plan as stringent as this MAP by the deadline established in Unit V.A.1., is subject to
the following after that deadline date:
a. The State loses any status it may have
held as an EPA-approved State for accreditation purposes under section 206 of TSCA, 15
U.S.C. 2646.
b. All training course providers approved
by the State lose State approval to conduct
training and issue accreditation that satisfies the requirements for TSCA accreditation
under this MAP.
c. The State may not:
i. Conduct training for accreditation purposes under section 206 of TSCA, 15 U.S.C.
2646.
ii. Approve training course providers to
conduct training or issue accreditation that
satisfies the requirements for TSCA accreditation; or
iii. Issue accreditation that satisfies the
requirement for TSCA accreditation.
EPA will extend EPA-approval to any
training course provider that loses State approval because the State does not comply
with the deadline, so long as the provider is
in compliance with Unit V.B. of this MAP,
and the provider is approved by a State that
had complied with an earlier version of the
MAP as of the day before the State loses its
EPA approval.
5. A State that does not have an accreditation program that satisfies the requirements
for TSCA accreditation under either an earlier version of the MAP or this MAP, may
not:
a. Conduct training for accreditation purposes under section 206 of TSCA, 15 U.S.C.
2646;
b. Approve training course providers to
conduct training or issue accreditation that
satisfies the requirements for TSCA accreditation; or
c. Issue accreditation that satisfies the requirement for TSCA accreditation.

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B. Requirements applicable to Training
Courses and Providers
As of October 4, 1994, an approved training
provider must certify to EPA and to any
State that has approved the provider for
TSCA accreditation, that each of the provider’s training courses complies with the requirements of this MAP. The written submission must document in specific detail the
changes made to each training course in
order to comply with the requirements of
this MAP and clearly state that the provider
is also in compliance with all other requirements of this MAP, including the new recordkeeping and certificate provisions. Each
submission must include the following state-

ment signed by an authorized representative
of the training provider: ‘‘Under civil and
criminal penalties of law for the making or
submission of false or fraudulent statements
or representations (18 U.S.C. 1001 and 15
U.S.C. 2615), I certify that the training described in this submission complies with all
applicable requirements of Title II of TSCA,
40 CFR part 763, Appendix C to Subpart E, as
revised, and any other applicable Federal,
state, or local requirements.’’ A consolidated
self-certification submission from each
training provider that addresses all of its approved training courses is permissible and
encouraged.
The self-certification must be sent via registered mail, to EPA Headquarters at the following address: Attn. Self-Certification Program, Field Programs Branch, Chemical
Management Division (7404), Office of Pollution Prevention and Toxics, Environmental
Protection Agency, 1200 Pennsylvania Ave.,
NW., Washington, DC 20460. A duplicate copy
of the complete submission must also be sent
to any States from which approval had been
obtained.
The timely receipt of a complete self-certification by EPA and all approving States
shall have the effect of extending approval
under this MAP to the training courses offered by the submitting provider. If a selfcertification is not received by the approving
government bodies on or before the due date,
the affected training course is not approved
under this MAP. Such training providers
must then reapply for approval of these
training courses pursuant to the procedures
outlined in Unit III.
C. Requirements applicable to Accredited
Persons.
Persons accredited by a State with an accreditation program no less stringent than
an earlier version of the MAP or by an EPAapproved training provider as of April 3, 1994,
are accredited in accordance with the requirements of this MAP, and are not required to retake initial training. They must
continue to comply with the requirements
for annual refresher training in Unit I.D. of
the revised MAP.
D. Requirements applicable to NonAccredited Persons.
In order to perform work requiring accreditation under TSCA Title II, persons who are
not accredited by a State with an accreditation program no less stringent than an earlier version of the MAP or by an EPA-approved training provider as of April 3, 1994,
must comply with the upgraded training requirements of this MAP by no later than October 4, 1994. Non-accredited persons may obtain initial accreditation on a provisional
basis by successfully completing any of the
training programs approved under an earlier

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Pt. 763, Subpt. E, App. D

40 CFR Ch. I (7–1–07 Edition)

version of the MAP, and thereby perform
work during the first 6 months after this
MAP takes effect. However, by October 4,
1994, these persons must have successfully
completed an upgraded training program
that fully complies with the requirements of
this MAP in order to continue to perform
work requiring accreditation under section
206 of TSCA, 15 U.S.C. 2646.
[59 FR 5251, Feb. 3, 1994, as amended at 60 FR
31922, June 19, 1995; 70 FR 59889, Oct. 13, 2005]

APPENDIX D TO SUBPART E OF PART
763—TRANSPORT AND DISPOSAL OF
ASBESTOS WASTE
For the purposes of this appendix, transport is defined as all activities from receipt
of the containerized asbestos waste at the
generation site until it has been unloaded at
the disposal site. Current EPA regulations
state that there must be no visible emissions
to the outside air during waste transport.
However, recognizing the potential hazards
and subsequent liabilities associated with
exposure, the following additional precautions are recommended.
Recordkeeping. Before accepting wastes, a
transporter should determine if the waste is
properly wetted and containerized. The
transporter should then require a chain-ofcustody form signed by the generator. A
chain-of-custody form may include the name
and address of the generator, the name and
address of the pickup site, the estimated
quantity of asbestos waste, types of containers used, and the destination of the
waste. The chain-of-custody form should
then be signed over to a disposal site operator to transfer responsibility for the asbestos waste. A copy of the form signed by the
disposal site operator should be maintained
by the transporter as evidence of receipt at
the disposal site.
Waste handling. A transporter should ensure that the asbestos waste is properly contained in leak-tight containers with appropriate labels, and that the outside surfaces of
the containers are not contaminated with asbestos debris adhering to the containers. If
there is reason to believe that the condition
of the asbestos waste may allow significant
fiber release, the transporter should not accept the waste. Improper containerization of
wastes is a violation of the NESHAPs regulation and should be reported to the appropriate EPA Regional Asbestos NESHAPs
contact below:

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Region I
Asbestos NESHAPs Contact, Air Management Division, USEPA, Region I, JFK Federal Building, Boston, MA 02203, (617) 223–
3266.

Region II
Asbestos NESHAPs Contact, Air & Waste
Management Division, USEPA, Region II, 26
Federal Plaza, New York, NY 10007, (212) 264–
6770.
Region III
Asbestos NESHAPs Contact, Air Management Division, USEPA, Region III, 841 Chestnut Street, Philadelphia, PA 19107, (215) 597–
9325.
Region IV
Asbestos NESHAPs Contact, Air, Pesticide
& Toxic Management, USEPA, Region IV,
345 Courtland Street, NE., Atlanta, GA 30365,
(404) 347–4298.
Region V
Asbestos NESHAPs Contact, Air Management Division, USEPA, Region V, 77 West
Jackson Boulevard, Chicago, IL 60604, (312)
353–6793.
Region VI
Asbestos NESHAPs Contact, Air & Waste
Management Division, USEPA, Region VI,
1445 Ross Avenue, Dallas, TX 75202, (214) 655–
7229.
Region VII
Asbestos NESHAPs Contact, Air & Waste
Management Division, USEPA, Region VII,
726 Minnesota Avenue, Kansas City, KS 66101,
(913) 236–2896.
Region VIII
Asbestos NESHAPs Contact, Air & Waste
Management Division, USEPA, Region VIII,
999 18th Street, Suite 500, Denver, CO 80202,
(303) 293–1814.
Region IX
Asbestos NESHAPs Contact, Air Management Division, USEPA, Region IX, 215 Fremont Street, San Francisco, CA 94105, (415)
974–7633.
Region X
Asbestos NESHAPs Contact, Air & Toxics
Management Division, USEPA, Region X,
1200 Sixth Avenue, Seattle, WA 98101, (206)
442–2724.
Once the transporter is satisfied with the
condition of the asbestos waste and agrees to
handle it, the containers should be loaded
into the transport vehicle in a careful manner to prevent breaking of the containers.
Similarly, at the disposal site, the asbestos
waste containers should be transferred carefully to avoid fiber release.
Waste transport. Although there are no regulatory specifications regarding the transport vehicle, it is recommended that vehicles

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Environmental Protection Agency

Pt. 763, Subpt. E, App. D

used for transport of containerized asbestos
waste have an enclosed carrying compartment or utilize a canvas covering sufficient
to contain the transported waste, prevent
damage to containers, and prevent fiber release. Transport of large quantities of asbestos waste is commonly conducted in a 20cubic-yard ‘‘roll off’’ box, which should also
be covered. Vehicles that use compactors to
reduce waste volume should not be used because these will cause the waste containers
to rupture. Vacuum trucks used to transport
waste slurry must be inspected to ensure
that water is not leaking from the truck.
Disposal involves the isolation of asbestos
waste material in order to prevent fiber release to air or water. Landfilling is recommended as an environmentally sound isolation method because asbestos fibers are
virtually immobile in soil. Other disposal
techniques such as incineration or chemical
treatment are not feasible due to the unique
properties of asbestos. EPA has established
asbestos disposal requirements for active and
inactive disposal sites under NESHAPs (40
CFR Part 61, subpart M) and specifies general requirements for solid waste disposal
under RCRA (40 CFR Part 257). Advance EPA
notification of the intended disposal site is
required by NESHAPs.
Selecting a disposal facility. An acceptable
disposal facility for asbestos wastes must adhere to EPA’s requirements of no visible
emissions to the air during disposal, or minimizing emissions by covering the waste
within 24 hours. The minimum required
cover is 6 inches of nonasbestos material,
normally soil, or a dust-suppressing chemical. In addition to these Federal requirements, many state or local government
agencies require more stringent handling
procedures. These agencies usually supply a
list of ‘‘approved’’ or licensed asbestos disposal sites upon request. Solid waste control
agencies are listed in local telephone directories under state, county, or city headings.
A list of state solid waste agencies may be
obtained by calling the RCRA hotline: 1–800–
424–9346 (382–3000 in Washington, DC). Some
landfill owners or operators place special requirements on asbestos waste, such as placing all bagged waste into 55-gallon metal
drums. Therefore, asbestos removal contractors should contact the intended landfill before arriving with the waste.
Receiving asbestos waste. A landfill approved
for receipt of asbestos waste should require
notification by the waste hauler that the
load contains asbestos. The landfill operator
should inspect the loads to verify that asbestos waste is properly contained in leak-tight
containers and labeled appropriately. The
appropriate
EPA
Regional
Asbestos
NESHAPs Contact should be notified if the
landfill operator believes that the asbestos
waste is in a condition that may cause significant fiber release during disposal. In situ-

ations when the wastes are not properly containerized, the landfill operator should thoroughly soak the asbestos with a water spray
prior to unloading, rinse out the truck, and
immediately cover the wastes with nonasbestos material prior to compacting the
waste in the landfill.
Waste deposition and covering. Recognizing
the health dangers associated with asbestos
exposure, the following procedures are recommended to augment current federal requirements:
• Designate a separate area for asbestos
waste disposal. Provide a record for future
landowners that asbestos waste has been buried there and that it would be hazardous to
attempt to excavate that area. (Future regulations may require property deeds to identify the location of any asbestos wastes and
warn against excavation.)
• Prepare a separate trench to receive asbestos wastes. The size of the trench will depend upon the quantity and frequency of asbestos waste delivered to the disposal site.
The trenching technique allows application
of soil cover without disturbing the asbestos
waste containers. The trench should be
ramped to allow the transport vehicle to
back into it, and the trench should be as narrow as possible to reduce the amount of
cover required. If possible, the trench should
be aligned perpendicular to prevailing winds.
• Place the asbestos waste containers into
the trench carefully to avoid breaking them.
Be particularly careful with plastic bags because when they break under pressure asbestos particles can be emitted.
• Completely cover the containerized
waste within 24 hours with a minimum of 6
inches of nonasbestos material. Improperly
containerized waste is a violation of the
NESHAPs and EPA should be notified.
However, if improperly containerized
waste is received at the disposal site, it
should be covered immediately after unloading. Only after the wastes, including properly containerized wastes, are completely
covered, can the wastes be compacted or
other heavy equipment run over it. During
compacting, avoid exposing wastes to the air
or tracking asbestos material away from the
trench.
• For final closure of an area containing
asbestos waste, cover with at least an additional 30 inches of compacted nonasbestos
material to provide a 36-inch final cover. To
control erosion of the final cover, it should
be properly graded and vegetated. In areas of
the United States where excessive soil erosion may occur or the frost line exceeds 3
feet, additional final cover is recommended.
In desert areas where vegetation would be
difficult to maintain, 3–6 inches of well graded crushed rock is recommended for placement on top of the final cover.
Controlling public access. Under the current
NESHAPs regulation, EPA does not require

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Pt. 763, Subpt. E, App. E

40 CFR Ch. I (7–1–07 Edition)

that a landfill used for asbestos disposal use
warning signs or fencing if it meets the requirement to cover asbestos wastes. However, under RCRA, EPA requires that access
be controlled to prevent exposure of the public to potential health and safety hazards at
the disposal site. Therefore, for liability protection of operators of landfills that handle
asbestos, fencing and warning signs are recommended to control public access when
natural barriers do not exist. Access to a
landfill should be limited to one or two entrances with gates that can be locked when
left unattended. Fencing should be installed
around the perimeter of the disposal site in
a manner adequate to deter access by the
general public. Chain-link fencing, 6-ft high
and topped with a barbed wire guard, should
be used. More specific fencing requirements
may be specified by local regulations. Warning signs should be displayed at all entrances
and at intervals of 330 feet or less along the
property line of the landfill or perimeter of
the sections where asbestos waste is deposited. The sign should read as follows:
ASBESTOS WASTE DISPOSAL SITE
BREATHING
ASBESTOS
DUST
MAY
CAUSE LUNG DISEASE AND CANCER
Recordkeeping. For protection from liability, and considering possible future requirements for notification on disposal site deeds,
a landfill owner should maintain documentation of the specific location and quantity of
the buried asbestos wastes. In addition, the
estimated depth of the waste below the surface should be recorded whenever a landfill
section is closed. As mentioned previously,
such information should be recorded in the
land deed or other record along with a notice
warning against excavation of the area.
[52 FR 41897, Oct. 30, 1987, as amended at 62
FR 1834, Jan. 14, 1997]

APPENDIX E TO SUBPART E OF PART
763—INTERIM METHOD OF THE DETERMINATION OF ASBESTOS IN BULK
INSULATION SAMPLES
SECTION 1. POLARIZED LIGHT MICROSCOPY

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1.1

Principle and Applicability

Bulk samples of building materials taken
for asbestos identification are first examined
for homogeneity and preliminary fiber identification at low magnification. Positive
identification of suspect fibers is made by
analysis of subsamples with the polarized
light microscope.
The principles of optical mineralogy are
well established. 1,2 A light microscope
equipped with two polarizing filters is used
to observe specific optical characteristics of
a sample. The use of plane polarized light allows the determination of refractive indices
along specific crystallographic axes. Mor-

phology and color are also observed. A retardation plate is placed in the polarized light
path for determination of the sign of elongation using orthoscopic illumination. Orientation of the two filters such that their vibration planes are perpendicular (crossed
polars)
allows
observation
of
the
birefringence and extinction characteristics
of anisotropic particles.
Quantitative analysis involves the use of
point counting. Point counting is a standard
technique in petrography for determining
the relative areas occupied by separate minerals in thin sections of rock. Background
information on the use of point counting 2
and the interpretation of point count data 3
is available.
This method is applicable to all bulk samples of friable insulation materials submitted for identification and quantitation of
asbestos components.
1.2

Range

The point counting method may be used
for analysis of samples containing from 0 to
100 percent asbestos. The upper detection
limit is 100 percent. The lower detection
limit is less than 1 percent.
1.3

Interferences

Fibrous organic and inorganic constituents
of bulk samples may interfere with the identification and quantitation of the asbestos
mineral content. Spray-on binder materials
may coat fibers and affect color or obscure
optical characteristics to the extent of
masking fiber identity. Fine particles of
other materials may also adhere to fibers to
an extent sufficient to cause confusion in
identification. Procedures that may be used
for the removal of interferences are presented in Section 1.7.2.2.
1.4

Precision and Accuracy

Adequate data for measuring the accuracy
and precision of the method for samples with
various matrices are not currently available.
Data obtained for samples containing a single asbestos type in a simple matrix are
available in the EPA report Bulk Sample
Analysis for Asbestos Content: Evaluation of
the Tentative Method.4
1.5
1.5.1

Apparatus

Sample Analysis

A low-power binocular microscope, preferably stereoscopic, is used to examine the
bulk insulation sample as received.
• Microscope: binocular, 10–45X (approximate).
• Light Source: incandescent or fluorescent.
• Forceps, Dissecting Needles, and Probes
• Glassine Paper or Clean Glass Plate

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Environmental Protection Agency

Pt. 763, Subpt. E, App. E

Compound microscope requirements: A polarized light microscope complete with polarizer, analyzer, port for wave retardation
plate, 360° graduated rotating stage, substage
condenser, lamp, and lamp iris.
• Polarized Light Microscope: described above.
• Objective Lenses: 10X, 20X, and 40X or near
equivalent.
• Dispersion Staining Objective Lens (optional)
• Ocular Lens: 10X minimum.
• Eyepiece Reticle: cross hair or 25 point
Chalkley Point Array.
• Compensator Plate: 550 millimicron retardation.
1.5.2

1.6

Reagents

Sample Preparation

Analytical Reagents

Refractive Index Liquids: 1.490–1.570, 1.590–
1.720 in increments of 0.002 or 0.004.
• Refractive Index Liquids for Dispersion Staining: high-dispersion series, 1.550, 1.605, 1.630
(optional).
• UICC Asbestos Reference Sample Set: Available from: UICC MRC Pneumoconiosis
Unit,
Llandough
Hospital,
Penarth,
Glamorgan CF6 1XW, UK, and commercial
distributors.
• Tremolite-asbestos (source to be determined)
• Actinolite-asbestos (source to be determined)
1.7

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1.7.2
1.7.2.1

• Distilled Water (optional)
• Dilute CH3COOH: ACS reagent grade (optional)
• Dilute HCl: ACS reagent grade (optional)
• Sodium metaphosphate (NaPO3)6 (optional)
1.6.2

1.7.1

Procedures

NOTE: Exposure to airborne asbestos fibers
is a health hazard. Bulk samples submitted
for analysis are usually friable and may release fibers during handling or matrix reduction steps. All sample and slide preparations
should be carried out in a ventilated hood or
glove box with continuous airflow (negative
pressure). Handling of samples without these
precautions may result in exposure of the

Sampling

Samples for analysis of asbestos content
shall be taken in the manner prescribed in
Reference 5 and information on design of
sampling and analysis programs may be
found in Reference 6. If there are any questions about the representative nature of the
sample, another sample should be requested
before proceeding with the analysis.

Sample Preparation

Sample preparation apparatus requirements will depend upon the type of insulation sample under consideration. Various
physical and/or chemical means may be employed for an adequate sample assessment.
• Ventilated Hood or negative pressure glove
box.
• Microscope Slides
• Coverslips
• Mortar and Pestle: agate or porcelain. (optional)
• Wylie Mill (optional)
• Beakers and Assorted Glassware (optional)
• Certrifuge (optional)
• Filtration apparatus (optional)
• Low temperature asher (optional)

1.6.1

analyst and contamination of samples by
airborne fibers.

Analysis

Gross Examination

Bulk samples of building materials taken
for the identification and quantitation of asbestos are first examined for homogeneity at
low magnification with the aid of a
stereomicroscope. The core sample may be
examined in its container or carefully removed from the container onto a glassine
transfer paper or clean glass plate. If possible, note is made of the top and bottom orientation. When discrete strata are identified,
each is treated as a separate material so that
fibers are first identified and quantified in
that layer only, and then the results for each
layer are combined to yield an estimate of
asbestos content for the whole sample.
1.7.2.2

Sample Preparation

Bulk materials submitted for asbestos
analysis involve a wide variety of matrix
materials. Representative subsamples may
not be readily obtainable by simple means in
heterogeneous materials, and various steps
may be required to alleviate the difficulties
encountered. In most cases, however, the
best preparation is made by using forceps to
sample at several places from the bulk material. Forcep samples are immersed in a refractive index liquid on a microscope slide,
teased apart, covered with a cover glass, and
observed with the polarized light microscope.
Alternatively, attempts may be made to
homogenize the sample or eliminate interferences before further characterization. The
selection of appropriate procedures is dependent upon the samples encountered and
personal preference. The following are presented as possible sample preparation steps.
A mortar and pestle can sometimes be used
in the size reduction of soft or loosely bound
materials though this may cause matting of
some samples. Such samples may be reduced
in a Wylie mill. Apparatus should be clean
and extreme care exercised to avoid crosscontamination of samples. Periodic checks
of the particle sizes should be made during
the grinding operation so as to preserve any
fiber bundles present in an identifiable form.
These procedures are not recommended for
samples that contain amphibole minerals or

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Pt. 763, Subpt. E, App. E

40 CFR Ch. I (7–1–07 Edition)
of 500 °C or lower. Temperatures of 550 °C or
higher will cause dehydroxylation of the asbestos minerals, resulting in changes of the
refractive index and other key parameters. If
a muffle furnace is to be used, the furnace
thermostat should be checked and calibrated
to ensure that samples will not be heated at
temperatures greater than 550 °C.
Ashing and acid treatment of samples
should not be used as standard procedures. In
order to monitor possible changes in fiber
characteristics, the material should be
viewed microscopically before and after any
sample preparation procedure. Use of these
procedures on samples to be used for quantitation requires a correction for percent
weight loss.

vermiculite. Grinding of amphiboles may result in the separation of fiber bundles or the
production of cleavage fragments with aspect ratios greater than 3:1. Grinding of
vermiculite may also produce fragments
with aspect ratios greater than 3:1.
Acid treatment may occasionally be required to eliminate interferences. Calcium
carbonate, gypsum, and bassanite (plaster)
are frequently present in sprayed or
trowelled insulations. These materials may
be removed by treatment with warm dilute
acetic acid. Warm dilute hydrochloric acid
may also be used to remove the above materials. If acid treatment is required, wash the
sample at least twice with distilled water,
being careful not to lose the particulates
during decanting steps. Centrifugation or filtration of the suspension will prevent significant fiber loss. The pore size of the filter
should be 0.45 micron or less. Caution: prolonged acid contact with the sample may
alter the optical characteristics of chrysotile
fibers and should be avoided.
Coatings and binding materials adhering to
fiber surfaces may also be removed by treatment with sodium metaphosphate.7 Add 10
mL of 10g/L sodium metaphosphate solution
to a small (0.1 to 0.5 mL) sample of bulk material in a 15-mL glass centrifuge tube. For
approximately 15 seconds each, stir the mixture on a vortex mixer, place in an ultrasonic bath and then shake by hand. Repeat
the series. Collect the dispersed solids by
centrifugation at 1000 rpm for 5 minutes.
Wash the sample three times by suspending
in 10 mL distilled water and recentrifuging.
After washing, resuspend the pellet in 5 mL
distilled water, place a drop of the suspension on a microscope slide, and dry the slide
at 110 °C.
In samples with a large portion of cellulosic or other organic fibers, it may be useful to ash part of the sample and view the
residue. Ashing should be performed in a low
temperature asher. Ashing may also be performed in a muffle furnace at temperatures

1.7.2.3

Fiber Identification

Positive identification of asbestos requires
the determination of the following optical
properties.
• Morphology
• Color and pleochroism
• Refractive indices
• Birefringence
• Extinction characteristics
• Sign of elongation
Table 1–1 lists the above properties for commercial asbestos fibers. Figure 1–1 presents a
flow diagram of the examination procedure.
Natural variations in the conditions under
which deposits of asbestiform minerals are
formed will occasionally produce exceptions
to the published values and differences from
the UICC standards. The sign of elongation is
determined by use of the compensator plate
and crossed polars. Refractive indices may
be determined by the Becke line test. Alternatively, dispersion staining may be used.
Inexperienced operators may find that the
dispersion staining technique is more easily
learned, and should consult Reference 9 for
guidance. Central stop dispersion staining
colors are presented in Table 1–2. Available
high-dispersion (HD) liquids should be used.

TABLE 1–1—OPTICAL PROPERTIES OF ASBESTOC FIBERS
Refrac- tive indices b
Morphology, color a

Mineral

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a

g

Chrysotile
(asbestiform
serpentine).

Wavy fibers. Fiber bundles have
splayed ends and ‘‘kinks’’. Aspect
ratio typically >10:1. Colorless 3,
nonpleochroic.

1.493–1.560

Amosite
(asbestiform
grunerite).

Straight, rigid fibers. Aspect ratio typically >10:1. Colorless to brown,
nonpleochroic or weakly so. Opaque
inclusions may be present.

1.635–1.696

1.517–
1.562f
(normally
1.556).
1.655–
1.729 f
(normally
1.696–
1.710.

Birefringence

Extinction

.008

| to fiber
length.

+
(length
slow)

.020–.033

| to fiber
length.

+
(length
slow)

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Environmental Protection Agency

Pt. 763, Subpt. E, App. E

TABLE 1–1—OPTICAL PROPERTIES OF ASBESTOC FIBERS—Continued
Refrac- tive indices b
Morphology, color a

Mineral

Extinction

1.668–
1.7173e
(normally
close to
1.700).
1.615–
1.676 f.

.014–.016

| to fiber
length.

¥
(length fast)

.019–.024

| to fiber
length.

+
(length
slow)

1.622–
1.688 f.

.023–.020

Oblique
extinction, 10–
20° for
fragments.
Composite fibers
show |
extinction.

+
(length
slow)

Straight, rigid fibers. Thick fibers and
bundles common, blue to purpleblue
in
color.
Pleochroic.
Birefringence is generally masked by
blue color.

1.654–1.701

Anthophylliteasbestos.

Straight fibers and acicular cleavage
fragments.d Some composite fibers.
Aspect ratio <10:1. Colorless to light
brown.
Normally present as acicular or prismatic cleavage fragments.d Single
crystals predominate, aspect ratio
<10:1. Colorless to pale green.

1.596–1.652

1.599–1.668

a From

reference 5; colors cited are seen by observation with plane polarized light.
references 5 and 8.
subjected to heating may be brownish.
d Fibers defined as having aspect ratio >3:1.
e to fiber length.
f |To fiber length.
b From

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c Fibers

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Sign of
elonation

g

Crocidolite
(asbestiform
Riebeckite).

Tremolite-actinolite-asbestos.

Birefringence

a

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40 CFR Ch. I (7–1–07 Edition)

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EC01AP92.017</GPH>

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Pt. 763, Subpt. E, App. E

Environmental Protection Agency

Pt. 763, Subpt. E, App. E

TABLE 1–2—CENTRAL STOP DISPERSION
STAINING COLORS A
h

Mineral

RI Liquid

Chrysotile .....

1.550 HD

Blue .............

Amosite ........

1.680

Blue-magenta to
pale blue.
Yellow to
white.
Red magenta

1.550HD
Crocidolite b ..

1.700
1.550HD

Anthophyllite

1.605HD

Tremolite ......
Actinolite ......

1.605HD c
1.605HD

1.630HD c
a From
b Blue

Yellow to
white.
Blue .............
Pale blue .....
Gold-magenta to
blue.
Magenta ......

h|
Blue-magenta
Golden-yellow
Yellow to
white
Blue-magenta
Yellow to
white
Gold to goldmagenta
Gold
Gold

Golden-yellow

reference 9.
absorption color.
extinction view.

c Oblique

rfrederick on PROD1PC67 with CFR

1.7.2.4

Quantitation of Asbestos Content

Asbestos quantitation is performed by a
point-counting procedure or an equivalent
estimation method. An ocular reticle (crosshair or point array) is used to visually superimpose a point or points on the microscope
field of view. Record the number of points
positioned directly above each kind of particle or fiber of interest. Score only points
directly over asbestos fibers or nonasbestos
matrix material. Do not score empty points
for the closest particle. If an asbestos fiber
and a matrix particle overlap so that a point
is superimposed on their visual intersection,
a point is scored for both categories. Point
counting provides a determination of the
area percent asbestos. Reliable conversion of
area percent to percent of dry weight is not
currently feasible unless the specific
gravities and relative volumes of the materials are known.
For the purpose of this method, ‘‘asbestos
fibers’’ are defined as having an aspect ratio
greater than 3:1 and being positively identified as one of the minerals in Table 1–1.
A total of 400 points superimposed on either asbestos fibers or nonasbestos matrix
material must be counted over at least eight
different preparations of representative subsamples. Take eight forcep samples and
mount each separately with the appropriate
refractive index liquid. The preparation
should not be heavily loaded. The sample
should be uniformly dispersed to avoid overlapping particles and allow 25–50 percent
empty area within the fields of view. Count
50 nonempty points on each preparation,
using either
• A cross-hair reticle and mechanical stage;
or

• A reticle with 25 points (Chalkley Point
Array) and counting at least 2 randomly
selected fields.
For samples with mixtures of isotropic and
anisotropic materials present, viewing the
sample with slightly uncrossed polars or the
addition of the compensator plate to the polarized light path will allow simultaneous
discrimination of both particle types. Quantitation should be performed at 100X or at
the lowest magnification of the polarized
light microscope that can effectively distinguish the sample components. Confirmation
of the quantitation result by a second analyst on some percentage of analyzed samples
should be used as standard quality control
procedure.
The percent asbestos is calculated as follows:
% asbestos=(a/n) 100%
where
a=number of asbestos counts,
n=number of nonempty points counted (400).
If a=0, report ‘‘No asbestos detected.’’ If 0<
a≤3, report ‘‘<1% asbestos’’.
The value reported should be rounded to
the nearest percent.
1.8

References

1. Paul F. Kerr, Optical Mineralogy, 4th ed.,
New York, McGraw-Hill, 1977.
2. E. M. Chamot and C. W. Mason, Handbook of Chemical Microscopy, Volume One, 3rd
ed., New York: John Wiley & Sons, 1958.
3. F. Chayes, Petrographic Modal Analysis:
An Elementary Statistical Appraisal, New
York: John Wiley & Sons, 1956.
4. E. P. Brantly, Jr., K. W. Gold, L. E.
Myers, and D. E. Lentzen, Bulk Sample Analysis for Asbestos Content: Evaluation of the
Tentative Method, U.S. Environmental Protection Agency, October 1981.
5. U.S. Environmental Protection Agency,
Asbestos-Containing Materials in School Buildings: A Guidance Document, Parts 1 and 2,
EPA/OPPT No. C00090, March 1979.
6. D. Lucas, T. Hartwell, and A. V. Rao, Asbestos-Containing Materials in School Buildings: Guidance for Asbestos Analytical Programs, EPA 560/13–80–017A, U.S. Environmental Protection Agency, December 1980, 96
pp.
7. D. H. Taylor and J. S. Bloom,
Hexametaphosphate pretreatment of insulation samples for identification of fibrous
constituents, Microscope, 28, 1980.
8. W. J. Campbell, R. L. Blake, L. L.
Brown, E. E. Cather, and J. J. Sjoberg. Selected Silicate Minerals and Their Asbestiform
Varieties: Mineralogical Definitions and Identification-Characterization, U.S. Bureau of
Mines Information Circular 8751, 1977.
9. Walter C. McCrone, Asbestos Particle
Atlas, Ann Arbor: Ann Arbor Science Publishers, June 1980.

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Pt. 763, Subpt. E, App. E

40 CFR Ch. I (7–1–07 Edition)

SECTION 2. X-RAY POWDER DIFFRACTION
2.1

Principle and Applicability

The principle of X-ray powder diffraction
(XRD) analysis is well established. 1,2 Any
solid, crystalline material will diffract an
impingent beam of parallel, monochromatic
X-rays whenever Bragg’s Law,
λ = 2d sin q,
is satisfied for a particular set of planes in
the crystal lattice, where
λ = the X-ray wavelength, Å;
d = the interplanar spacing of the set of reflecting lattice planes, Å; and
q = the angle of incidence between the X-ray
beam and the reflecting lattice planes.
By appropriate orientation of a sample relative to the incident X-ray beam, a diffraction pattern can be generated that, in most
cases, will be uniquely characteristic of both
the chemical composition and structure of
the crystalline phases present.
Unlike optical methods of analysis, however, XRD cannot determine crystal morphology. Therefore, in asbestos analysis,
XRD does not distinguish between fibrous
and nonfibrous forms of the serpentine and
amphibole minerals (Table 2–1). However,
when used in conjunction with optical methods such as polarized light microscopy
(PLM), XRD techniques can provide a reliable analytical method for the identification
and characterization of asbestiform minerals
in bulk materials.

For qualitative analysis by XRD methods,
samples are initially scanned over limited
diagnostic peak regions for the serpentine
(∼7.4 Å) and amphibole (8.2–8.5 Å) minerals
(Table 2–2). Standard slow-scanning methods
for bulk sample analysis may be used for materials shown by PLM to contain significant
amounts of asbestos (>5–10 percent). Detection of minor or trace amounts of asbestos
may require special sample preparation and
step-scanning analysis. All samples that exhibit diffraction peaks in the diagnostic regions for asbestiform minerals are submitted
to a full (5°–60° 2q; 1° 2q/min) qualitative XRD
scan, and their diffraction patterns are compared with standard reference powder diffraction patterns 3 to verify initial peak assignments and to identify possible matrix
interferences when subsequent quantitative
analysis will be performed.

TABLE 2–1—THE ASBESTOS MINERALS AND
THEIR NONASBESTIFORM ANALOGS
Asbestiform
SERPENTINE
Chrysotile
AMPHIBOLE
Anthophyllite asbestos
Cummingtonite-grunerite
asbestos (‘‘Amosite’’)
Crocidolite
Tremolite asbestos
Actinolite asbestos

Nonasbestiform

Antigorite, lizardite
Anthophyllite
Cummingtonite-grunerite
Riebeckite
Tremolite
Actinolite

TABLE 2–2—PRINCIPAL LATTICE SPACINGS OF ASBESTIFORM MINERALS a
Minerals

Chrysotile ..................

‘‘Amosite’’ ..................
Anthophyllite ..............
Anthophyllite ..............
Crocidolite .................
Tremolite ...................

Principal d-spacings (Å) and relative intensities

7.37100
7.36100 ..
7.10100 ..
8.33100
8.22100 ..
3.05100
3.06100 ..
2.72100
8.35100
8.38100
2.706100
3.13100 ..

3.6570
3.6680
2.3380
3.0670
3.06085
3.2460
8.3370
2.54100
3.1055
3.12100
3.1495
2.70660

4.5750
2.4565
3.5570
2.75670
3.2570
8.2655
3.2350
3.48080
2.72035
2.70590
8.4340
8.4440

JCPDS Powder diffraction file 3 number

21–543b
25–645
22–1162 (theoretical)
17–745 (nonfibrous)
27–1170 (UICC)
9–455
16–401 (synthetic)
25–157
27–1415 (UICC)
13–437b
20–1310b (synthetic)
23–666 (synthetic mixture with richterite)

rfrederick on PROD1PC67 with CFR

a This information is intended as a guide, only. Complete powder diffraction data, including mineral type and source, should be
referred to, to ensure comparability of sample and reference materials where possible. Additional precision XRD data on
amosite, crocidolite, tremolite, and chrysotile are available from the U.S. Bureaus of Mines.4
b Fibrosity questionable.

Accurate quantitative analysis of asbestos
in bulk samples by XRD is critically dependent on particle size distribution, crystallite
size, preferred orientation and matrix absorption effects, and comparability of standard reference and sample materials. The
most intense diffraction peak that has been
shown to be free from interference by prior

qualitative XRD analysis is selected for
quantitation of each asbestiform mineral. A
‘‘thin-layer’’ method of analysis 5,6 is recommended
in
which,
subsequent
to
comminution of the bulk material to ∼10 µm
by suitable cryogenic milling techniques, an
accurately known amount of the sample is
deposited on a silver membrane filter. The

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