ISO 22309:2006

INTERNATIONAL ISO
STANDARD 22309
First edition
2006-04-15


Microbeam analysis — Quantitative
analysis using energy-dispersive
spectrometry (EDS)
Analyse par microfaisceaux — Analyse élémentaire quantitative par
spectrométrie à sélection d'énergie (EDS)





Reference number
ISO 22309:2006(E)
©
ISO 2006

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ISO 22309:2006(E)
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ISO 22309:2006(E)
Contents Page
Foreword. iv
Introduction . v
1 Scope . 1
2 Normative references . 2
3 Terms and definitions. 2
4 Specimen preparation . 6
5 Preliminary precautions. 7
6 Analysis procedure. 7
7 Data reduction. 9
7.1 General. 9
7.2 Identification of peaks. 9
7.3 Estimation of peak intensity . 9
7.4 Calculation of k-ratios . 10
7.5 Matrix effects. 10
7.6 Use of reference materials. 10
7.7 Standardless analysis . 11
7.8 Uncertainty of results. 11
7.9 Reporting of results. 12
Annex A (informative) The assignment of spectral peaks to their elements . 14
Annex B (informative) Peak identity/interferences . 16
Annex C (informative) Factors affecting the uncertainty of a result. 18
Annex D (informative) Analysis of elements with atomic number < 11 . 20
Annex E (informative) Example data from a reproducibility study within a laboratory and between
laboratories . 21
Bibliography . 23

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ISO 22309:2006(E)
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 22309 was prepared by Technical Committee ISO/TC 202, Microbeam analysis.
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ISO 22309:2006(E)
Introduction
X-rays generated when a high-energy electron beam interacts with a specimen have energies (wavelengths)
which are characteristic of the chemical elements (atom types) present in the specimen. The intensity of these
X-rays from each element is related to the concentration of that element in the specimen. If these intensities
are measured, compared with those from a suitable reference material or set of reference materials, and
corrected in an appropriate manner, the concentration of each element can be determined. “Standardless”
procedures also provide quantitative information, but involve a comparison with previously measured
reference intensities that are stored within the software package or are calculated theoretically; such
procedures may, depending on any assumptions made, be inherently less accurate than the method
employing reference materials (see References [1] to [8] in the Bibliography). There are two common methods
of detecting the characteristic X-rays that are produced, one which relies on wavelength dispersive
spectrometry (WDS) and the other which uses energy-dispersive spectrometry (EDS). This International
Standard relates to the latter, energy-dispersive spectrometry.
Using EDS, the quantitative analysis of light elements (i.e. atomic number Z < 11, below Na) is more complex
and some of the problems are discussed in this International Standard.

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INTERNATIONAL STANDARD ISO 22309:2006(E)

Microbeam analysis — Quantitative analysis using energy-
dispersive spectrometry (EDS)
1 Scope
This International Standard gives guidance on the quantitative analysis at specific points or areas of a
specimen using energy-dispersive spectrometry (EDS) fitted to a scanning electron microscope (SEM) or
electron probe microanalyser (EPMA); any expression of amount, i.e. in terms of percent (mass fraction), as
large/small or major/minor amounts is deemed to be quantitative. The correct identification of all elements
present in the specimen is a necessary part of quantitative analysis and is therefore considered in this
International Standard. This International Standard provides guidance on the various approaches and is
applicable to routine quantitative analysis of mass fractions down to 1 %, utilising either reference materials or
“standardless” procedures. It can be used with confidence for elements with atomic number Z > 10.
Guidance on the analysis of light elements with Z < 11 is also given.
NOTE With care, mass fractions as low as 0,1 % are measurable when there is no peak overlap and the relevant
characteristic line is strongly excited. This International Standard applies principally to quantitative analyses on a flat
polished specimen surface. The basic procedures are also applicable to the analysis of specimens that do not have a
polished surface but additional uncertainty components will be introduced.
There is no accepted method for accurate quantitative EDS analysis of light elements. However, several EDS
methods do exist. These are the following.
a) Measuring peak areas and comparing intensities in the same way as for heavier elements. For the
reasons explained in Annex D, the uncertainty and inaccuracy associated with the results for light
elements will be greater than for the heavier elements.
b) Where the light element is known to be combined stoichiometrically with heavier elements (Z > 10) in the
specimen, its concentration can be determined by summing the appropriate proportions of concentrations
of the other elements. This is often used for the analysis of oxygen in silicate mineral specimens.
c) Calculation of concentration by difference where the light element percentage is 100 % minus the
percentage sum of the analysed elements. This method is only possible with good beam-current stability
and a separate measurement of at least one reference specimen and it requires very accurate analysis of
the other elements in the specimen.
Annex D summarises the problems of light element analysis, additional to those that exist for quantitative
analysis of the heavier elements. If both EDS and wavelength spectrometry (WDS) are available, then WDS
can be used to overcome the problems of peak overlap that occur with EDS at low energies. However, many
of the other issues are common to both techniques.
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ISO 22309:2006(E)
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 14594, Microbeam analysis — Electron probe microanalysis — Guidelines for the determination of
experimental parameters for wavelength dispersive spectroscopy
ISO 15632:2002, Microbeam analysis — Instrumental specification for energy dispersive X-ray spectrometers
with semiconductor detectors
ISO 16700:2004, Microbeam analysis — Scanning electron microscopy — Guidelines for calibrating image
magnification
ISO/IEC 17025:2005, General requirements for the competence of testing and calibration laboratories
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
3.1
absorption correction
matrix correction arising from the loss of X-ray intensity from an element due to photoelectric absorption by all
elements within the specimen while passing through it to the detector
3.2
accuracy
closeness of agreement between the “true” value and the measured value
3.3
accelerating voltage
potential difference applied between the filament and anode in order to accelerate the electrons emitted from
the source
NOTE Accelerating voltage is expressed in kilovolts.
3.4
atomic number correction
matrix correction which modifies intensity from each element in the specimen and standards to take account
of electron backscattering and stopping power, the magnitudes of which are influenced by all the elements in
the analysed volume
3.5
beam current
electron current contained within the beam
NOTE Beam current is expressed in nanoamperes.
3.6
beam stability
extent to which beam current varies during the course of an analysis
NOTE Beam stability is expressed in percent per hour.
3.7
bremsstrahlung
background continuum of X-rays generated by the deceleration of electrons within the specimen
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ISO 22309:2006(E)
3.8
certified reference material
CRM
reference material, one or more of whose property values are certified by a technically valid procedure,
accompanied by or traceable to a certificate or other documentation which is issued by a certifying body
3.9
characteristic X-ray
photon of electromagnetic radiation created by the relaxation of an excited atomic state caused by inner shell
ionisation following inelastic scattering of an energetic electron, or by absorption of an X-ray photon
3.10
dead time
the time that the system is unavailable to record a photon measurement because it is busy processing a
previous event
NOTE This is frequently expressed as a percentage of the total time (see also live time).
3.11
energy-dispersive spectrometry
EDS
form of X-ray spectrometry in which the energy of individual photons are measured and used to build up a
digital histogram representing the distribution of X-rays with energy
3.12
electron probe microanalysis
a technique of spatially resolved elemental analysis based on electron-excited X-ray spectrometry with a
focused electron probe and an interaction/excitation volume with micrometre to sub-micrometre dimensions
3.13
escape peaks
peaks that occur as a result of loss of incident photon energy by fluorescence of the material of the detector
NOTE 1 These occur at an energy equal to that of the incident characteristic peak minus the energy of the X-ray line(s)
emitted by the element(s) in the detector (1,734 keV for silicon).
NOTE 2 They cannot occur below the critical excitation potential of the detector material, e.g. Si K escape does not
occur for energies below 1,838 keV.
3.14
fluorescence
photoelectric absorption of any X-ray radiation (characteristic or bremsstrahlung) by an atom which results in
an excited atomic state which will de-excite with electron shell transitions and subsequent emission of an
Auger electron or the characteristic X-ray of the absorbing atom
3.15
fluorescence correction
matrix correction which modifies the intensity from each element in the specimen and standards to take
account of excess X-rays generated from element “A” due to the absorption of characteristic X-rays from
element “B” whose energy exceeds the critical (ionisation) energy of “A”
3.16
full width at half maximum
FWHM
measure of the width of an X-ray peak in which the background is first removed to reveal the complete peak
profile
NOTE FWHM is determined by measuring the width at half the maximum height.
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ISO 22309:2006(E)
3.17
incident beam energy
energy gained by the beam as a result of the potential applied between the filament and anode
3.18
k-ratio
net peak intensity (after background subtraction) for an element found in the specimen, divided by the
intensity, recorded or calculated, of the corresponding peak in the spectra of a reference material
3.19
live time (s)
time the pulse measurement circuitry is available for the detection of X-ray photons
See also dead time (3.10).
NOTE 1 Live time is expressed in second (s).
NOTE 2 Live time = real time for analysis − dead time. Real time is the time that would be measured with a
conventional clock. For an X-ray acquisition, the real time always exceeds the live time.
3.20
overvoltage ratio
ratio of the incident beam energy to the critical excitation energy for a particular shell and sub-shell (K, LI, LII,
etc.) from which the characteristic X-ray is emitted
3.21
peak intensity
total number of X-rays (counts) under the profile of a characteristic X-ray peak after background subtraction
NOTE This is sometimes referred to as the peak integral.
3.22
peak profile
detailed shape of a characteristic peak which depends on the relative intensities and energies of the individual
X-ray emissions that are unresolved by the energy-dispersive spectrometer
3.23
precision
closeness of agreement between the results obtained by applying the experimental procedure several times
under prescribed conditions
3.24
quantitative EDS
procedure leading to the assignment of numerical values or expressions to represent the concentrations of
elements measured within the analysis volume
3.25
reference material
RM
material or substance, one or more properties of which are sufficiently well established to be used for the
calibration of an apparatus, the assessment of a method, or for assigning values to materials
NOTE A reference material is said to be homogeneous with respect to a specified property if the property value, as
determined by tests on specimens of specified size, is found to lie within the specified uncertainty limits, the specimens
being taken either from a single or different supply unit.
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ISO 22309:2006(E)
3.26
repeatability
closeness of agreement between results of successive measurements of the same quantity carried out by the
same method, by the same observer, with the same measuring instruments, in the same laboratory, at quite
short intervals of time
3.27
reproducibility
closeness of agreement between the result of measurements of the same quantity, where the individual
measurements are made by different methods, with different measuring instruments, by different observers, in
different laboratories, after intervals of time that are quite long compared with the duration of a single
measurement, under different normal conditions of use of the instruments employed
3.28
resolution
〈energy〉 width of a peak measured by an energy-dispersive spectrometer and expressed as the peak width at
half the maximum peak intensity
NOTE This is usually expressed as the value for Mn Kα (5,894 keV), although peaks from other suitable elements
can be used.
3.29
resolution
〈spatial〉 spatial specificity of microanalysis
NOTE This is usually expressed in terms of a linear or volumetric measure of the region of the specimen that is
sampled by the measured characteristic radiation.
3.30
standardless analysis
procedure for quantitative X-ray microanalysis in which the reference peak intensity in the k-value expression,
(unknown/reference) is supplied from purely physical calculations or from stored data from a suite of reference
materials; adjustments being made to match analysis conditions and augment incomplete reference data
3.31
sum peaks
artefact peaks that occur as a result of pulse co-incidence effects that occur within the pulse pair resolution of
the pile-up inspection circuitry
NOTE These peaks appear at energies corresponding to the sum of those energies of the two photons that arrive
simultaneously at the detector.
3.32
traceability
ability to trace the history, application or location of an entity by means of recorded identifications
3.33
uncertainty
that part of the expression of the result of a measurement that states the range of values within which the
“true” value is estimated to lie for a stated probability
3.34
validation
confirmation by examination and provision of objective evidence that the particular requirements for a specific
intended use are fulfilled
3.35
X-ray absorption
attenuation of X-rays passing through matter, arising primarily from photoelectric absorption for X-ray energies
and ranges appropriate to EPMA/EDS and SEM/EDS
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ISO 22309:2006(E)
4 Specimen preparation
4.1 Material for analysis shall be stable under variable pressure conditions and the electron beam. As-
received specimens can be examined after simple cleaning, but surface inhomogeneity or topography will
adversely affect the quality of the quantitative analysis.
4.2 For reliable quantitative analysis, the specimen shall present a flat, smooth surface normal to the
electron beam. This requirement is usually met by the application of conventional metallographic or
petrographic techniques. The area for analysis should be homogeneous over a region, typically a few
micrometres in diameter, around the electron beam.
4.3 Solid specimens can be reduced to an appropriate size, making sure they undergo no transformation
during the process. Prior to examination in the as-received condition, all surface debris should be removed
using appropriate techniques, such as ultrasonic cleaning.
4.4 Specimens for sectioning should be embedded, where possible, in a conducting medium prior to
metallographic or petrographic polishing using standard procedures. The medium shall be chosen with care,
to avoid the possibility of the conducting component becoming smeared onto the specimen surface and
mistaken for a component of the specimen by effectively altering the composition of the analysed volume.
NOTE 1 Polishing may be carried through to 1/4 µm grade diamond, provided this can be done without introducing
relief effects. Complete removal of all scratches is not essential, provided areas for analysis are clean and relief-free.
Damage to the specimen during preparation should be avoided. Potential damage mechanisms include:
a) the effects of lubricant;
b) the removal of second phases (precipitates);
c) differential polishing of phases with different hardness, thus introducing relief to the surface;
d) strain introduced into the surface;
e) edge curvature.
With cross-sections, the specimen can be coated with a harder material to improve edge retention.
[9]
NOTE 2 See ASTM E3-01 for further guidance.
4.5 If optical examination is to be used for the location of areas for analysis, either prior to or while in the
instrument, etching of the specimen may be necessary. The depth of etching should be kept to a minimum,
being aware of the possibility of surface compositional changes or the development of undesirable
topographic effects. Polishing away the etching may be needed after locating and marking the regions for
analysis by reference to existing or added features, such as a scratch or hardness indent.
4.6 The specimen should have a good conductivity to avoid charge-up generated by electron beam
irradiation. The specimen shall be connected to the instrument ground either through a conducting mount, or
by a stripe of silver or carbon paint. Any exposed non-conducting mounting material may be covered with a
conducting medium to avoid disturbance of the electron beam during analysis.
Carbon to a thickness of about 20 nm can be used as a conductive coating, although a metallic (e.g.
aluminium) coating of lesser thickness may be used if carbon is unacceptable.
NOTE Coating with an element already present in the specimen changes the apparent composition of that element in
the specimen, the magnitude of the effect being dependent on accelerating voltage and the thickness of the coating.
4.7 The prepared specimens shall be positioned in the instrument stage in such a way that, for the majority
of work, the surface can be reliably held normal to the incident electron beam.
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ISO 22309:2006(E)
[18]
4.8 Reference materials should conform to ISO 14595 and shall be prepared in a similar way to the
unknown specimens, e.g. polished, carbon coated, and positioned in the same orientation relative to the
electron beam.
5 Preliminary precautions
5.1 With a suitable vacuum level and the electron beam on, preliminary checks to ensure beam stability
(better than 1 % per hour variation in counts from a standard specimen) and stable detector performance
should be made prior to commencing calibration and analysis procedures. Detector stability shall be
monitored by measuring the detector resolution and energy calibration (see ISO 15632).
5.2 The energy scale of the detector system shall be checked or re-calibrated at regular intervals (e.g.
daily) or whenever there is any doubt over the identity of spectral peaks. All calibration data and any departure
from calibration shall be recorded.
5.3 The energy scale shall be checked using the line positions for two peaks, one of low energy (for
example, Al Kα at 1,486 keV) and one of high energy (for example, Cu Kα at 8,040 keV). Suitable individual
reference materials for this purpose are readily available. Alternatively, Kα peaks from two elements, such as
Al and Cu, present in the same reference material can be collected into the same displayed spectrum.
NOTE 1 Where it is possible to monitor the zero of the energy scale, only a single spectral peak is needed for accurate
calibration.
NOTE 2 Use of the line positions for two peaks from the same element, e.g. Cu Lα and Cu Kα, along with a simple
fitting procedure may give reduced calibration accuracy because of the distortion of Cu Lα by Cu LI and Cu Lβ.
5.4 The full width at half maximum (FWHM) of a selected peak provides a measure of the detector
resolution. It shall be measured at regular intervals following the procedure in ISO 15632, and shall be less
than an acceptable limit (typically that corresponding to a deterioration of more than 10 % of the as-delivered
resolution) for given settings of the pulse processing electronics. If these limits are exceeded, the system
performance shall be investigated and revalidated if necessary. All such measurements shall be performed
under identical conditions and be recorded.
NOTE For accurate quantitative analysis using peaks with an energy close to 1 keV, it is not advisable to use a
detector for which the FWHM of Mn Kα exceeds 160 eV, and is preferably less than 135 eV.
5.5 The ratio of the intensities of the Cu Lα and Cu Kα peaks, or equivalent peaks from other elements, e.g.
nickel, provides a measure of the detector efficiency and shall be determined at regular intervals and recorded.
Where this decreases to an unacceptable level (typically not less than 2/3 of the as-delivered value), the
system shall be revalidated by the manufacturer, particularly where standardless analysis is being carried out.
The detector should conform to ISO 15632:2002, Annex B.
5.6 For standardless analysis, check the measured spectrum using the Duane-Hunt rule
NOTE Deviations of the high energy end of the bremsstrahlung background from the indicated high voltage means
either charging of the specimen or a wrong high voltage indicated by the SEM. No quantitative analysis can be done in
these cases.
6 Analysis procedure
6.1 The filament shall be saturated and sufficient time allowed for it to achieve adequate stability, for
example better than 1 % over the anticipated duration of the analysis run. An accelerating voltage, of typically
between 10 kV and 25 kV, shall be chosen to meet one or more of several criteria.
a) For efficient excitation and good peak intensity, an overvoltage of at least 1,8 is desirable. Thus, when
utilising high energy lines of the order of 8 keV to 10 keV, a minimum accelerating voltage of 20 kV is
recommended.
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ISO 22309:2006(E)
b) For analysis of low energy lines, e.g. 1 keV to 3 keV, it is desirable to minimise the magnitude of the
absorption correction and possible errors arising from it, by operation at low beam voltages, e.g. 10 kV
providing the excitation requirement a) is satisfied for the lines of interest.
NOTE At 10 kV, analysis of the elements from Z = 24 (Cr) to Z = 29 (Cu) will not be possible since the K lines are not
adequately excited.
c) For accurate analysis, it is essential that the analysed volume shall be wholly contained within the feature
under examination throughout the analysis period; such features may be surface layers, small inclusions,
areas near to an interface, etc. Methods for the estimation of the influence of accelerating voltage on
analysis area and analysis depth are given in ISO 14594,
...