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ASTM E520-08(2023)

(Practice)

Standard Practice for Describing Photomultiplier Detectors in Emission and Absorption Spectrometry

Standard Practice for Describing Photomultiplier Detectors in Emission and Absorption Spectrometry

ABSTRACT
This practice describes the photomultiplier properties that are essential to their judicious selection and use of in emission and absorption spectrometry. The properties covered here include structural features, electrical properties, and characteristics involved in precautions and problems. The structural features covered are envelope configurations, window materials, electrical connections, and housing for the external structure, and the photocathode, dynodes and anode, and rigidness of structural components for the internal structure. Electrical properties, on the other hand, incorporate the following: optical-electronic characteristics of the photocathode including spectral response; current amplification including gain per stage, overall gain, gain control (voltage-divider bridge), linearity of response, and anode saturation; signal nature; dark current including cathode size, internal aperture, and refrigeration effects; noise nature including additivity of noise power, signal-to-noise ratio, equivalent noise input; and photomultiplier properties as a component in an electrical circuit including output impedance, response time, and signal gating and integration possibilities. Finally, the characteristics involved in precautions and problems cover fatigue and hysteresis effects, illumination of photocathode, and gas leakage.
SCOPE
1.1 This practice covers photomultiplier properties that are essential to their judicious selection and use in emission and absorption spectrometry. Descriptions of these properties can be found in the following sections:    
Section  
Structural Features  
4  
General  
4.1  
External Structure  
4.2  
Internal Structure  
4.3  
Electrical Properties  
5  
General  
5.1  
Optical-Electronic Characteristics of the Photocathode  
5.2  
Current Amplification  
5.3  
Signal Nature  
5.4  
Dark Current  
5.5  
Noise Nature  
5.6  
Photomultiplier as a Component in an Electrical Circuit  
5.7  
Precautions and Problems  
6  
General  
6.1  
Fatigue and Hysteresis Effects  
6.2  
Illumination of Photocathode  
6.3  
Gas Leakage  
6.4  
Recommendations on Important Selection Criteria  
7  
1.2 Radiation in the frequency range common to analytical emission and absorption spectrometry is detected by photomultipliers presently to the exclusion of most other transducers. Detection limits, analytical sensitivity, and accuracy depend on the characteristics of these current-amplifying detectors as well as other factors in the system.  
1.3 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.  
1.4 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
Historical
Publication Date
31-Mar-2023
ICS
17.180.30 - Optical measuring instruments
Technical Committee
E01 - Analytical Chemistry for Metals, Ores, and Related Materials
Drafting Committee
E01.20 - Fundamental Practices
Current Stage
Ref Project

Relations

Replaced By
ASTM E520-08(2023)e1 - Standard Practice for Describing Photomultiplier Detectors in Emission and Absorption Spectrometry
Effective Date
01-Apr-2023
Refers
ASTM E135-20 - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
01-Jan-2020
Refers
ASTM E135-19 - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-May-2019
Refers
ASTM E135-16 - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-May-2016
Refers
ASTM E135-15a - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
01-Jul-2015
Refers
ASTM E135-15 - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-May-2015
Refers
ASTM E135-14b - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-Aug-2014
Refers
ASTM E135-14a - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
01-Apr-2014
Refers
ASTM E135-14 - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-Feb-2014
Refers
ASTM E135-13a - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
01-Dec-2013
Refers
ASTM E135-11b - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-Sep-2011
Refers
ASTM E135-11a - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-Jun-2011
Refers
ASTM E135-11 - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-Jan-2011
Refers
ASTM E135-10b - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
01-Jul-2010
Refers
ASTM E135-10a - Standard Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
Effective Date
15-Jan-2010

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Standards Content (Sample)


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: E520 − 08 (Reapproved 2023)
Standard Practice for
Describing Photomultiplier Detectors in Emission and
Absorption Spectrometry
This standard is issued under the fixed designation E520; 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 mendations issued by the World Trade Organization Technical
Barriers to Trade (TBT) Committee.
1.1 This practice covers photomultiplier properties that are
essential to their judicious selection and use in emission and
2. Referenced Documents
absorption spectrometry. Descriptions of these properties can
2.1 ASTM Standards:
be found in the following sections:
E135 Terminology Relating to Analytical Chemistry for
Section
Structural Features 4 Metals, Ores, and Related Materials
General 4.1
External Structure 4.2
3. Terminology
Internal Structure 4.3
Electrical Properties 5
3.1 Definitions—For terminology relating to detectors refer
General 5.1
to Terminology E135.
Optical-Electronic Characteristics of the Photocathode 5.2
Current Amplification 5.3
3.2 Definitions of Terms Specific to This Standard:
Signal Nature 5.4
3.2.1 solar blind, n—photocathode of photomultiplier tube
Dark Current 5.5
does not respond to higher wavelengths.
Noise Nature 5.6
Photomultiplier as a Component in an Electrical Circuit 5.7
3.2.1.1 Discussion—In general, solar blind photomultiplier
Precautions and Problems 6
tubes used in atomic emission spectrometry transmit radiation
General 6.1
below about 300 nm and do not transmit wavelengths above
Fatigue and Hysteresis Effects 6.2
Illumination of Photocathode 6.3
300 nm.
Gas Leakage 6.4
Recommendations on Important Selection Criteria 7
4. Structural Features
1.2 Radiation in the frequency range common to analytical
4.1 General—The external structure and dimensions, as
emission and absorption spectrometry is detected by photomul-
well as the internal structure and electrical properties, can be
tipliers presently to the exclusion of most other transducers.
significant in the selection of a photomultiplier.
Detection limits, analytical sensitivity, and accuracy depend on
the characteristics of these current-amplifying detectors as well
4.2 External Structure—The external structure consists of
as other factors in the system.
envelope configurations, window materials, electrical contacts
through the glass-wall envelopes, and exterior housing.
1.3 This standard does not purport to address all of the
4.2.1 Envelope Configurations—Glass envelope shapes and
safety concerns, if any, associated with its use. It is the
dimensions are available in an abundant variety. Two envelope
responsibility of the user of this standard to establish appro-
configurations are common, the end-on (or head-on) and
priate safety, health, and environmental practices and deter-
side-on types (see Fig. 1).
mine the applicability of regulatory limitations prior to use.
4.2.2 Window Materials—Various window materials, such
1.4 This international standard was developed in accor-
as glass, quartz and quartz-like materials, sapphire, magnesium
dance with internationally recognized principles on standard-
fluoride, and cleaved lithium fluoride, cover the ranges of
ization established in the Decision on Principles for the
spectral transmission essential to efficient detection in spectro-
Development of International Standards, Guides and Recom-
metric applications. Window cross sections for the end-on type
photomultipliers include plano-plano, plano-concave,
This practice is under the jurisdiction of ASTM Committee E01 on Analytical
Chemistry for Metals, Ores, and Related Materials and is the direct responsibility of
Subcommittee E01.20 on Fundamental Practices. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved April 1, 2023. Published April 2023. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
ɛ1
approved in 1998. Last previous edition approved in 2015 as E520 – 08 (2015) . Standards volume information, refer to the standard’s Document Summary page on
DOI: 10.1520/E0520-08R23. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E520 − 08 (2023)
at a region where the electric field is directed away from the
surface and toward the next dynode. Six of these configurations
are shown in Fig. 2. Ordinarily a photomultiplier uses from 4
dynodes to 16 dynodes. There are several different configura-
tions of anodes including multianodes and cross wire anodes
for position sensitivity.
4.3.3 Rigidness of Structural Components—The standard
structural components generally will not endure exceptional
mechanical shocks. However, specifically constructed photo-
multipliers (ruggedized) that are resistant to damage by me-
chanical shock and stress are available for special applications,
such as geophysical uses or in mobile laboratories.
5. Electrical Properties
5.1 General—The electrical properties of a photomultiplier
are a complex function of the cathode, dynodes, and the
voltage divider bridge used for gain control.
5.2 Optical-Electronic Characteristics of the
Photocathode—Electrons are ejected into a vacuum from the
conduction bands of semiconducting or conducting materials if
the surface of the material is exposed to electromagnetic
radiation having a photon energy higher than that required by
the photoelectric work-function threshold. The number of
electrons emitted per incident photon, that is, the quantum
efficiency, is likely to be less than unity and typically less than
0.3.
FIG. 1 Envelope Configurations
convexo-concave forms, and a hemispherical form for the
collection of 2-π radians of light flux.
4.2.3 Electrical Connections—Standard pin bases, flying-
leads, or potted pin bases are available to facilitate the location
of a photomultiplier, or for the use of a photomultiplier at low
temperatures. TFE-fluorocarbon receptacles for pin-base types
are recommended to minimize the current leakage between
pins.
4.2.4 Housing—The housing for a photomultiplier should
be “light tight.” Light leaks into a housing or monochromator
from fluorescent lamps are particularly bad noise sources
which can be readily detected with an oscilloscope adjusted for
twice the power line frequency. A mu-metal housing or shield
is recommended to diminish stray magnetic field interferences
with the internal focus on electron trajectories between tube
elements.
4.3 Internal Structure—The internal structure consists of
arrangements of cathode, dynodes, and anodes.
4.3.1 Photocathode—A typical photomultiplier of the
end-on configuration possesses a semitransparent to opaque
layer of photoemissive material that is deposited on the inner
surface of the window segment in an evacuated glass envelope.
In the side-on window types, the cathode layer is on a reflective
substrate within the evacuated tube or on the inner surface of
the window.
4.3.2 Dynodes and Anode—Secondary-electron multiplica-
tion systems are designed so that the electrons strike a dynode FIG. 2 Electrostatic Dynode Structures
E520 − 08 (2023)
5.2.1 Spectral Response—The spectral response of a photo- electron energy and the work function of the material used for
cathode is the relative rate of photoelectron production as a the dynode surface. Most often dynode surfaces are Cs-Sb or
function of the wavelength of the incident radiation of constant Be-O composites on Cu/Be or Ni substrates. The gain per
flux density and solid angle. Spectral response is measured at dynode stage generally is purposely limited.
the cathode with a simple anode or at the anode of a 5.3.2 Overall Gain—A series of dynodes, arranged so that a
secondary-electron photomultiplier. Usually, this wavelength- stepwise amplification of electrons from a photocathode
dependent response is expressed in amperes per watt at anode. occurs, constitutes a total secondary electron multiplication
5.2.1.1 Spectral response curves for several common stan- system. Ordinarily, the number of dynodes employed in a
dard cathode-types are shown in Fig. 3. The S-number is a photomultiplier ranges from 4 to 16. The overall gain for a
standard industrial reference number for a given cathode type system, G, is related to the mean gain per stage, g, and the
n
and spectral response. Some of the common cathode surface number of dynode stages, n, by the equation G?=?g . Overall
compositions are listed below. Semiconductive photocathodes, gains in the order of 10 can be achieved easily.
for example, GaAs(Cs) and InGaAs(Cs), as well as red- 5.3.3 Gain Control (Voltage-Divider Bridge)—Since, for a
enhanced multialkali photocathodes (S-25) are also available. given photomultiplier the cathode and dynode surface materi-
A “solar blind” response cathode of CsI, not shown in Fig. 3, als and arrangement are fixed, the only practical means to
provides a low-noise signal in the 160 nm to 300 nm region of change the overall gain is to control the voltages applied to the
the spectrum. Intensity measurements at wavelengths below individual tube elements. This control is accomplished by
100 nm can be made with a windowless, gold-cathode photo- adjusting the voltage that is furnished by a high-voltage supply
multiplier. and that is imposed across a voltage-divider bridge (see Fig. 4).
Selection of proper resistance values and the configuration for
Examples of Cathode Surfaces
Response Type Designation Window Cathode Surface
the voltage-divider bridge ultimately determine whether a
S-1? Lime Glass Ag-O-Cs
given photomultiplier will function with stability and linearity
(Reflection)
in a certain application. Operational stability is determined by
S-5? Ultraviolet Sb-Cs
Transmitting Glass (Reflection)
the stability of the high voltage supplied to the divider-bridge
S-11 Lime Glass Sb-Cs
by the relative anode and divider-bridge currents and by the
(Semitransparent)
stability of each dynode voltage as determined by the divider-
S-13 Fused Silica Sb-Cs
(Semitransparent)
bridge.
S-20 Lime Glass Sb-Na-K-Cs
5.3.3.1 To a first approximation, the error in the gain varies
(Semitransparent)
proportionately to the error in the applied high voltage multi-
5.3 Current Amplification—The feeble photoelectron cur-
plied by the number of stages. Therefore, for a ten-stage tube,
rent generated at the cathode is increased to a conveniently
a gain stability of 61? % is attained with a power-supply
measurable level by a secondary electron multiplication sys-
voltage stability of 6 0.1? %.
tem. The mechanism for electron multiplication simply de-
5.3.3.2 For a tube stability of 1? %, the current drawn from
pends on the principle that the collision of an energetic electron
the heaviest loaded stage must be less than 1? % of the total
with a low work-function surface (dynode) will cause the
current through the voltage divider bridge. For most spectro-
ejection of several secondary electrons. Thus, a primary
scopic applications, a bridge current of about 0.5 mA to 1 mA
photoelectron that is directed by an electrostatic field and
is sufficient.
through an accelerating voltage to the first tube dynode will
5.3.3.3 The value of R (see Fig. 4) is set to give a voltage
effectively be amplified by a factor equal to the number of
between the cathode and the first dynode as recommended by
secondary electrons ejected from the single collision.
the manufacturer. Resistors R , R ···R , R , R , and R
2 3 n−2 n−1 n n+1
5.3.1 Gain per Stage—The amplification factor or gain
may be graded to give interstage voltages which are appropri-
produced at a dynode stage depends both on the primary
ate to the required peak current. With higher interstage voltages
at the output end of the tube, higher peak currents can be
drawn, but average currents above 1 mA are not normally
recommended. The value selected for decoupling-capacitors,
FIG. 3 Spectral Response Curves for Several Cathode Types FIG. 4 Voltage-Divider Bridge
E520 − 08 (2023)
C, which serve to prevent sudden significant interstage voltage exists even when the cathode is not illuminated. This total
changes between the last few dynodes, is dependent on the current is referred to as dark current.
signal frequency. Typically, the capacitance, C, is about two
5.5.1 Spectral Response and Dark Current—In general,
nanofarads (nF). In Fig. 4, A can be a load resistor (1 MΩ to
those cathode surfaces which provide extended red response
10 MΩ) or the input impedance to a current-measuring device.
have both low photoelectric-work functions and low
5.3.3.4 The overall gain of a photomultiplier varies in a
thermionic-work functions. Therefore, higher dark currents can
nonlinear fashion with the overall voltage applied to the divider
be expected for tubes with red-sensitive cathodes. However,
bridge as shown in Fig. 5.
the S-20 surface, which has much better red response and
5.3.4 Linearity of Response—A photomultiplier is capable
higher quantum efficiency than the S-11 surface, has a thermi-
of providing a linear response to the radiant input signal over
onic emission level that is equal to or lower than that of the
several orders of magnitude. Usually, the dynamic range at the
S-11.
photomultiplier exceeds the range capability of the common
5.5.2 Cathode Size—The dark current from thermionic elec-
linear voltage amplifiers used in measuring circuits.
trons is directly proportional to the area of photocathode
5.3.5 Anode Saturation—As the light intensity impinging on
viewed by the first dynode.
a photocathode is increased, an intensity level is reached,
5.5.3 Internal Apertures—Some photomultipliers are pro-
above which the anode current will no longer increase. A
vided with a defining aperture plane (or plate) between the
current-density saturation at the anode, or anode saturation, is
photocathode and the first dynode. The target plate defines an
responsible for this effect. A photomultiplier should never be
aperture that limits the area of the cathode viewed by the first
operated at anode saturation conditions nor in the nonlinear
dynode and effectively reduces dark current.
response region approaching saturation because of possible
5.5.4 Refrigeration of Photocathodes—Dark current from
damage to the tube.
S-1-type photomultipliers can be reduced considera
...


NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation: E520 − 08 (Reapproved 2023)
Standard Practice for
Describing Photomultiplier Detectors in Emission and
Absorption Spectrometry
This standard is issued under the fixed designation E520; 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 mendations issued by the World Trade Organization Technical
Barriers to Trade (TBT) Committee.
1.1 This practice covers photomultiplier properties that are
essential to their judicious selection and use in emission and
2. Referenced Documents
absorption spectrometry. Descriptions of these properties can
2.1 ASTM Standards:
be found in the following sections:
E135 Terminology Relating to Analytical Chemistry for
Section
Structural Features 4 Metals, Ores, and Related Materials
General 4.1
External Structure 4.2
3. Terminology
Internal Structure 4.3
Electrical Properties 5
3.1 Definitions—For terminology relating to detectors refer
General 5.1
to Terminology E135.
Optical-Electronic Characteristics of the Photocathode 5.2
Current Amplification 5.3
3.2 Definitions of Terms Specific to This Standard:
Signal Nature 5.4
3.2.1 solar blind, n—photocathode of photomultiplier tube
Dark Current 5.5
does not respond to higher wavelengths.
Noise Nature 5.6
Photomultiplier as a Component in an Electrical Circuit 5.7
3.2.1.1 Discussion—In general, solar blind photomultiplier
Precautions and Problems 6
tubes used in atomic emission spectrometry transmit radiation
General 6.1
below about 300 nm and do not transmit wavelengths above
Fatigue and Hysteresis Effects 6.2
Illumination of Photocathode 6.3
300 nm.
Gas Leakage 6.4
Recommendations on Important Selection Criteria 7
4. Structural Features
1.2 Radiation in the frequency range common to analytical
4.1 General—The external structure and dimensions, as
emission and absorption spectrometry is detected by photomul-
well as the internal structure and electrical properties, can be
tipliers presently to the exclusion of most other transducers.
significant in the selection of a photomultiplier.
Detection limits, analytical sensitivity, and accuracy depend on
the characteristics of these current-amplifying detectors as well
4.2 External Structure—The external structure consists of
as other factors in the system.
envelope configurations, window materials, electrical contacts
through the glass-wall envelopes, and exterior housing.
1.3 This standard does not purport to address all of the
4.2.1 Envelope Configurations—Glass envelope shapes and
safety concerns, if any, associated with its use. It is the
dimensions are available in an abundant variety. Two envelope
responsibility of the user of this standard to establish appro-
configurations are common, the end-on (or head-on) and
priate safety, health, and environmental practices and deter-
side-on types (see Fig. 1).
mine the applicability of regulatory limitations prior to use.
4.2.2 Window Materials—Various window materials, such
1.4 This international standard was developed in accor-
as glass, quartz and quartz-like materials, sapphire, magnesium
dance with internationally recognized principles on standard-
fluoride, and cleaved lithium fluoride, cover the ranges of
ization established in the Decision on Principles for the
spectral transmission essential to efficient detection in spectro-
Development of International Standards, Guides and Recom-
metric applications. Window cross sections for the end-on type
photomultipliers include plano-plano, plano-concave,
This practice is under the jurisdiction of ASTM Committee E01 on Analytical
Chemistry for Metals, Ores, and Related Materials and is the direct responsibility of
Subcommittee E01.20 on Fundamental Practices. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved April 1, 2023. Published April 2023. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
ɛ1
approved in 1998. Last previous edition approved in 2015 as E520 – 08 (2015) . Standards volume information, refer to the standard’s Document Summary page on
DOI: 10.1520/E0520-08R23. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E520 − 08 (2023)
at a region where the electric field is directed away from the
surface and toward the next dynode. Six of these configurations
are shown in Fig. 2. Ordinarily a photomultiplier uses from 4
dynodes to 16 dynodes. There are several different configura-
tions of anodes including multianodes and cross wire anodes
for position sensitivity.
4.3.3 Rigidness of Structural Components—The standard
structural components generally will not endure exceptional
mechanical shocks. However, specifically constructed photo-
multipliers (ruggedized) that are resistant to damage by me-
chanical shock and stress are available for special applications,
such as geophysical uses or in mobile laboratories.
5. Electrical Properties
5.1 General—The electrical properties of a photomultiplier
are a complex function of the cathode, dynodes, and the
voltage divider bridge used for gain control.
5.2 Optical-Electronic Characteristics of the
Photocathode—Electrons are ejected into a vacuum from the
conduction bands of semiconducting or conducting materials if
the surface of the material is exposed to electromagnetic
radiation having a photon energy higher than that required by
the photoelectric work-function threshold. The number of
electrons emitted per incident photon, that is, the quantum
efficiency, is likely to be less than unity and typically less than
0.3.
FIG. 1 Envelope Configurations
convexo-concave forms, and a hemispherical form for the
collection of 2-π radians of light flux.
4.2.3 Electrical Connections—Standard pin bases, flying-
leads, or potted pin bases are available to facilitate the location
of a photomultiplier, or for the use of a photomultiplier at low
temperatures. TFE-fluorocarbon receptacles for pin-base types
are recommended to minimize the current leakage between
pins.
4.2.4 Housing—The housing for a photomultiplier should
be “light tight.” Light leaks into a housing or monochromator
from fluorescent lamps are particularly bad noise sources
which can be readily detected with an oscilloscope adjusted for
twice the power line frequency. A mu-metal housing or shield
is recommended to diminish stray magnetic field interferences
with the internal focus on electron trajectories between tube
elements.
4.3 Internal Structure—The internal structure consists of
arrangements of cathode, dynodes, and anodes.
4.3.1 Photocathode—A typical photomultiplier of the
end-on configuration possesses a semitransparent to opaque
layer of photoemissive material that is deposited on the inner
surface of the window segment in an evacuated glass envelope.
In the side-on window types, the cathode layer is on a reflective
substrate within the evacuated tube or on the inner surface of
the window.
4.3.2 Dynodes and Anode—Secondary-electron multiplica-
tion systems are designed so that the electrons strike a dynode FIG. 2 Electrostatic Dynode Structures
E520 − 08 (2023)
5.2.1 Spectral Response—The spectral response of a photo- electron energy and the work function of the material used for
cathode is the relative rate of photoelectron production as a the dynode surface. Most often dynode surfaces are Cs-Sb or
function of the wavelength of the incident radiation of constant Be-O composites on Cu/Be or Ni substrates. The gain per
flux density and solid angle. Spectral response is measured at dynode stage generally is purposely limited.
the cathode with a simple anode or at the anode of a 5.3.2 Overall Gain—A series of dynodes, arranged so that a
secondary-electron photomultiplier. Usually, this wavelength- stepwise amplification of electrons from a photocathode
dependent response is expressed in amperes per watt at anode. occurs, constitutes a total secondary electron multiplication
5.2.1.1 Spectral response curves for several common stan- system. Ordinarily, the number of dynodes employed in a
dard cathode-types are shown in Fig. 3. The S-number is a photomultiplier ranges from 4 to 16. The overall gain for a
standard industrial reference number for a given cathode type system, G, is related to the mean gain per stage, g, and the
n
and spectral response. Some of the common cathode surface number of dynode stages, n, by the equation G?=?g . Overall
compositions are listed below. Semiconductive photocathodes, gains in the order of 10 can be achieved easily.
for example, GaAs(Cs) and InGaAs(Cs), as well as red- 5.3.3 Gain Control (Voltage-Divider Bridge)—Since, for a
enhanced multialkali photocathodes (S-25) are also available. given photomultiplier the cathode and dynode surface materi-
A “solar blind” response cathode of CsI, not shown in Fig. 3, als and arrangement are fixed, the only practical means to
provides a low-noise signal in the 160 nm to 300 nm region of change the overall gain is to control the voltages applied to the
the spectrum. Intensity measurements at wavelengths below individual tube elements. This control is accomplished by
100 nm can be made with a windowless, gold-cathode photo- adjusting the voltage that is furnished by a high-voltage supply
multiplier. and that is imposed across a voltage-divider bridge (see Fig. 4).
Selection of proper resistance values and the configuration for
Examples of Cathode Surfaces
Response Type Designation Window Cathode Surface
the voltage-divider bridge ultimately determine whether a
S-1? Lime Glass Ag-O-Cs
given photomultiplier will function with stability and linearity
(Reflection)
in a certain application. Operational stability is determined by
S-5? Ultraviolet Sb-Cs
Transmitting Glass (Reflection)
the stability of the high voltage supplied to the divider-bridge
S-11 Lime Glass Sb-Cs
by the relative anode and divider-bridge currents and by the
(Semitransparent)
stability of each dynode voltage as determined by the divider-
S-13 Fused Silica Sb-Cs
(Semitransparent)
bridge.
S-20 Lime Glass Sb-Na-K-Cs
5.3.3.1 To a first approximation, the error in the gain varies
(Semitransparent)
proportionately to the error in the applied high voltage multi-
5.3 Current Amplification—The feeble photoelectron cur-
plied by the number of stages. Therefore, for a ten-stage tube,
rent generated at the cathode is increased to a conveniently
a gain stability of 61? % is attained with a power-supply
measurable level by a secondary electron multiplication sys-
voltage stability of 6 0.1? %.
tem. The mechanism for electron multiplication simply de-
5.3.3.2 For a tube stability of 1? %, the current drawn from
pends on the principle that the collision of an energetic electron
the heaviest loaded stage must be less than 1? % of the total
with a low work-function surface (dynode) will cause the
current through the voltage divider bridge. For most spectro-
ejection of several secondary electrons. Thus, a primary
scopic applications, a bridge current of about 0.5 mA to 1 mA
photoelectron that is directed by an electrostatic field and
is sufficient.
through an accelerating voltage to the first tube dynode will
5.3.3.3 The value of R (see Fig. 4) is set to give a voltage
effectively be amplified by a factor equal to the number of
between the cathode and the first dynode as recommended by
secondary electrons ejected from the single collision.
the manufacturer. Resistors R , R ···R , R , R , and R
2 3 n−2 n−1 n n+1
5.3.1 Gain per Stage—The amplification factor or gain
may be graded to give interstage voltages which are appropri-
produced at a dynode stage depends both on the primary
ate to the required peak current. With higher interstage voltages
at the output end of the tube, higher peak currents can be
drawn, but average currents above 1 mA are not normally
recommended. The value selected for decoupling-capacitors,
FIG. 3 Spectral Response Curves for Several Cathode Types FIG. 4 Voltage-Divider Bridge
E520 − 08 (2023)
C, which serve to prevent sudden significant interstage voltage exists even when the cathode is not illuminated. This total
changes between the last few dynodes, is dependent on the current is referred to as dark current.
signal frequency. Typically, the capacitance, C, is about two
5.5.1 Spectral Response and Dark Current—In general,
nanofarads (nF). In Fig. 4, A can be a load resistor (1 MΩ to
those cathode surfaces which provide extended red response
10 MΩ) or the input impedance to a current-measuring device.
have both low photoelectric-work functions and low
5.3.3.4 The overall gain of a photomultiplier varies in a
thermionic-work functions. Therefore, higher dark currents can
nonlinear fashion with the overall voltage applied to the divider
be expected for tubes with red-sensitive cathodes. However,
bridge as shown in Fig. 5.
the S-20 surface, which has much better red response and
5.3.4 Linearity of Response—A photomultiplier is capable
higher quantum efficiency than the S-11 surface, has a thermi-
of providing a linear response to the radiant input signal over
onic emission level that is equal to or lower than that of the
several orders of magnitude. Usually, the dynamic range at the
S-11.
photomultiplier exceeds the range capability of the common
5.5.2 Cathode Size—The dark current from thermionic elec-
linear voltage amplifiers used in measuring circuits.
trons is directly proportional to the area of photocathode
5.3.5 Anode Saturation—As the light intensity impinging on
viewed by the first dynode.
a photocathode is increased, an intensity level is reached,
5.5.3 Internal Apertures—Some photomultipliers are pro-
above which the anode current will no longer increase. A
vided with a defining aperture plane (or plate) between the
current-density saturation at the anode, or anode saturation, is
photocathode and the first dynode. The target plate defines an
responsible for this effect. A photomultiplier should never be
aperture that limits the area of the cathode viewed by the first
operated at anode saturation conditions nor in the nonlinear
dynode and effectively reduces dark current.
response region approaching saturation because of possible
5.5.4 Refrigeration of Photocathodes—Dark current from
damage to the tube.
S-1-type photomultipliers can be reduced considerably by
5.4 Signal Nature—The current through a photomultiplier is
cooling the photocathode. The S-1 dark current i
...


This document is not an ASTM standard and is intended only to provide the user of an ASTM standard an indication of what changes have been made to the previous version. Because
it may not be technically possible to adequately depict all changes accurately, ASTM recommends that users consult prior editions as appropriate. In all cases only the current version
of the standard as published by ASTM is to be considered the official document.
´1
Designation: E520 − 08 (Reapproved 2015) E520 − 08 (Reapproved 2023)
Standard Practice for
Describing Photomultiplier Detectors in Emission and
Absorption Spectrometry
This standard is issued under the fixed designation E520; 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.
ε NOTE—Editorial corrections were made to 1.1, 3.2.1, and 4.2.1 in February 2016.
1. Scope
1.1 This practice covers photomultiplier properties that are essential to their judicious selection and use in emission and absorption
spectrometry. Descriptions of these properties can be found in the following sections:
Section
Structural Features 4
General 4.1
External Structure 4.2
Internal Structure 4.3
Electrical Properties 5
General 5.1
Optical-Electronic Characteristics of the Photocathode 5.2
Current Amplification 5.3
Signal Nature 5.4
Dark Current 5.5
Noise Nature 5.6
Photomultiplier as a Component in an Electrical Circuit 5.7
Precautions and Problems 6
General 6.1
Fatigue and Hysteresis Effects 6.2
Illumination of Photocathode 6.3
Gas Leakage 6.4
Recommendations on Important Selection Criteria 7
1.2 Radiation in the frequency range common to analytical emission and absorption spectrometry is detected by photomultipliers
presently to the exclusion of most other transducers. Detection limits, analytical sensitivity, and accuracy depend on the
characteristics of these current-amplifying detectors as well as other factors in the system.
1.3 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 and healthsafety, health, and environmental practices and determine
the applicability of regulatory limitations prior to use.
1.4 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.
This practice is under the jurisdiction of ASTM Committee E01 on Analytical Chemistry for Metals, Ores, and Related Materials and is the direct responsibility of
Subcommittee E01.20 on Fundamental Practices.
Current edition approved Dec. 15, 2015April 1, 2023. Published February 2016April 2023. Originally approved in 1998. Last previous edition approved in 20082015 as
ɛ1
E520 – 08. 08 (2015) . DOI: 10.1520/E0520-08R15E01.10.1520/E0520-08R23.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E520 − 08 (2023)
2. Referenced Documents
2.1 ASTM Standards:
E135 Terminology Relating to Analytical Chemistry for Metals, Ores, and Related Materials
3. Terminology
3.1 Definitions—For terminology relating to detectors refer to Terminology E135.
3.2 Definitions of Terms Specific to This Standard:
3.2.1 solar blind, n—photocathode of photomultiplier tube does not respond to higher wavelengths.
3.2.1.1 Discussion—
In general, solar blind photomultiplier tubes used in atomic emission spectrometry transmit radiation below about 300 nm and do
not transmit wavelengths above 300 nm.
4. Structural Features
4.1 General—The external structure and dimensions, as well as the internal structure and electrical properties, can be significant
in the selection of a photomultiplier.
4.2 External Structure—The external structure consists of envelope configurations, window materials, electrical contacts through
the glass-wall envelopes, and exterior housing.
4.2.1 Envelope Configurations—Glass envelope shapes and dimensions are available in an abundant variety. Two envelope
configurations are common, the end-on (or head-on) and side-on types (see Fig. 1).
FIG. 1 Envelope Configurations
For referenced ASTM standards, visit the ASTM website, www.astm.org, or contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM Standards
volume information, refer to the standard’s Document Summary page on the ASTM website.
E520 − 08 (2023)
4.2.2 Window Materials—Various window materials, such as glass, quartz and quartz-like materials, sapphire, magnesium
fluoride, and cleaved lithium fluoride, cover the ranges of spectral transmission essential to efficient detection in spectrometric
applications. Window cross sections for the end-on type photomultipliers include plano-plano, plano-concave, convexo-concave
forms, and a hemispherical form for the collection of 2-π radians of light flux.
4.2.3 Electrical Connections—Standard pin bases, flying-leads, or potted pin bases are available to facilitate the location of a
photomultiplier, or for the use of a photomultiplier at low temperatures. TFE-fluorocarbon receptacles for pin-base types are
recommended to minimize the current leakage between pins.
4.2.4 Housing—The housing for a photomultiplier should be “light tight.” Light leaks into a housing or monochromator from
fluorescent lamps are particularly bad noise sources which can be readily detected with an oscilloscope adjusted for twice the
power line frequency. A mu-metal housing or shield is recommended to diminish stray magnetic field interferences with the internal
focus on electron trajectories between tube elements.
4.3 Internal Structure—The internal structure consists of arrangements of cathode, dynodes, and anodes.
4.3.1 Photocathode—A typical photomultiplier of the end-on configuration possesses a semitransparent to opaque layer of
photoemissive material that is deposited on the inner surface of the window segment in an evacuated glass envelope. In the side-on
window types, the cathode layer is on a reflective substrate within the evacuated tube or on the inner surface of the window.
4.3.2 Dynodes and Anode—Secondary-electron multiplication systems are designed so that the electrons strike a dynode at a
region where the electric field is directed away from the surface and toward the next dynode. Six of these configurations are shown
in Fig. 2. Ordinarily a photomultiplier uses from 4 dynodes to 16 dynodes. There are several different configurations of anodes
including multianodes and cross wire anodes for position sensitivity.
4.3.3 Rigidness of Structural Components—The standard structural components generally will not endure exceptional mechanical
FIG. 2 Electrostatic Dynode Structures
E520 − 08 (2023)
shocks. However, specifically constructed photomultipliers (ruggedized) that are resistant to damage by mechanical shock and
stress are available for special applications, such as geophysical uses or in mobile laboratories.
5. Electrical Properties
5.1 General—The electrical properties of a photomultiplier are a complex function of the cathode, dynodes, and the voltage
divider bridge used for gain control.
5.2 Optical-Electronic Characteristics of the Photocathode—Electrons are ejected into a vacuum from the conduction bands of
semiconducting or conducting materials if the surface of the material is exposed to electromagnetic radiation having a photon
energy higher than that required by the photoelectric work-function threshold. The number of electrons emitted per incident
photon, that is, the quantum efficiency, is likely to be less than unity and typically less than 0.3.
5.2.1 Spectral Response—The spectral response of a photocathode is the relative rate of photoelectron production as a function
of the wavelength of the incident radiation of constant flux density and solid angle. Spectral response is measured at the cathode
with a simple anode or at the anode of a secondary-electron photomultiplier. Usually, this wavelength-dependent response is
expressed in amperes per watt at anode.
5.2.1.1 Spectral response curves for several common standard cathode-types are shown in Fig. 3. The S-number is a standard
industrial reference number for a given cathode type and spectral response. Some of the common cathode surface compositions
are listed below. Semiconductive photocathodes, for example, GaAs(Cs) and InGaAs(Cs), as well as red-enhanced multialkali
photocathodes (S-25) are also available. A “solar blind” response cathode of CsI, not shown in Fig. 3, provides a low-noise signal
in the 160-nm to 300-nm160 nm to 300 nm region of the spectrum. Intensity measurements at wavelengths below 100 nm can be
made with a windowless, gold-cathode photomultiplier.
Examples of Cathode Surfaces
Response Type Designation Window Cathode Surface
S-1? Lime Glass Ag-O-Cs
(Reflection)
S-5? Ultraviolet Sb-Cs
Transmitting Glass (Reflection)
S-11 Lime Glass Sb-Cs
(Semitransparent)
S-13 Fused Silica Sb-Cs
(Semitransparent)
S-20 Lime Glass Sb-Na-K-Cs
(Semitransparent)
5.3 Current Amplification—The feeble photoelectron current generated at the cathode is increased to a conveniently measurable
level by a secondary electron multiplication system. The mechanism for electron multiplication simply depends on the principle
that the collision of an energetic electron with a low work-function surface (dynode) will cause the ejection of several secondary
electrons. Thus, a primary photoelectron that is directed by an electrostatic field and through an accelerating voltage to the first
tube dynode will effectively be amplified by a factor equal to the number of secondary electrons ejected from the single collision.
FIG. 3 Spectral Response Curves for Several Cathode Types
E520 − 08 (2023)
5.3.1 Gain per Stage—The amplification factor or gain produced at a dynode stage depends both on the primary electron energy
and the work function of the material used for the dynode surface. Most often dynode surfaces are Cs-Sb or Be-O composites on
Cu/Be or Ni substrates. The gain per dynode stage generally is purposely limited.
5.3.2 Overall Gain—A series of dynodes, arranged so that a stepwise amplification of electrons from a photocathode occurs,
constitutes a total secondary electron multiplication system. Ordinarily, the number of dynodes employed in a photomultiplier
ranges from 4 to 16. The overall gain for a system, G, is related to the mean gain per stage, g, and the number of dynode stages,
n 6
n, by the equation G?=?g . Overall gains in the order of 10 can be achieved easily.
5.3.3 Gain Control (Voltage-Divider Bridge)—Since, for a given photomultiplier the cathode and dynode surface materials and
arrangement are fixed, the only practical means to change the overall gain is to control the voltages applied to the individual tube
elements. This control is accomplished by adjusting the voltage that is furnished by a high-voltage supply and that is imposed
across a voltage-divider bridge (see Fig. 4). Selection of proper resistance values and the configuration for the voltage-divider
bridge ultimately determine whether a given photomultiplier will function with stability and linearity in a certain application.
Operational stability is determined by the stability of the high voltage supplied to the divider-bridge by the relative anode and
divider-bridge currents and by the stability of each dynode voltage as determined by the divider-bridge.
5.3.3.1 To a first approximation, the error in the gain varies proportionately to the error in the applied high voltage multiplied by
the number of stages. Therefore, for a ten-stage tube, a gain stability of 61?%61? % is attained with a power-supply voltage
stability of 6 0.1?%.0.1? %.
5.3.3.2 For a tube stability of 1?%,1? %, the current drawn from the heaviest loaded stage must be less than 1?%1? % of the total
current through the voltage divider bridge. For most spectroscopic applications, a bridge current of about 0.5 mA to 1 mA is
sufficient.
5.3.3.3 The value of R (see Fig. 4) is set to give a voltage between the cathode and the first dynode as recommended by the
manufacturer. Resistors R , R ···R , R , R , and R may be graded to give interstage voltages which are appropriate to the
2 3 n−2 n−1 n n+1
required peak current. With higher interstage voltages at the output end of the tube, higher peak currents can be drawn, but average
currents above 1 mA are not normally recommended. The value selected for decoupling-capacitors, C, which serve to prevent
sudden significant interstage voltage changes between the last few dynodes, is dependent on the signal frequency. Typically, the
capacitance, C, is about two nanofarads (nF). In Fig. 4, A can be a load resistor (1 MΩ to 10 MΩ) (1 MΩ to 10 MΩ) or the input
impedance to a current-measuring device.
5.3.3.4 The overall gain of a photomultiplier varies in a nonlinear fashion with the overall voltage applied to the divider bridge
as shown in Fig. 5.
5.3.4 Linearity of Response—A photomultiplier is capable of providing a linear response to the radiant input signal over several
orders of magnitude. Usually, the dynamic range at the photomultiplier exceeds the range capability of the common linear voltage
amplifiers used in measuring circuits.
5.3.5 Anode Saturation—As the light intensity impinging on a photocathode is increased, an intensity level is reached, above
which the anode current will no longer increase. A current-density saturation at the anode, or anode saturation, is responsible for
this effect. A photomultiplier should never be operated at anode saturation conditions nor in the nonlinear response region
approaching saturation because of possible damage to the tube.
FIG. 4 Voltage-Divider Bridge
E520 − 08 (2023)
A.?Venetian Blind-15 Dynodes
B.?Box and Grid-11 Dynodes
C.?Venetian Blind-11 Dynodes
FIG. 5 Overall Gain Dependence on Applied Voltage (SbCs Cathode)
5.4 Signal Nature—The current through a photomultiplier is composed of discrete charge carriers. Each effective photoelectron
is randomly emitted from the cathode and travels a distance to the first dynode where a small packet of electrons is generated. This
packet of electrons then travels to the next dynode where yet a larger packet of electrons is produced, and this process continues
repetitively until a final large packet of electrons reaches the anode to produce a measurable electri
...

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ASTM E520-08(2023)e1(Practice)
Standard Practice for Describing Photomultiplier Detectors in Emission and Absorption Spectrometry

ABSTRACT
This practice describes the photomultiplier properties that are essential to their judicious selection and use of in emission and absorption spectrometry. The properties covered here include structural features, electrical properties, and characteristics involved in precautions and problems. The structural features covered are envelope configurations, window materials, electrical connections, and housing for the external structure, and the photocathode, dynodes and anode, and rigidness of structural components for the internal structure. Electrical properties, on the other hand, incorporate the following: optical-electronic characteristics of the photocathode including spectral response; current amplification including gain per stage, overall gain, gain control (voltage-divider bridge), linearity of response, and anode saturation; signal nature; dark current including cathode size, internal aperture, and refrigeration effects; noise nature including additivity of noise power, signal-to-noise ratio, equivalent noise input; and photomultiplier properties as a component in an electrical circuit including output impedance, response time, and signal gating and integration possibilities. Finally, the characteristics involved in precautions and problems cover fatigue and hysteresis effects, illumination of photocathode, and gas leakage.
SCOPE
1.1 This practice covers photomultiplier properties that are essential to their judicious selection and use in emission and absorption spectrometry. Descriptions of these properties can be found in the following sections:    
Section  
Structural Features  
4  
General  
4.1  
External Structure  
4.2  
Internal Structure  
4.3  
Electrical Properties  
5  
General  
5.1  
Optical-Electronic Characteristics of the Photocathode  
5.2  
Current Amplification  
5.3  
Signal Nature  
5.4  
Dark Current  
5.5  
Noise Nature  
5.6  
Photomultiplier as a Component in an Electrical Circuit  
5.7  
Precautions and Problems  
6  
General  
6.1  
Fatigue and Hysteresis Effects  
6.2  
Illumination of Photocathode  
6.3  
Gas Leakage  
6.4  
Recommendations on Important Selection Criteria  
7  
1.2 Radiation in the frequency range common to analytical emission and absorption spectrometry is detected by photomultipliers presently to the exclusion of most other transducers. Detection limits, analytical sensitivity, and accuracy depend on the characteristics of these current-amplifying detectors as well as other factors in the system.  
1.3 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.  
1.4 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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1.1 This guide covers the best practices for use of various turbidimeter designs for measurement of turbidity in waters including: drinking water, wastewater, industrial waters, and for regulatory and environmental monitoring. This guide covers both continuous and static measurements.  
1.1.1 In principle there are three basic applications for on-line measurement set ups. The first is the bypass or slipstream technique; a portion of sample is transported from the process or sample stream and to the turbidimeter for analysis. It is then either transported back to the sample stream or to waste. The second is the in-line measurement; the sensor is submerged directly into the sample or process stream, which is typically contained in a pipe. The third is in-situ where the sensor is directly inserted into the sample stream. The in-situ principle is intended for the monitoring of water during any step within a processing train, including immediately before or after the process itself.  
1.1.2 Static covers both benchtop and portable designs for the measurement of water samples that are captured into a cell and then measured.  
1.2 Depending on the monitoring goals and desired data requirements, certain technologies will deliver more desirable results for a given application. This guide will help the user align a technology to a given application with respect to best practices for data collection.  
1.3 Some designs are applicable for either a lower or upper measurement range. This guide will help provide guidance to the best-suited technologies based given range of turbidity.  
1.4 Modern electronic turbidimeters are comprised of many parts that can cause them to produce different results on samples. The wavelength of incident light used, detector type, detector angle, number of detectors (and angles), and optical pathlength are all design criteria that may be different among instruments. When these sensors are all calibra...

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ASTM D3321-19(2023)(Test Method)
Standard Test Method for Use of the Refractometer for Field Test Determination of the Freezing Point of Aqueous Engine Coolants

SIGNIFICANCE AND USE
4.1 This practice is commonly used by vehicle service personnel to determine the freezing point, in degrees Celsius or Fahrenheit, of aqueous solutions of commercial ethylene and propylene glycol-based coolant. A durable hand-held refractometer is available that reads the freezing point, directly, in degrees Celsius or Fahrenheit, when a few drops of engine coolant are properly placed on the temperature-compensated prism surface of the refractometer. This refractometer is for glycol and water solutions, and is not suitable for other coolant solutions.  
4.2 The hand-held refractometer should be calibrated before use (see Section 7).  
4.3 Care must be taken to use the correct glycol freezing point scale for the glycol type being measured. Use of the wrong glycol scale can result in freezing point errors of 18 and more degrees Fahrenheit.  
4.4 Ethylene glycol/propylene glycol mixtures will result in inaccurate freezing point measurements using either freezing point scale.
SCOPE
1.1 This test method covers the use of a portable refractometer for determining the approximate freezing protection provided by ethylene and propylene glycol-based coolant solutions as used in engine cooling systems and special applications.  
Note 1: Some instruments have a supplementary freezing protection scale for methoxypropanol coolants. Others carry a supplemental scale calibrated in density or specific gravity readings of sulfuric acid solutions so that the refractometer can be used to determine the charged condition of lead acid storage batteries.  
1.2 The values stated in SI units are to be regarded as standard. The values given in parentheses after SI units are provided for information only and are not considered standard.  
1.3 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.  
1.4 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 E3143-18b(2023)(Practice)
Standard Practice for Performing Cryo-Transmission Electron Microscopy of Liposomes

SIGNIFICANCE AND USE
5.1 Cryo-TEM is a technique used to record high resolution images of samples that are frozen and embedded in a thin layer of vitrified, amorphous ice (2-5). Because vitrification occurs so rapidly, the resultant specimen is almost instantly frozen, yielding a very accurate representation of the specimen at the moment of freezing, without the distortions typically associated with air drying delicate wet samples. Once frozen, images of the specimen are recorded at low temperature using a specially designed electron microscope equipped with a cryo-holder capable of operating under low dose conditions in order to prevent beam induced structural damage to the specimen. The cryo-TEM technique is the consensus choice to directly observe, analyze and accurately measure liposomes suspended in aqueous solutions. Fig. 1 illustrates this by comparing an electron micrograph from an air-dried negatively stained liposomal preparation with an electron micrograph of the same solution imaged by cryo-TEM.
FIG. 1 Left—An Electron Micrograph of an Air-Dried Liposomal Preparation that has been Negatively Stained with 2 % Uranyl Acetate for Contrast; Right—An Electron Micrograph of the Same Liposomal Preparation Prepared as a Frozen Vitrified Specimen for Cryo-TEM
Note 1: Both images are shown to the same scale; scale bar is 200 nm.  
5.1.1 Fig. 1 demonstrates that liposomes may become distorted and are difficult to measure and analyze when they are air-dried, while the same liposomal preparation is clearly easier to analyze when the specimen is near-instantly preserved by vitrification.  
5.1.2 Cryo-TEM involves applying a small volume of sample to a specially prepared holey, ultra-thin or continuous carbon grid suspended in a cryo-TEM plunger over a cup of liquid ethane cooled in a container filled with liquid nitrogen (2, 3). These grids can be purchased or prepared in the laboratory using a carbon evaporator with glow discharge capabilities. Once the sample has wet the surface o...
SCOPE
1.1 This practice covers procedures for vitrifying and recording images of a suspension of liposomes with a cryo-transmission electron microscope (cryo-TEM) for the purpose of evaluating their shape, size distribution and lamellarity for quality assessment. The sample is vitrified in liquid ethane onto specially prepared holey, ultra-thin, or continuous carbon TEM grids, and imaged in a cryo-holder placed in a cryo-TEM.  
1.2 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.3 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.  
1.4 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 D6122-23(Practice)
Standard Practice for Validation of the Performance of Multivariate Online, At-Line, Field and Laboratory Infrared Spectrophotometer, and Raman Spectrometer Based Analyzer Systems

SIGNIFICANCE AND USE
5.1 The primary purpose of this practice is to permit the user to validate numerical values produced by a multivariate, infrared or near-infrared laboratory or process (online or at-line) analyzer calibrated to measure a specific chemical concentration, chemical property, or physical property. If the analyzer results agree with the primary test method to within limits based on the multivariate model for the user-prespecified statistical confidence level, these results can be considered ’validated’ to the user pre-specified confidence limit for a specific application, and hence can be considered useful for that specific application.  
5.2 Procedures are described for verifying that the instrument, the model, and the analyzer system are stable and properly operating.  
5.3 A multivariate analyzer system inherently utilizes a multivariate calibration model. In practice, the model both implicitly and explicitly spans some subset of the population of all possible samples that could be in the complete multivariate sample space. The model is applicable only to samples that fall within the subset population used in the model construction. A sample measurement cannot be validated unless applicability is established. Applicability cannot be assumed.  
5.3.1 Outlier detection methods are used to demonstrate applicability of the calibration model for the analysis of the process sample spectrum. The outlier detection limits are based on historical as well as theoretical criteria. The outlier detection methods are used to establish whether the results obtained by an analyzer are potentially valid. The validation procedures are based on mathematical test criteria that indicate whether the process sample spectrum is within the range spanned by the analyzer system calibration model. If the sample spectrum is an outlier, the analyzer result is invalid. If the sample spectrum is not an outlier, then the analyzer result is valid providing that all other requirements for validity are...
SCOPE
1.1 This practice covers requirements for the validation of measurements made by laboratory, field, or process (online or at-line) infrared (near- or mid-infrared analyzers, or both), and Raman analyzers, used in the calculation of physical, chemical, or quality parameters (that is, properties) of liquid petroleum products and fuels. The properties are calculated from spectroscopic data using multivariate modeling methods. The requirements include verification of adequate instrument performance, verification of the applicability of the calibration model to the spectrum of the sample under test, and verification that the uncertainties associated with the degree of agreement between the results calculated from the infrared or Raman measurements and the results produced by the PTM used for the development of the calibration model meets user-specified requirements. Initially, a limited number of validation samples representative of current production are used to do a local validation. When there is an adequate number of validation samples with sufficient variation in both property level and sample composition to span the model calibration space, the statistical methodology of Practice D6708 can be used to provide general validation of this equivalence over the complete operating range of the analyzer. For cases where adequate property and composition variation is not achieved, local validation shall continue to be used.  
1.1.1 For some applications, the analyzer and PTM are applied to the same material. The application of the multivariate model to the analyzer output (spectrum) directly produces a PPTMR for the same material for which the spectrum was measured. The PPTMRs are compared to the PTMRs measured on the same materials to determine the degree of agreement.  
1.1.2 For other applications, the material measured by the analyzer system is subjected to a consistent additive treatment prior to being analyzed by the PTM...

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ASTM E2911-23(Guide)
Standard Guide for Relative Intensity Correction of Raman Spectrometers

SIGNIFICANCE AND USE
4.1 Generally, Raman spectra measured using grating-based dispersive or Fourier transform Raman spectrometers have not been corrected for the instrumental response (spectral responsivity of the detection system). Raman spectra obtained with different instruments may show significant variations in the measured relative peak intensities of a sample compound. This is mainly as a result of differences in their wavelength-dependent optical transmission and detector efficiencies. These variations can be particularly large when widely different laser excitation wavelengths are used, but can occur when the same laser excitation is used and spectra of the same compound are compared between instruments. This is illustrated in Fig. 1, which shows the uncorrected luminescence spectrum of SRM 2241, acquired upon four different commercially available Raman spectrometers operating with 785 nm laser excitation. Instrumental response variations can also occur on the same instrument after a component change or service work has been performed. Each spectrometer, due to its unique combination of filters, grating, collection optics and detector response, has a very unique spectral response. The spectrometer dependent spectral response will of course also affect the shape of Raman spectra acquired upon these systems. The shape of this response is not to be construed as either “good or bad” but is the result of design considerations by the spectrometer manufacturer. For instance, as shown in Fig. 1, spectral coverage can vary considerably between spectrometer systems. This is typically a deliberate tradeoff in spectrometer design, where spectral coverage is sacrificed for enhanced spectral resolution.
FIG. 1 SRM 2241 Measured on Four Commercial Raman Spectrometers Utilizing 785 nm Excitation  
4.2 Variations in spectral peak intensities can be mostly corrected through calibration of the Raman intensity (y) axis. The conventional method of calibration of the spectral response of a Raman...
SCOPE
1.1 This guide is designed to enable the user to correct a Raman spectrometer for its relative spectral-intensity response function using NIST Standard Reference Materials2 in the 224X series (currently SRMs 2241, 2242, 2243, 2244, 2245, 2246), or a calibrated irradiance source. This relative intensity correction procedure will enable the intercomparison of Raman spectra acquired from differing instruments, excitation wavelengths, and laboratories.  
1.2 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.3 Because of the significant dangers associated with the use of lasers, ANSI Z136.1 or suitable regional standards should be followed in conjunction with this practice.  
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.  
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 E520-08(2023)e1(Practice)
Standard Practice for Describing Photomultiplier Detectors in Emission and Absorption Spectrometry

ABSTRACT
This practice describes the photomultiplier properties that are essential to their judicious selection and use of in emission and absorption spectrometry. The properties covered here include structural features, electrical properties, and characteristics involved in precautions and problems. The structural features covered are envelope configurations, window materials, electrical connections, and housing for the external structure, and the photocathode, dynodes and anode, and rigidness of structural components for the internal structure. Electrical properties, on the other hand, incorporate the following: optical-electronic characteristics of the photocathode including spectral response; current amplification including gain per stage, overall gain, gain control (voltage-divider bridge), linearity of response, and anode saturation; signal nature; dark current including cathode size, internal aperture, and refrigeration effects; noise nature including additivity of noise power, signal-to-noise ratio, equivalent noise input; and photomultiplier properties as a component in an electrical circuit including output impedance, response time, and signal gating and integration possibilities. Finally, the characteristics involved in precautions and problems cover fatigue and hysteresis effects, illumination of photocathode, and gas leakage.
SCOPE
1.1 This practice covers photomultiplier properties that are essential to their judicious selection and use in emission and absorption spectrometry. Descriptions of these properties can be found in the following sections:    
Section  
Structural Features  
4  
General  
4.1  
External Structure  
4.2  
Internal Structure  
4.3  
Electrical Properties  
5  
General  
5.1  
Optical-Electronic Characteristics of the Photocathode  
5.2  
Current Amplification  
5.3  
Signal Nature  
5.4  
Dark Current  
5.5  
Noise Nature  
5.6  
Photomultiplier as a Component in an Electrical Circuit  
5.7  
Precautions and Problems  
6  
General  
6.1  
Fatigue and Hysteresis Effects  
6.2  
Illumination of Photocathode  
6.3  
Gas Leakage  
6.4  
Recommendations on Important Selection Criteria  
7  
1.2 Radiation in the frequency range common to analytical emission and absorption spectrometry is detected by photomultipliers presently to the exclusion of most other transducers. Detection limits, analytical sensitivity, and accuracy depend on the characteristics of these current-amplifying detectors as well as other factors in the system.  
1.3 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.  
1.4 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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