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ASTM E1511-93(2005)

(Practice)

Standard Practice for Testing Conductivity Detectors Used in Liquid and Ion Chromatography

Standard Practice for Testing Conductivity Detectors Used in Liquid and Ion Chromatography

SIGNIFICANCE AND USE
This practice is intended to describe the performance of a conductivity detector independent of the chromatographic system in terms that the analyst can use to predict overall system performance when the detector is coupled to the column and other chromatography system components.
Although it is possible to observe each of the several characteristics of a detector under different and unique conditions, it is the intent of this practice that a complete set of detector specifications should be obtained at the same operating conditions, including the setup used for testing, flow rates, and temperatures. It should be noted that to specify a detector’capability completely, its performance should be measured at several sets of conditions within the useful range of the detector. The terms and tests described in this practice are sufficiently general so that they may be used at whatever conditions may be chosen for other reasons.
SCOPE
1.1 This practice covers the testing of the performance of conductivity detectors used as the detection component of a liquid or ion chromatography system.
1.2 The values stated in SI units are to be regarded as the standard.

General Information

Status
Historical
Publication Date
31-Jan-2005
ICS
71.040.50 - Physicochemical methods of analysis
Technical Committee
E13 - Molecular Spectroscopy and Separation Science
Drafting Committee
E13.19 - Separation Science
Current Stage
Ref Project

Relations

Replaces
ASTM E1511-93(2000) - Standard Practice for Testing Conductivity Detectors Used in Liquid and Ion Chromatography
Effective Date
01-Feb-2005
Replaced By
ASTM E1511-93(2010) - Standard Practice for Testing Conductivity Detectors Used in Liquid and Ion Chromatography
Effective Date
01-Nov-2010
Referred By
ASTM D8149-20 - Standard Practice for Optimization, Calibration, and Validation of Ion Chromatographic Determination of Heteroatoms and Anions in Petroleum Products and Lubricants
Effective Date
01-Feb-2005

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ASTM E1511-93(2005) - Standard Practice for Testing Conductivity Detectors Used in Liquid and Ion ChromatographyASTM E1511-93(2005) - Standard Practice for Testing Conductivity Detectors Used in Liquid and Ion Chromatography
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ASTM E1511-93(2005) - Standard Practice for Testing Conductivity Detectors Used in Liquid and Ion Chromatography
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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:E1511–93 (Reapproved 2005)
Standard Practice for
Testing Conductivity Detectors Used in Liquid and Ion
Chromatography
This standard is issued under the fixed designation E1511; 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 of the solution is defined to be independent of electrode and
cell dimensions. Specifically,
1.1 This practice covers the testing of the performance of
conductivity detectors used as the detection component of a 1
k5 G (1)
liquid or ion chromatography system. A
1.2 The values stated in SI units are to be regarded as the
where:
standard.
1 = the distance between two planer disk electrodes, and
A = the electrode’s surface area.
2. Referenced Documents
3.2.3.1 Discussion—In liquid and ion chromatography, cell
2.1 ASTM Standards:
dimensions are commonly measured in centimetres, so the
E1151 Practice for Ion Chromatography Terms and Rela-
units of k are S/cm. (Alternatively, the SI units of S/m may be
tionships
used. S/m = 100 S/cm.)
3.2.4 drift—the average slope of the noise envelope ex-
3. Terminology
pressed in nano siemens per centimetre per hour as measured
3.1 See Practice E1151.
over a period of 1 h.
3.2 Definitions:
3.2.5 equivalent conductivity—of an ionic solute, the con-
3.2.1 cell constant—the cell constant (K) of a conductivity
tribution of the solute to the total conductivity of the solution,
cell is equal to 1/A,so k =GK.
measured in microsiemens per centimetre, divided by its
3.2.1.1 Discussion—If the cell constant of the flow-through
concentration in milliequivalents/litre.
cell used is equal to one, then the conductivity equals the
3.2.6 flow dependence rate—the change in measured con-
conductance. Although the cell constant is often specified for
ductivity as a function of flow rate.
conductivity detectors, there is little practical value in knowing
3.2.7 limiting equivalent conductivity—of an ionic solute,
the constant as long as the detector is properly calibrated for
its equivalent conductivity extrapolated to infinite dilution.
conductivity.
3.2.8 linear range—of a conductivity detector for a given
3.2.2 conductance—the conductance (G) of a solution is the
solute in a specific solvent, the concentration range of solute
inverse of the resistance measured between two electrodes in a
for which the detector response factor is within 5 % of the
cell, expressed in units of siemens (S), equal to inverse ohms.
response factor in the middle of the range as determined from
3.2.2.1 Discussion—The term resistance refers specifically
the linearity plot specified in Section 11.
to the dc resistance to ionic current, independent of the
3.2.8.1 Discussion—The lower limit may be limited by
capacitive reactance at the interfaces between the electrodes
noise, and the upper limit by deviation from linearity. (The
and the solution.
upper limit may instead be limited by the maximum full-scale
3.2.3 conductivity—since the conductance is dependent on
deflection on the detector’s least sensitive output range.)
both the conductive properties of the solution and on the
3.2.9 long-term noise—the maximum amplitude in nano
dimensions of the electrodes and the cell, the conductivity (k)
siemenspercentimetreforallrandomvariationsofthedetector
output of frequencies between 2 and 60 cycles per hour.
This practice is under the jurisdiction of ASTM Committee E13 on Molecular
3.2.9.1 Discussion—Long-term noise represents noise that
Spectroscopy and Chromatography and is the direct responsibility of Subcommittee
can be mistaken for eluting peaks.
E13.19 on Chromatography.
3.2.10 minimum detectability—of a conductivity detector,
Current edition approved Feb. 1, 2005. Published March 2005. Originally
that concentration of solute in a specific solvent that corre-
approved in 1993. Last previous edition approved in 2000 as E1511 - 93(2000).
DOI: 10.1520/E1511-93R05.
sponds to twice the short-term noise.
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
3.2.10.1 Discussion—Because of the difficulty of pumping
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
solvents through the chromatographic system without any
Standards volume information, refer to the standard’s Document Summary page on
the ASTM website. contamination of the solvents from the system, this quantity
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
E1511–93 (2005)
can only be measured with solutes retained by a column. Since 5. Significance and Use
minimum detectability is dependent on the chromatographic
5.1 This practice is intended to describe the performance of
system used, it is not measured in this practice. However, if the
a conductivity detector independent of the chromatographic
minimum detectability of a solute is measured on one system
system in terms that the analyst can use to predict overall
with one detector, the minimum detectability can be predicted
system performance when the detector is coupled to the
when other detectors are tested on the same system by
column and other chromatography system components.
comparing the measured values of short-term noise.
5.2 Although it is possible to observe each of the several
3.2.11 response factor—of a conductivity detector, the mea-
characteristics of a detector under different and unique condi-
sured conductivity response of a solute divided by the solute tions, it is the intent of this practice that a complete set of
concentration.
detector specifications should be obtained at the same operat-
ing conditions, including the setup used for testing, flow rates,
3.2.12 response time of the detector—the time required for
andtemperatures.Itshouldbenotedthattospecifyadetector’s
theoutputofthedetectortochangefrom10to90 %ofthenew
capability completely, its performance should be measured at
equilibrium value when the composition of the eluent is
several sets of conditions within the useful range of the
changed in a stepwise manner, within the linear range of the
detector. The terms and tests described in this practice are
detector.
sufficiently general so that they may be used at whatever
3.2.12.1 Discussion—Aslow response time has the effect of
conditions may be chosen for other reasons.
limiting resolution for efficient peaks such as early eluting
peaks and those from highly efficient columns or microbore
6. Reagents
columns. Response time is generally dependent on three
6.1 Reagent chemicals are reagent grade or better.
factors: (a) cell volume, (b) volume of heat transfer tubing
6.1.1 Deionized Water, (DI water), 18 M-ohm.
leading to the cell, and (c) electronic filtering of the output.
6.1.2 Potassium Chloride, (KCl) dry powder.
3.2.13 sensitivity—thedetectorresponsedividedbyconcen-
6.1.3 Hydrochloric Acid, (HCl) standard 0.1000 N solution.
tration, which is also the response factor (11.1.1).
3.2.13.1 Discussion—Sensitivity is therefore by definition
7. Preparation of Standards
the same for all properly calibrated conductivity detectors.
7.1 Potassium Chloride Standards:
(Sensitivity is often confused with minimum detectability,
7.1.1 Prepare a 10-mM KCl standard stock solution. Weigh
which is dependent on both sensitivity and noise.) Therefore,
out 0.7455 g KCl (desiccated) and dissolve it in 18 M-ohm DI
the calibration of the detector should be measured, and if
water in a 1-Lplastic volumetric flask. Fill the flask to 1 Lwith
necessary, adjusted. Follow the manufacturer’s procedure for
DI water.
calibrating the detector. The procedure in Section 9 is used by
7.1.2 Prepare KCl standards from the 10-mM KCl standard
many manufacturers and is useful for the tests in this practice.
stock solution. Using accurate Class A pipettes, pipette the
3.2.14 short-term noise—the maximum amplitude in nano
volumes of the 10-mM standard stock solution listed below
siemenspercentimetreforallrandomvariationsofthedetector
into 100-mL plastic volumetric flasks. For the 1-mM KCl
output of a frequency greater than one cycle per minute.
standard,filla100-mLplasticvolumetricflaskwiththe10-mM
3.2.14.1 Discussion—Short-term noise determines the
KCl solution and transfer to a 1-Lplastic volumetric flask. Fill
smallest signal detectable by a conductivity detector, limits the
to the line with DI water.
precision available for the determination of trace samples, and
KCl Concentration, Volume in 100 mL DI Water,
may set the lower limit of linearity.
mm mL
0.05 0.5
4. Summary of Practice
0.1 1
0.2 2
4.1 Four different tests are performed to characterize a
0.5 5
detector.
1 100 mL in 1 L
4.1.1 Noise and drift are measured while a solution is
flowing through the detector cell. The test is performed using
10 mM No dilution
two different solutions: deionized water (DI) and 1 mM
7.2 Hydrochloric Acid Standards:
potassium chloride (KCl).
7.2.1 Prepare a 2.00-mM HCl standard stock solution by
4.1.2 Linear range is determined by preparing a plot of
diluting 20.0 mL of standard 0.1000 N HCl into a 1-L plastic
response factor versus the log of solute concentration using
volumetric flask and filling to the line with DI water. If
standard solutions of KCl and hydrochloric acid (HCl) as
standard 0.1000 N HCl is not available, a 0.10-mM HCl
solutes.
solution can be prepared by diluting 8.3 mL of 12 N (37 %)
4.1.3 Dependence of response on flow rate is measured by
concentration HCl into 1 L of DI water. (The concentration of
pumping 1 mM KCl through the conductivity cell at several
this solution will be less accurate than that prepared from
flow rates and measuring the detector output.
0.1000 N HCl standard.)
4.1.4 Response time is measured by measuring the time 7.2.2 Prepare the following HCl calibration standards from
required for the detector output to change from that measured the 2.00-mM HCl standard stock solution. Use accurate Class
with DI water to that measured with 1 mM KCl. A pipettes and 100-mL plastic volumetric flasks.
E1511–93 (2005)
9.1.1 Set up the chromatographic system according to the
HCl Concentration, Volume in 100 mL DI Water,
mM mL
instructions in Section 8. Turn on the pump and ensure that the
pump is pumping smoothly.
0.02 1
0.04 2 9.1.2 Monitor the detector output. The conductivity should
0.1 5
be below 1µS/cm. If it is higher, continue flushing out the
0.2 10
system to remove leftover salts until the conductivity stabilizes
0.4 20
below 1 µS/cm. (A higher reading is an indication of either an
2 No dilution
incompletely cleaned flow system or of poor deionized water
quality and may compromise noise and linearity tests.) Fill the
8. Instrumentation Set-Up
sample injection loop with DI water and inject. Note the
8.1 Set up the chromatographic system according to the
minimum conductivity reported during the elution of the DI
manufacturer’s recommendation. Also, passivate the conduc-
water through the detector cell. Either calibrate the detector to
tivity cell using the manufacturer’s recommended procedure.
zero using the injected DI water or subtract the conductivity of
Set the flow rate on the pump to 1.0 mL/min or to the flow rate
injected DI water from all subsequent measurements.
normallyusedinyourapplication.Filltheeluentbottlewith18
9.1.3 Fill the sample injection loop with the 1-mM KCl
M-ohm DI water. Connect the outlet of the pump to the
standard and inject the standard. Note the maximum conduc-
injection valve, and the outlet of the injection valve directly to
tivity reported during the elution through the detector cell of
the conductivity cell using as short a length of tubing as is
the 1-mM KCl standard. It should be 147.0 µS/cm. If it is not,
practical. (Standard 0.25-mm (0.01-in.) internal diameter
follow the manufacturer’s procedure for calibrating the con-
HPLC tubing may be used.) Do not install any columns or
ductivity detector so that the reading will be 147.0 µS/cm.
suppressors. To ensure smooth operation of the pump, it is
9.1.4 Some conductivity detectors do not report conductiv-
necessary to supply more pressure than that normally provided
ity directly in siemens, but instead provide a voltage output
by the detector cell and the standard tubing alone. This is
proportional to conductivity. Instead of adjusting the detector
accomplished by installing a 1-m coil of 0.25-mm internal
output, calibrate these detectors by recording the known
diameter narrow bore tubing between the pump and the
conductivity of the calibration solution (147.0 µS/cm for 1 mM
injection valve. Increase the length or decrease the diameter of
KCl), the detector sensitivity range, and the measured voltage
the tubing if the pressure is not high enough to produce smooth
output. (Be sure to subtract the voltage output for a blank of DI
pump operation. Generally, 500 to 1 000 psi will be sufficient.
water.) Divide the known conductivity by the net voltage
The waste line connected to the cell outlet should be of
output reading and multiply all subsequent voltage output
sufficient length to provide enough backpressure on the cell to
readings by this value.
prevent the formation of bubbles inside the cell. Inserting 20
10. Noise and Drift
cm of 0.25-mm internal diameter tubing between the cell and
waste line should provide sufficient backpressure.
10.1 Method of Measurement—Noise and drift are mea-
8.2 Install a sample injection loop of approximately 200 µL
sured under two conditions. Pure DI water is pumped through
on the injection valve. This can be constructed from1mof
the conductivity cell at 1 mL/min and the noise and drift
0.5-mm (0.02-in.) internal diameter tubing. During the tests
measured. The procedure is then repeated using 1 mM KCl.
described in Sections 6 and 7, observe the recorder trace and
Thedetectoroutputmaybesensitivetotemperaturechanges.It
verify that a plateau is reached after injection of the standard
is worthwhile to perform this test twice: once with the
solutions. If no plateau is reached, then a larger sample
temperature of the eluents and of the laboratory held as
injection loop is needed.
constant as possible, and once with controlled changes in
8.3 If the conductivity detector has a setting for temperature
laboratory temperature of approximately 5°C. This may be
compensation, set it to 2.0. If not, the DI water eluent and all
accomplished by cycling on and off a room heater or air
ofthetestsolutionsshouldbethermostatedascloseaspossible
conditioner.
to 25°C. Or, the detector cell may be thermostated at a higher
10.1.1 Set up the chromatographic system as desc
...

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SIGNIFICANCE AND USE
4.1 By following the general guidelines (Section 5) and instrument calibration methods (Sections 6 – 16) in this guide, users should be able to more easily conform to good laboratory and manufacturing practices (GXP) and comply with regulatory and QA/QC requirements, related to fluorescence measurements.  
4.2 Each instrument parameter needing calibration (for example, wavelength, spectral responsivity) is treated in a separate section. A list of different calibration methods is given for each instrument parameter with a brief usage procedure. Precautions, achievable precision and accuracy, and other useful information are also given for each method to allow users to make a more informed decision as to which method is the best choice for their calibration needs. Additional details for each method can be found in the references given.
SCOPE
1.1 This guide (1)2 lists the available materials and methods for each type of calibration or correction for fluorescence instruments (spectral emission correction, wavelength accuracy, and so forth) with a general description, the level of quality, precision and accuracy attainable, limitations, and useful references given for each entry.  
1.2 The listed materials and methods are intended for the qualification of fluorometers as part of complying with regulatory and other quality assurance/quality control (QA/QC) requirements.  
1.3 Precision and accuracy or uncertainty are given at a 1 σ confidence level and are approximated in cases where these values have not been well established.3  
1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.5 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.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E2143-01(2021)(Test Method)
Standard Test Method for Using Field-Portable Fiber Optics Synchronous Fluorescence Spectrometer for Quantification of Field Samples for Aromatic and Polycyclic Aromatic Hydrocarbons

SIGNIFICANCE AND USE
5.1 This technique is designed for on-site rapid screening and characterization of environmental soil and water samples resulting in significant cost savings for environmental remediation projects. Remote analysis can be made with optical fibers when situations warrant or demand use of this option.  
5.2 Quantification of total AHs and PAHs in these environmental samples is accomplished by having a subset of the samples analyzed by an alternate technique and generating a site-specific calibration curve.  
5.3 Synchronous fluorescence provides sufficient spectral information to characterize the AHs and PAHs present as benzene, toluene, ethylbenzene and xylene(s) (BTEX), the aromatic portion of total petroleum hydrocarbons (TPH), or large aromatic ring systems up to at least seven fused rings, such as might be found in creosote.
SCOPE
1.1 This test method covers a rapid method for the screening of environmental samples for aromatic hydrocarbons (AHs) and polycyclic aromatic hydrocarbons (PAHs). The screening takes place in the field and provides immediate feedback on limits of contamination by substances containing AHs and PAHs. Quantification is obtained by the use of appropriately characterized, site-specific calibration curves. Remote sensing by use of optical fibers is useful for accessing difficult to reach areas or potentially dangerous materials or situations. When contamination of field personnel by dangerous materials is a possibility, use of remote sensors may minimize or eliminate the likelihood of such contamination taking place.  
1.2 This test method is applicable to AHs and PAHs present in samples extracted from soils or in water. This test method is applicable for field screening or, with an appropriate calibration, quantification of total AHs and PAHs.  
1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E1866-97(2021)(Guide)
Standard Guide for Establishing Spectrophotometer Performance Tests

SIGNIFICANCE AND USE
4.1 If ASTM Committee E13 has not specified an appropriate test procedure for a specific type of spectrophotometer, or if the sample specified by a Committee E13 procedure is incompatible with the intended spectrophotometer operation, then this guide can be used to develop practical performance tests.  
4.1.1 For spectrophotometers which are equipped with permanent or semi-permanent sampling accessories, the test sample specified in a Committee E13 practice may not be compatible with the spectrophotometer configuration. For example, for FT-MIR instruments equipped with transmittance or IRS flow cells, tests based on polystyrene films are impractical. In such cases, these guidelines suggest means by which the recommended test procedures can be modified so as to be performed on a compatible test material.  
4.1.2 For spectrophotometers used in process measurements, the choice of test materials may be limited due to process contamination and safety considerations. These guidelines suggest means of developing performance tests based on materials which are compatible with the intended use of the spectrophotometer.  
4.2 Tests developed using these guidelines are intended to allow the user to compare the performance of a spectrophotometer on any given day with prior performance. The tests are intended to uncover malfunctions or other changes in instrument operation, but they are not designed to diagnose or quantitatively assess the malfunction or change. The tests are not intended for the comparison of spectrophotometers of different manufacture.
SCOPE
1.1 This guide covers basic procedures that can be used to develop spectrophotometer performance tests. The guide is intended to be applicable to spectrophotometers operating in the ultraviolet, visible, near-infrared and mid-infrared regions.  
1.2 This guide is not intended as a replacement for specific practices such as Practices E275, E925, E932, E958, E1421, or E1683 that exist for measuring performance of specific types of spectrophotometers. Instead, this guide is intended to provide guidelines in how similar practices should be developed when specific practices do not exist for a particular spectrophotometer type, or when specific practices are not applicable due to sampling or safety concerns. This guide can be used to develop performance tests for on-line process spectrophotometers.  
1.3 This guide describes univariate level zero and level one tests, and multivariate level A and level B tests which can be implemented to measure spectrophotometer performance. These tests are designed to be used as rapid, routine checks of spectrophotometer performance. They are designed to uncover malfunctions or other changes in instrument operation, but do not specifically diagnose or quantitatively assess the malfunction or change. The tests are not intended for the comparison of spectrophotometers of different manufacture.  
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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