石灰石、粘土,地质、矿产标准物质/标准品

methods of analysis of limestone and related materials. SRM 1d is composed of argillaceous limestone quarried in
Putnam County, Indiana, USA. A unit of SRM 1d consists of a single bottle containing approximately 70 g of
material of which 97 % passes a 75 µm (No. 200) sieve.

The certified values for 12 constituents in SRM 1d are listed in Table 1. Reference values for four constituents and
loss on ignition (1000 °C) are listed in Table 2. Information values for 26 constituents and loss on ignition
(1200 °C) are listed in Table 3. All values are reported as mass fractions [1] on a dry basis. Value assignment
categories are based on the definition of terms and modes used at NIST for chemical reference materials [2], and
uncertainties are assessed according to the ISO and NIST Guides [3]. Analytical methods employed in the
development of this material are listed in Table 4.

Certified Values: A NIST certified value is a value for which NIST has the highest confidence in its accuracy, in
that all known or suspected sources of bias have been investigated or accounted for by NIST. A certified value is
the present best estimate of the true value based on the results of analyses performed at NIST and cooperating
laboratories. The uncertainty listed with the value is an expanded uncertainty (95 % confidence interval [4]) and is
calculated in conformance with the methods in the ISO and NIST Guides [3].

Reference Values: Reference values are non-certified values that are the present best estimates of the true values.
However, the values do not meet the NIST criteria for certification and are provided with associated uncertainties
that may not include all components of uncertainty. The uncertainty listed with the value is an expanded uncertainty
(95 % confidence interval [4]) and is calculated in conformance with the methods in the ISO and NIST Guides [3].

Information Values: An information value is considered to be a value that will be of interest and use to the SRM
user, but insufficient information is available to assess the uncertainty associated with the value.

Constituent Assignment: The constituents listed in this Certificate of Analysis are expressed as the chemical forms
given in ASTM C 25-99 [5]. Gravimetric factors used at NIST were calculated from the IUPAC recommended
atomic weights [6].

Expiration of Certification: The certification of this SRM is valid until 01 October 2024, within the uncertainty
specified, provided the SRM is handled and stored in accordance with the instructions given in this certificate (see
“Instructions for Use”). However, the certification will be nullified if the SRM is damaged or contaminated.

Stability: This material is considered to be stable during the period of certification when stored in its original
container in a cool, dry location. NIST will monitor this material and will report any significant changes in
certification to the purchaser. Registration (see attached sheet) will facilitate notification.

The overall direction and coordination of the technical measurements leading to the certification of this SRM were
performed by J.R. Sieber of the NIST Analytical Chemistry Division.

Stephen A. Wise, Chief
Analytical Chemistry Division

Gaithersburg, MD 20899Robert L. Watters, Jr., Chief
Certificate Issue Date: 18 February 2005Measurement Services Division

SRM 1d Page 1 of 4

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Analytical measurements for certification of this SRM were performed by J.R. Sieber and A.F. Marlow of the NIST
Analytical Chemistry Division.

Statistical consultation was provided by S.D. Leigh of the NIST Statistical Engineering Division.

The support aspects involved in the issuance of this SRM were coordinated through the NIST Standard Reference
Materials Program by B.S. MacDonald of the NIST Measurement Services Division.

Material Preparation: The material for SRM 1d was obtained from Lone Star Industries, Inc.1, Indianapolis,

Indiana. The raw material was collected under the direction of W.D. Robinson, Lone Star Concrete, Greencastle,
IN. Preparation of the SRM and contributing chemical analyses were performed by the U.S. Geological Survey
(USGS) under the direction of S.A. Wilson. Homogeneity assessment was done by NIST using measurements
performed at USGS.

INSTRUCTIONS FOR USE

To relate analytical determinations to the values on this Certificate of Analysis, a minimum sample quantity of
200 mg should be used. It is recommended to mix the contents of the bottle prior to sampling by turning the bottle
end over end for two minutes. The sample should be dried according to the “Instructions for Drying”. If particle
size reduction is performed, it is the user’s responsibility to prevent contamination or loss of material.

Instructions for Drying: The material must be dried at 105 °C to 110 °C in air for 2 h prior to analysis. Typical
mass loss on drying is approximately 0.2 %.

Table 1. Certified Values for SRM 1d Limestone, Argillaceous

Constituent Mass Fraction Expanded Uncertainty
(%) (%)

Na2O 0.0109 0.0016a
MgO 0.301 0.010a
Al2O3 0.526 0.013a
SiO a
2 4.080 0.071
P2O5 0.0413 0.0025a
S 0.1028 0.0062a
K2O 0.1358 0.0046a

a
CaO 52.85 0.16
Mn 0.0209 0.0005a
Fe2O3 0.3191 0.0068a
ZnO 0.0022 0.0003b
SrO 0.0303 0.0010a

a The assigned value is a weighted mean of the results from two to seven analytical methods. The uncertainty listed with each

value is an expanded uncertainty about the mean, with a coverage factor 2 (approximately 95 % confidence), calculated by
combining a between-source variance incorporating inter-method bias with a pooled within-source variance following the ISO
and NIST Guides [3,7].
b The assigned value is an unweighted mean of the results from two to five analytical methods. The uncertainty listed with the

value is an expanded uncertainty about the mean, with coverage factor 2, calculated by combining a between-method variance
with a pooled, within-method variance following the ISO and NIST Guides [3,8].

_______________________

1 Certain commercial equipment, instruments, or materials are identified in this report to adequately specify the experimental

procedure. Such identification does not imply recommendation or endorsement by the NIST, nor does it imply that the materials
or equipment identified are necessarily the best available for the purpose.

SRM 1d Page 2 of 4

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Table 2. Reference Values for SRM 1d Limestone, Argillaceous

Constituent Mass Fraction Expanded Uncertainty

(%) (%)
C 11.50 0.25b
TiO2 0.0306 0.0065b
Cr2O3 0.0012 0.0002b

b
BaO 0.0033 0.0011
Loss on Ignition (1000 °C) 41.57 0.06a

a The assigned value is a weighted mean of the results from two to seven analytical methods. The uncertainty listed with each

Table 3. Information Values for SRM 1d Limestone, Argillaceous

Constituent Mass Fraction Constituent Mass Fraction
(mg/kg) (mg/kg)

Be 0.1 Nb 0.7
Cd 0.3 Nd 3
Ce 4 Ni 4
Cl 130 Pr 0.6
Cs 0.4 Rb 6
Dy 0.6 Sm 0.5
Er 0.4 Sn 1
Eu 0.1 Tb 0.09
F 160 Th 0.5
Ga 1 U 1
Gd 0.5 V 10
Ho 0.1 Y 5
La 4 Yb 0.3
Loss on Ignition (1200 °C)c 41.6 % Dry Brightness (Y)d 80.03

c Note: Loss on Ignition [5] has units of %, not mg/kg.
d Dry Brightness (Y) [9] is reported as a unit-less quantity.

Table 4. Analytical Methods Used in Elemental Determinations

Method Constituents Determined

Wavelength Dispersive X-Ray Fluorescence SpectrometryNa, Mg, Al, Si, P, S, K, Ca, Ti, Mn, Fe, Zn, Sr
(WDXRF) at NIST [10,11]
Wavelength Dispersive X-Ray Fluorescence SpectrometryNa, Mg, Al, Si, P, S, K, Ca, Ti, Cr, Mn, Fe, Zn,
(WDXRF) at Cooperating LaboratoriesSr, Ba
Inductively-Coupled Plasma Optical Emission SpectrometryBe, Na, Mg, Al, Si, P, K, Ca, Ti, V, Cr, Mn, Fe,
(ICP-OES) at Cooperating LaboratoriesNi, Zn, Sr, Sn, Ba
Inductively-Coupled Plasma Mass Spectrometry (ICP-MS)Be, V, Ni, Ga, Rb, Y, Nb, Cd, Sn, Cs, Ba, La, Ce,
at Cooperating Laboratories Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Yb, Th, U
Flame Atomic Absorption Spectrophotometry (FAAS)Na, K
at Cooperating Laboratories
Combustion with Infrared Detection at CooperatingC, S
Laboratories
Potentiometric Titration at Cooperating LaboratoriesF, Cl

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Cooperating Laboratories: Analytical determinations for certification of SRM 1d were performed by the
following laboratories:

Acme Analytical, Laboratories Ltd.; Vancouver, British Columbia, Canada; R. McCaffrey, W. Szeto
Carmeuse Lime, Inc.; Annville, PA; J. Morrow
Carmeuse Technology Center; Pittsburgh, PA; M. Houghton
Construction Technology Laboratories, Inc.; Skokie, IL; D. Broton, M. Bharucha
Newmont Mining Corp.; Englewood, CO; C. Bucknam
Specialty Minerals, Inc.; Easton, PA; R. Kroc, G. Hevner, T. Rissmiller, G. Tomaino
United States Geological Survey; Denver, CO; S. Wilson, J. Taggart, Z. Brown, A. Meier, M. Adams, P. Briggs

REFERENCES

[1] Taylor, B.N.; Guidefor the Use of the International System of Units (SI) ; NIST Special Publication 811; U.S.
Government Printing Office: Washington, DC (1995).
[2] May, W.E.; Parris, R.M.; Beck II, C.M.; Fassett, J.D.; Greenberg, R.R.; Guenther, F.R.; Kramer, G.W.;
Wise, S.A.; Gills, T.E.; Colbert, J.C.; Gettings, R.J.; MacDonald, B.S.; Definitions of Terms and Modes Used
at NIST for Value-Assignment of Reference Materials for Chemical Measurements; NIST Special Publication
260-136, U.S. Government Printing Office: Washington, DC, p. 16 (2000).
[3] ISO; Guide to the Expression of Uncertainty in Measurement; ISBN 92-67-10188-9, 1st ed.; International
Organization for Standardization: Geneva, Switzerland (1993); see also Taylor, B.N.; Kuyatt, C.E.; Guidelines
for Evaluating and Expressing the Uncertainty of NIST Measurement Results ; NIST Technical Note 1297;
U.S. Government Printing Office: Washington, DC (1994); available at http://physics.nist.gov/Pubs/.
[4] Hahn, G.J., and Meeker, W.Q.; Statistical Intervals: A Guide for Practitioners; John Wiley & Sons, Inc.: New
York, NY(1991).
[5] ASTM C 25-99; Standard Test Methods for Chemical Analysis of Limestone, Quicklime, and Hydrated Lime;
Annu. Book ASTM Stand., Vol. 04.01 (2003).
[6] Vocke, R.D; Atomic Weights of the Elements 1997; Pure Appl. Chem., Vol. 71(8), pp. 1593-1607 (1999).
[7] Ruhkin, A.L.; Vangel, M.G.; Estimation of a Common Mean and Weighted Mean Statistics; J. Am. Statist.
Assoc., Vol. 93, pp. 303-308 (1998).
[8] Levenson, M.S.; Banks, D.L.; Eberhardt, K.R.; Gill, L.M.; Guthrie, W.F.; Liu, H.K.; Vangel, M.G.; Yen, J.H.;
Zang, N.F.; An Approach to Combining Results from Multiple Methods Motivated by the ISO GUM; J. Res.
Natl. Inst. Stand. Technol., Vol. 105, pp. 571-579 (2000).
[9] ASTM C 110-02a; Standard Test Methods for Chemical Analysis of Limestone, Quicklime, and Hydrated
Lime; Annu. Book ASTM Stand., Vol. 04.01 (2003).
[10] Sieber, J.R.; Matrix-Independent XRF Methods for Certification of Standard Reference Materials; Adv. X-Ray
Anal., Vol. 45, pp. 493-504 (2002).
[11] Sieber, J.R.; Broton, D.; Fales, C.; Leigh, S.; MacDonald, B.; Marlow, A.; Nettles, S.; Yen, J.; Standard
Reference Materials for Cements; Cem. Concr. Res., Vol. 32, pp. 1899-1906 (2002).

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