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HIPB-1: High Purity Lead Certified Reference Material for Lead Mass Fraction, Atomic Weight, Isotopic Composition, and Elemental Impurities

From National Research Council Canada

Alternative titleHIPB-1 : Matériau de référence certifié de plomb de pureté élevée pour la fraction massique du plomb, masse atomique, la composition isotopique et les impuretés élémentaires
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DOIResolve DOI: https://doi.org/10.4224/crm.2020.hipb-1
AuthorSearch for: 1ORCID identifier: https://orcid.org/0000-0002-3349-5535; Search for: 1; Search for: 2; Search for: 1; Search for: 1; Search for: 1ORCID identifier: https://orcid.org/0000-0002-1167-6474; Search for: 1ORCID identifier: https://orcid.org/0000-0002-2377-2615; Search for: 1ORCID identifier: https://orcid.org/0000-0002-6896-8603
Affiliation
  1. National Research Council Canada
  2. State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan, PR China
Format3D, Material
Material typeHigh-purity material
SubjectCanadian reference material; HIPB-1; lead; isotopes of lead; atomic weight
Abstract
HIPB-1 is a high purity lead Certified Reference Material (CRM). A unit of HIPB-1 consists of approx. 1 g of high purity lead wire. This material is intended as a primary standard for the determination of mass fraction of lead and as an isotopic standard of lead.
Analytes
View analytes
AnalyteQuantityValueExpanded uncertaintyUnitType
leadmass fraction0.9999900.000002kg/kgcertified
leadatomic weight207.17910.00021certified
lead-204isotopic abundance0.0128220.000012mol/molcertified
lead-206isotopic abundance0.270960.00008mol/molcertified
lead-207isotopic abundance0.2035110.000026mol/molcertified
lead-208isotopic abundance0.512710.00010mol/molcertified
206Pb/204Pbisotope ratio21.1330.014mol/molcertified
207Pb/204Pbisotope ratio15.8730.014mol/molcertified
208Pb/204Pbisotope ratio39.990.04mol/molcertified
204Pb/206Pbisotope ratio0.0473190.000030mol/molcertified
207Pb/206Pbisotope ratio0.751070.00022mol/molcertified
208Pb/206Pbisotope ratio1.89220.0010mol/molcertified
204Pb/207Pbisotope ratio0.063000.00006mol/molcertified
206Pb/207Pbisotope ratio1.33140.0004mol/molcertified
208Pb/207Pbisotope ratio2.51930.0008mol/molcertified
204Pb/208Pbisotope ratio0.0250100.000026mol/molcertified
206Pb/208Pbisotope ratio0.528490.00028mol/molcertified
207Pb/208Pbisotope ratio0.396940.00012mol/molcertified
lithiummass fraction<0.060.07µg/kgcertified
berylliummass fraction<0.040.02µg/kgcertified
boronmass fraction<0.10.2µg/kgcertified
carbonmass fraction25300µg/kgcertified
nitrogenmass fraction330µg/kgcertified
oxygenmass fraction53500µg/kgcertified
fluorinemass fraction<0.61.5µg/kgcertified
sodiummass fraction12100µg/kgcertified
magnesiummass fraction<0.11.5µg/kgcertified
aluminiummass fraction125µg/kgcertified
siliconmass fraction0.42.1µg/kgcertified
phosphorusmass fraction<0.090.24µg/kgcertified
sulfurmass fraction55µg/kgcertified
chlorinemass fraction33170µg/kgcertified
potassiummass fraction<67µg/kgcertified
calciummass fraction<225µg/kgcertified
scandiummass fraction<0.050.04µg/kgcertified
titaniummass fraction<0.050.41µg/kgcertified
vanadiummass fraction<0.040.16µg/kgcertified
chromiummass fraction<0.070.04µg/kgcertified
manganesemass fraction<0.070.04µg/kgcertified
ironmass fraction0.41µg/kgcertified
cobaltmass fraction<0.050.03µg/kgcertified
nickelmass fraction326µg/kgcertified
coppermass fraction17090µg/kgcertified
zincmass fraction74µg/kgcertified
galliummass fraction<0.30.2µg/kgcertified
germaniummass fraction<0.60.6µg/kgcertified
arsenicmass fraction0.50.3µg/kgcertified
seleniummass fraction<21µg/kgcertified
brominemass fraction<0.82µg/kgcertified
rubidiummass fraction<0.10.1µg/kgcertified
strontiummass fraction<0.040.03µg/kgcertified
yttriummass fraction<0.040.06µg/kgcertified
zirconiummass fraction<0.060.03µg/kgcertified
niobiummass fraction<0.030.02µg/kgcertified
molybdenummass fraction<0.30.2µg/kgcertified
rutheniummass fraction<0.50.7µg/kgcertified
rhodiummass fraction<3250µg/kgcertified
palladiummass fraction125µg/kgcertified
silvermass fraction53301600µg/kgcertified
cadmiummass fraction2070600µg/kgcertified
indiummass fraction0.71.5µg/kgcertified
tinmass fraction63µg/kgcertified
antimonymass fraction0.50.4µg/kgcertified
telluriummass fraction<0.30.2µg/kgcertified
iodinemass fraction<0.070.18µg/kgcertified
caesiummass fraction<0.090.13µg/kgcertified
bariummass fraction<0.10.1µg/kgcertified
lanthanummass fraction<0.030.02µg/kgcertified
ceriummass fraction<0.020.01µg/kgcertified
praseodymiummass fraction<0.10.3µg/kgcertified
neodymiummass fraction<0.080.4µg/kgcertified
samariummass fraction<0.61.5µg/kgcertified
europiummass fraction<0.30.8µg/kgcertified
gadoliniummass fraction<0.51.3µg/kgcertified
terbiummass fraction<0.10.3µg/kgcertified
dysprosiummass fraction<923µg/kgcertified
holmiummass fraction<0.10.3µg/kgcertified
erbiummass fraction<0.41µg/kgcertified
thuliummass fraction<0.10.3µg/kgcertified
ytterbiummass fraction<0.41µg/kgcertified
lutetiummass fraction<0.10.3µg/kgcertified
hafniummass fraction<0.10.1µg/kgcertified
tantalummass fraction<240400µg/kgcertified
tungstenmass fraction<0.20.1µg/kgcertified
rheniummass fraction<0.20.3µg/kgcertified
osmiummass fraction<0.71µg/kgcertified
iridiummass fraction13µg/kgcertified
platinummass fraction134µg/kgcertified
goldmass fraction<3230µg/kgcertified
mercurymass fraction<1411µg/kgcertified
thalliummass fraction580120µg/kgcertified
bismuthmass fraction1200360µg/kgcertified
thoriummass fraction<0.064µg/kgcertified
uraniummass fraction<0.060.09µg/kgcertified
Publication date
PublisherNational Research Council Canada
Copyright statement
  • © 2020 National Research Council Canada
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References
View items (9)
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  2. Meija, Juris, and Zoltán Mester. ‘Uncertainty Propagation of Atomic Weight Measurement Results’. Metrologia 45, no. 1 (8 January 2008): 53–62. .
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  4. Wang, Meng, G. Audi, F. G. Kondev, W.J. Huang, S. Naimi, and Xing Xu. ‘The AME2016 Atomic Mass Evaluation (II). Tables, Graphs and References’. Chinese Physics C 41, no. 3 (March 2017): 030003. .
  5. Tong, Shuoyun, Juris Meija, Lian Zhou, Brad Methven, Zoltán Mester, and Lu Yang. ‘High-Precision Measurements of the Isotopic Composition of Common Lead Using MC-ICPMS: Comparison of Calibration Strategies Based on Full Gravimetric Isotope Mixture and Regression Models’. Analytical Chemistry 91, no. 6 (7 March 2019): 4164–71. .
  6. Yang, Lu, Shuoyun Tong, Lian Zhou, Zhaochu Hu, Zoltán Mester, and Juris Meija. ‘A Critical Review on Isotopic Fractionation Correction Methods for Accurate Isotope Amount Ratio Measurements by MC-ICP-MS’. Journal of Analytical Atomic Spectrometry 33, no. 11 (2018): 1849–61. .
  7. Sturgeon, R E, B Methven, S N Willie, and P Grinberg. ‘Assignment of Purity to Primary Metal Calibrants Using Pin-Cell VG 9000 Glow Discharge Mass Spectrometry: A Primary Method with Direct Traceability to the SI International System of Units?’ Metrologia 51, no. 5 (25 June 2014): 410–22. .
  8. Dunstan, L.P., J.W. Gramlich, I.L. Barnes, and W.C. Purdy. ‘Absolute Isotopic Abundance and the Atomic Weight of a Reference Sample of Thallium’. Journal of Research of the National Bureau of Standards 85, no. 1 (January 1980): 1. .
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Referenced by
View items (10)
  1. He, Juan, Juris Meija, Xiandeng Hou, Chengbin Zheng, Zoltán Mester, and Lu Yang. ‘Determination of the Isotopic Composition of Lutetium Using MC-ICPMS’. Analytical and Bioanalytical Chemistry 412, no. 24 (16 December 2019): 6257–63. https://doi.org/10.1007/s00216-019-02271-6.
  2. Huang, Zili, Chaoqun Wang, Rui Liu, Yingying Su, and Yi Lv. ‘Self-Validated Homogeneous Immunoassay by Single Nanoparticle in-Depth Scrutinization’. Analytical Chemistry 92, no. 3 (8 January 2020): 2876–81. https://doi.org/10.1021/acs.analchem.9b05596.
  3. Xu, Shifen, Linghong Zhan, Chengyi Hong, Xiaomei Chen, Xi Chen, and Munetaka Oyama. ‘Metal–Organic Framework-5 as a Novel Phosphorescent Probe for the Highly Selective and Sensitive Detection of Pb(II) in Mussels’. Sensors and Actuators B: Chemical 308 (April 2020): 127733. https://doi.org/10.1016/j.snb.2020.127733.
  4. Li, Ziyan, Hongmei Li, Dongyan Deng, Rui Liu, and Yi Lv. ‘Mass Spectrometric Assay of Alpha-Fetoprotein Isoforms for Accurate Serological Evaluation’. Analytical Chemistry 92, no. 7 (7 February 2020): 4807–13. https://doi.org/10.1021/acs.analchem.9b03995.
  5. He, Juan, Lu Yang, Xiandeng Hou, Zoltan Mester, and Juris Meija. ‘Determination of the Isotopic Composition of Gadolinium Using Multicollector Inductively Coupled Plasma Mass Spectrometry’. Analytical Chemistry 92, no. 8 (8 April 2020): 6103–10. https://doi.org/10.1021/acs.analchem.0c00531.
  6. Flierl, Lukas, Axel Pramann, Janine Noordmann, Anita Röthke, and Olaf Rienitz. ‘UncorK – A Monte Carlo Simulation Tool for Calculating Combined Uncertainties Associated with Mass Bias Calibration Factors for Isotope Ratio Measurements’. Spectrochimica Acta Part B: Atomic Spectroscopy 168 (June 2020): 105866. https://doi.org/10.1016/j.sab.2020.105866.
  7. Lin, Ran, Jie Lin, Keqing Zong, Kang Chen, Shuoyun Tong, Lanping Feng, Wen Zhang, et al. ‘Determination of the Isotopic Composition of an Enriched Hafnium Spike by MC‐ICP‐MS Using a Regression Model’. Geostandards and Geoanalytical Research 44, no. 4 (29 July 2020): 753–62. https://doi.org/10.1111/ggr.12343.
  8. Kanan, Sofian M., and Ahmed Malkawi. ‘Recent Advances in Nanocomposite Luminescent Metal-Organic Framework Sensors for Detecting Metal Ions’. Comments on Inorganic Chemistry 41, no. 1 (4 September 2020): 1–66. https://doi.org/10.1080/02603594.2020.1805319.
  9. Zhu, Xiang-Kun, Jacqueline Benefield, Tyler B. Coplen, Zhaofu Gao, and Norman E. Holden. ‘Variation of Lead Isotopic Composition and Atomic Weight in Terrestrial Materials (IUPAC Technical Report)’. Pure and Applied Chemistry 93, no. 1 (1 October 2020): 155–66. https://doi.org/10.1515/pac-2018-0916.
  10. Karasiński, Jakub, Andriy Tupys, Lu Yang, Zoltan Mester, Ludwik Halicz, and Ewa Bulska. ‘Novel Approach for the Accurate Determination of Se Isotope Ratio by Multicollector ICP-MS’. Analytical Chemistry 92, no. 24 (23 November 2020): 16097–104. https://doi.org/10.1021/acs.analchem.0c03768.
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CollectionCanadian Reference Materials and Methods
Record identifier6547228a-b07c-4d9a-8a70-9d1b9acb5f7e
Record created2020-12-12
Record modified2025-11-20
Date modified: