Development and application of reference and routine analytical methods providing SI-traceable results for the determination of technology-critical elements in PCB from WEEE
The recovery and reprocessing of technology-critical elements (TCE) present in printed circuit boards (PCB) from electrical and electronic waste is essential both for recycling valuable materials subject to supply risk and for reducing the environmental impact. Although the quantitative knowledge of...
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| Published in | Journal of analytical atomic spectrometry Vol. 39; no. 11; pp. 289 - 2823 |
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| Main Authors | , , , , , , , , , , , , , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
London
Royal Society of Chemistry
30.10.2024
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| Subjects | |
| Online Access | Get full text |
| ISSN | 0267-9477 1364-5544 |
| DOI | 10.1039/d4ja00235k |
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| Abstract | The recovery and reprocessing of technology-critical elements (TCE) present in printed circuit boards (PCB) from electrical and electronic waste is essential both for recycling valuable materials subject to supply risk and for reducing the environmental impact. Although the quantitative knowledge of TCE amounts in end-of-life PCB plays a key role, there are neither matrix certified reference materials nor harmonized analytical methods available to establish the traceability of the results to the International System of Units. To fill these gaps, we developed and applied five reference analytical methods based on ICP-MS standard addition calibrations and INAA
k
0
- and relative calibrations suitable to certify reference materials. In addition, we developed and tested six analytical methods based on more commonly used ICP-MS external standard calibrations to provide industry with routine analysis methods. Twenty TCE (Ag, Au, Co, Cu, Dy, Ga, Gd, Ge, In, La, Li, Nd, Ni, Pd, Pr, Pt, Rh, Sm, Ta and Ti) were selected as target analytes and a batch of powdered PCB was used as measurement material. An overall mutual agreement was observed among data collected by reference methods at a few percent relative uncertainty levels. Moreover, all but one of the methods developed for routine analysis demonstrated their suitability in industrial applications by producing data within ± 20% of the values established with reference methods.
Development and test of five reference analytical methods and six routine analytical methods providing SI-traceable results of twenty technology-critical elements in end-of-life PCB materials. |
|---|---|
| AbstractList | The recovery and reprocessing of technology-critical elements (TCE) present in printed circuit boards (PCB) from electrical and electronic waste is essential both for recycling valuable materials subject to supply risk and for reducing the environmental impact. Although the quantitative knowledge of TCE amounts in end-of-life PCB plays a key role, there are neither matrix certified reference materials nor harmonized analytical methods available to establish the traceability of the results to the International System of Units. To fill these gaps, we developed and applied five reference analytical methods based on ICP-MS standard addition calibrations and INAA k0- and relative calibrations suitable to certify reference materials. In addition, we developed and tested six analytical methods based on more commonly used ICP-MS external standard calibrations to provide industry with routine analysis methods. Twenty TCE (Ag, Au, Co, Cu, Dy, Ga, Gd, Ge, In, La, Li, Nd, Ni, Pd, Pr, Pt, Rh, Sm, Ta and Ti) were selected as target analytes and a batch of powdered PCB was used as measurement material. An overall mutual agreement was observed among data collected by reference methods at a few percent relative uncertainty levels. Moreover, all but one of the methods developed for routine analysis demonstrated their suitability in industrial applications by producing data within ± 20% of the values established with reference methods. The recovery and reprocessing of technology-critical elements (TCE) present in printed circuit boards (PCB) from electrical and electronic waste is essential both for recycling valuable materials subject to supply risk and for reducing the environmental impact. Although the quantitative knowledge of TCE amounts in end-of-life PCB plays a key role, there are neither matrix certified reference materials nor harmonized analytical methods available to establish the traceability of the results to the International System of Units. To fill these gaps, we developed and applied five reference analytical methods based on ICP-MS standard addition calibrations and INAA k 0 - and relative calibrations suitable to certify reference materials. In addition, we developed and tested six analytical methods based on more commonly used ICP-MS external standard calibrations to provide industry with routine analysis methods. Twenty TCE (Ag, Au, Co, Cu, Dy, Ga, Gd, Ge, In, La, Li, Nd, Ni, Pd, Pr, Pt, Rh, Sm, Ta and Ti) were selected as target analytes and a batch of powdered PCB was used as measurement material. An overall mutual agreement was observed among data collected by reference methods at a few percent relative uncertainty levels. Moreover, all but one of the methods developed for routine analysis demonstrated their suitability in industrial applications by producing data within ± 20% of the values established with reference methods. Development and test of five reference analytical methods and six routine analytical methods providing SI-traceable results of twenty technology-critical elements in end-of-life PCB materials. The recovery and reprocessing of technology-critical elements (TCE) present in printed circuit boards (PCB) from electrical and electronic waste is essential both for recycling valuable materials subject to supply risk and for reducing the environmental impact. Although the quantitative knowledge of TCE amounts in endof-life PCB plays a key role, there are neither matrix certified reference materials nor harmonized analytical methods available to establish the traceability of the results to the International System of Units. To fill these gaps, we developed and applied five reference analytical methods based on ICP-MS standard addition calibrations and INAA k 0 -and relative calibrations suitable to certify reference materials. In addition, we developed and tested six analytical methods based on more commonly used ICP-MS external standard calibrations to provide industry with routine analysis methods. Twenty TCE (Ag, Au, Co, Cu, Dy, Ga, Gd, Ge, In, La, Li, Nd, Ni, Pd, Pr, Pt, Rh, Sm, Ta and Ti) were selected as target analytes and a batch of powdered PCB was used as measurement material. An overall mutual agreement was observed among data collected by reference methods at a few percent relative uncertainty levels. Moreover, all but one of the methods developed for routine analysis demonstrated their suitability in industrial applications by producing data within ± 20% of the values established with reference methods. The recovery and reprocessing of technology-critical elements (TCE) present in printed circuit boards (PCB) from electrical and electronic waste is essential both for recycling valuable materials subject to supply risk and for reducing the environmental impact. Although the quantitative knowledge of TCE amounts in end-of-life PCB plays a key role, there are neither matrix certified reference materials nor harmonized analytical methods available to establish the traceability of the results to the International System of Units. To fill these gaps, we developed and applied five reference analytical methods based on ICP-MS standard addition calibrations and INAA k 0 - and relative calibrations suitable to certify reference materials. In addition, we developed and tested six analytical methods based on more commonly used ICP-MS external standard calibrations to provide industry with routine analysis methods. Twenty TCE (Ag, Au, Co, Cu, Dy, Ga, Gd, Ge, In, La, Li, Nd, Ni, Pd, Pr, Pt, Rh, Sm, Ta and Ti) were selected as target analytes and a batch of powdered PCB was used as measurement material. An overall mutual agreement was observed among data collected by reference methods at a few percent relative uncertainty levels. Moreover, all but one of the methods developed for routine analysis demonstrated their suitability in industrial applications by producing data within ± 20% of the values established with reference methods. |
| Author | Walch, Anna Irrgeher, Johanna Rienitz, Olaf Ghestem, Jean-Philippe Lafaurie, Nicolas Ja imovi, Radojko Röthke, Anita Vogl, Jochen Pramann, Axel Sara-Aho, Timo Kutan, Derya Michaliszyn, Lena Klein, Ole Cankur, Oktay Oelze, Marcus Oster, Caroline Di Luzio, Marco Noireaux, Johanna D'Agostino, Giancarlo Lancaster, Shaun T Pröfrock, Daniel Bergamaschi, Luigi |
| AuthorAffiliation | Department Environment and Climate change Division Chemistry-Biology Finnish Environment Institute (Syke) National Metrology Institute of Turkey (TUBITAK) Gebze Technical University Bundesanstalt für Materialforschung und -prüfung (BAM) University of Pavia Unit of Radiochemistry and Spectroscopy c/o Department of Chemistry Department of Physics Department of Environmental Sciences Laboratoire Nationale des Essais et de la métrologie (LNE) Chair of General and Analytical Chemistry Bureau de Recherches Géologiques et Minières (BRGM) Inorganic Chemistry Laboratory Water, Environment, Processes and Analysis Department Istituto Nazionale di Ricerca Metrologica (INRIM) Metrology Helmholtz-Zentrum Hereon (Hereon) Montanuniversität Leoben (MUL) Inorganic Trace Analysis Physikalisch-Technische Bundesanstalt (PTB) Jo ef Stefan Institute (JSI) Research Infrastructure |
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| Author_xml | – sequence: 1 givenname: Giancarlo surname: D'Agostino fullname: D'Agostino, Giancarlo – sequence: 2 givenname: Marcus surname: Oelze fullname: Oelze, Marcus – sequence: 3 givenname: Jochen surname: Vogl fullname: Vogl, Jochen – sequence: 4 givenname: Jean-Philippe surname: Ghestem fullname: Ghestem, Jean-Philippe – sequence: 5 givenname: Nicolas surname: Lafaurie fullname: Lafaurie, Nicolas – sequence: 6 givenname: Ole surname: Klein fullname: Klein, Ole – sequence: 7 givenname: Daniel surname: Pröfrock fullname: Pröfrock, Daniel – sequence: 8 givenname: Marco surname: Di Luzio fullname: Di Luzio, Marco – sequence: 9 givenname: Luigi surname: Bergamaschi fullname: Bergamaschi, Luigi – sequence: 10 givenname: Radojko surname: Ja imovi fullname: Ja imovi, Radojko – sequence: 11 givenname: Caroline surname: Oster fullname: Oster, Caroline – sequence: 12 givenname: Johanna surname: Irrgeher fullname: Irrgeher, Johanna – sequence: 13 givenname: Shaun T surname: Lancaster fullname: Lancaster, Shaun T – sequence: 14 givenname: Anna surname: Walch fullname: Walch, Anna – sequence: 15 givenname: Anita surname: Röthke fullname: Röthke, Anita – sequence: 16 givenname: Lena surname: Michaliszyn fullname: Michaliszyn, Lena – sequence: 17 givenname: Axel surname: Pramann fullname: Pramann, Axel – sequence: 18 givenname: Olaf surname: Rienitz fullname: Rienitz, Olaf – sequence: 19 givenname: Timo surname: Sara-Aho fullname: Sara-Aho, Timo – sequence: 20 givenname: Oktay surname: Cankur fullname: Cankur, Oktay – sequence: 21 givenname: Derya surname: Kutan fullname: Kutan, Derya – sequence: 22 givenname: Johanna surname: Noireaux fullname: Noireaux, Johanna |
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| Cites_doi | 10.1016/j.wasman.2019.04.041 10.1039/c9ja00283a 10.1111/ggr.12327 10.1016/j.wasman.2020.08.054 10.1007/s10967-017-5191-4 10.1007/s10967-022-08622-5 10.1007/s00769-011-0827-5 10.1351/pac200375060683 10.3390/resources6040064 10.1016/j.sab.2010.12.011 10.1039/c9ja00284g 10.1007/s00244-021-00892-6 10.1039/D0AY01049A 10.1039/c8ay01192c 10.1007/s00216-012-6377-9 10.1007/s00216-022-04497-3 10.1039/an9941902161 10.1023/a:1010601403010 10.1039/D3JA00025G 10.1366/12-06681 10.1051/epjap/2019190284 |
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| References | Kragten (D4JA00235K/cit16/1) 1994; 119 Baldé (D4JA00235K/cit1/1) 2024 De Corte (D4JA00235K/cit9/1) 2001; 248 EURACHEM/CITAC (D4JA00235K/cit17/1) 2012 Vogl (D4JA00235K/cit26/1) 2020; 44 Rienitz (D4JA00235K/cit8/1) 2012; 404 Di Luzio (D4JA00235K/cit23/1) 2023; 332 Bookhagen (D4JA00235K/cit4/1) 2018; 10 Profrock (D4JA00235K/cit14/1) 2012; 66 de Laeter (D4JA00235K/cit15/1) 2003; 75 Das (D4JA00235K/cit3/1) 2017; 6 Di Luzio (D4JA00235K/cit21/1) 2017; 312 Hauswaldt (D4JA00235K/cit7/1) 2012; 17 Dang (D4JA00235K/cit2/1) 2021; 81 Zimmermann (D4JA00235K/cit13/1) 2020; 12 HyperLab (D4JA00235K/cit22/1) 2014 Andrade (D4JA00235K/cit6/1) 2019; 34 Touze (D4JA00235K/cit12/1) 2020; 118 Andrade (D4JA00235K/cit5/1) 2019; 34 Trimmel (D4JA00235K/cit19/1) 2023; 415 BIPM, IEC, IFCC, ILAC, ISO, IUPAC, IUPAP, and OIML (D4JA00235K/cit20/1) 2024 Hubau (D4JA00235K/cit11/1) 2019; 91 Greenberg (D4JA00235K/cit10/1) 2011; 66 Lancaster (D4JA00235K/cit18/1) 2023; 38 Pramann (D4JA00235K/cit25/1) 2019; 88 |
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| SubjectTerms | Calibration Circuit boards Copper Data analysis Earth Sciences End of life Gadolinium Gold Industrial applications Industrial development International System of Units Materials traceability Palladium Printed circuits Reference materials Reprocessing Sciences of the Universe Tantalum Technology assessment Uncertainty analysis |
| Title | Development and application of reference and routine analytical methods providing SI-traceable results for the determination of technology-critical elements in PCB from WEEE |
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