Evaluating the effect of hydrofluoric acid etching on quartz grains using microscope image analysis, laser diffraction and weight loss particle size estimate

Poręba, Grzegorz; Tudyka, Konrad; Szymak, Agnieszka; Pluta, Julia; Rocznik, Joanna; Świątkowski, Jakub; Osadnik, Rafał; Moska, Piotr

doi:10.2478/geochr-2022-0001

Artykuł - szczegóły

Tytuł artykułu

Evaluating the effect of hydrofluoric acid etching on quartz grains using microscope image analysis, laser diffraction and weight loss particle size estimate

Autorzy

Poręba Grzegorz , Tudyka Konrad , Szymak Agnieszka , Pluta Julia , Rocznik Joanna , Świątkowski Jakub , Osadnik Rafał , Moska Piotr

Wybrane pełne teksty z tego czasopisma

Identyfikatory

DOI

10.2478/geochr-2022-0001

Warianty tytułu

Języki publikacji

Abstrakty

In this work we investigate the quartz etching process using hydrofluoric acid for trapped charge dating (TCD) applications. It is done using material collected from an active sand mine in Bełchatów Nowy Świat, central Poland. Approximately 20 kg of material was collected and prepared using routine procedures that are applied in TCD laboratories. The material was sieved using 180–200 μm meshes, and the selected fraction was etched for various time intervals. Sieved samples were etched for durations from 0 min up to 180 min and measured with microscope image analysis (IA), laser diffraction (LD), and mass loss which were used to estimate the depths of etching. Our results show statistical data on how non-uniform the etching process is. We estimate this as a function of etching time from IA, LD and mass loss. In our investigation, mass loss measurements with the assumption of spherical grains correspond to the decrease of radius of ca. 0.151 ± 0.003 μm ˑ min–1. In case of LD, a rough etch depth estimation corresponds to a range 0.06–0.18 μm ˑ min–1 with median at 0.13 μm ˑ min–1. Microscope IA gives a 0.03–0.09 μm ˑ min–1 with a median at 0.05 μm ˑ min–1. Moreover, quartz grains are fractured into smaller pieces while etching. It means that assumptions that are used in etch depth estimation from mass loss are not correct. They incorrect not only because grains are not spheres but also because the number of grains is not constant. Therefore, the etch depth estimated from mass loss might be overestimated. Using microscope IA we report etch depth ranges that might be used to roughly estimate the etch depth uncertainty.

Słowa kluczowe

quartz etching microscope image analysis laser diffraction particle size

Wydawca

De Gruyter

Czasopismo

Geochronometria

Rocznik

2022

Tom

Vol. 49, no. 1

Strony

1--8

Opis fizyczny

Bibliogr. 31 poz., rys.

Twórcy

autor

Poręba Grzegorz

grzegorz.poreba@polsl.pl

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

https://orcid.org/0000-0001-5852-1798

autor

Tudyka Konrad

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

https://orcid.org/0000-0002-5319-4748

autor

Szymak Agnieszka

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

https://orcid.org/0000-0001-7778-4497

autor

Pluta Julia

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

https://orcid.org/0000-0002-0843-8600

autor

Rocznik Joanna

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

https://orcid.org/0000-0003-3593-8747

autor

Świątkowski Jakub

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

autor

Osadnik Rafał

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

autor

Moska Piotr

Division of Geochronology and Environmental Isotopes, Institute of Physics – Centre for Science and Education, Silesian University of Technology Gliwice, Poland

https://orcid.org/0000-0001-6114-9595

Bibliografia

1. Aitken MJ and Bowman SGE, 1975. Electron spin resonance as a method of dating. Archaeometry 17(1): 132–138, DOI 10.1111/j.1475-4754.1975.tb00127.x.
2. Aitken MJ, 1985. Thermoluminescence Dating. Academic Press, London.
3. Bartyik T, Magyar G, Filyó D, Tóth O, Blanka-Végi V, Kiss T, Marković S, Persoiu I, Gavrilov M, Mezősi G and Sipos G, 2021. Spatial differences in the luminescence sensitivity of quartz extracted from Carpathian Basin fluvial sediments. Quaternary Geochronology 64: 101166, DOI 10.1016/j.quageo.2021.101166.
4. Bell WT and Zimmerman DW, 1978. The effect of Hf acid etching on the morphology of quartz inclusions for thermoluminescence dating. Archaeometry 20(1): 63–65, DOI 10.1111/j.1475-4754.1978.tb00213.x.
5. Bell WT, 1979. Attenuation factors for the absorbed radiation dose in quartz inclusions for thermoluminescence dating. Ancient TL 8: 2–13.
6. Berger M, Coursey J and Zucker M, 1999. ESTAR, PSTAR, and ASTAR: Computer programs for calculating stopping-power and range tables for electrons, protons, and Helium Ions (version 1.21). WEB site: <http://physics.nist.gov/Star>.
7. Bhattiprolu S, 2020. Python for Microscopists. WEB site: <https://github.com/bnsreenu/python_for_microscopists>. Accessed 2020 August 20.
8. Bradski G, 2000. The OpenCV Library. Dr. Dobb's Journal of Software Tools.
9. Califice A, Michel F, Dislaire G and Pirard E, 2013. Influence of particle shape on size distribution measurements by 3D and 2D image analyses and laser diffraction. Powder Technology 237: 67–75, DOI 10.1016/j.powtec.2013.01.003.
10. Cox EP, 1927. A method of assigning numerical and percentage values to the degree of roundness of sand grains. Journal of Paleontology. Paleontological Society 1(3): 179–183.
11. Doan DH, Delage P, Nauroy JF, Tang AM and Youssef S, 2012. Microstructural characterization of a Canadian oil sand. Canadian Geotechnical Journal 49(10): 1212–1220, DOI 10.1139/t2012-072.
12. Durcan JA, King GE and Duller GAT, 2015. DRAC: Dose rate and age calculator for trapped charge dating. Quaternary Geochronology 28: 54–61, DOI 10.1016/J.QUAGEO.2015.03.012.
13. Duval M, Campaña I, Guilarte V, Miguens L, Iglesias J and González Sierra S, 2015. Assessing the uncertainty on particle size and shape: Implications for ESR and OSL dating of quartz and feldspar grains. Radiation Measurements 81: 116–122, DOI 10.1016/j.radmeas.2015.01.012.
14. Duval M, Guilarte V, Campana I, Arnold LJ, Miguens L, Iglesias J and Gonzalez-Sierra S, 2018. Quantifying hydrofluoric acid etching of quartz and feldspar coarse grains based on weight loss estimates: Implication for ESR and luminescence dating studies. Ancient TL 36(1): 14.
15. Fleming S, 1979. Thermoluminescence techniques in archaeology. Clarendon Press, Oxford.
16. Fleming SJ, 1970. Thermoluminescent dating: Refinement of the quartz inclusion method. Archaeometry 12(2): 133–143, DOI 10.1111/j.1475-4754.1970.tb00016.x.
17. Fuchs M and Lomax J, 2019. Stone pavements in arid environments: Reasons for De overdispersion and grain-size dependent OSL ages. Quaternary Geochronology 49: 191–198, DOI 10.1016/j.quageo.2018.05.013.
18. Goedicke C, 1984. Microscopic investigations of the quartz etching technique for TL dating. Nuclear Tracks and Radiation Measurements (1982) 9(2): 87–93, DOI 10.1016/0735-245X(84)90026-7.
19. Huntley DJ, Godfrey-Smith DI and Thewalt MLW, 1985. Optical dating of sediments. Nature 313(5998): 105–107, DOI 10.1038/313105a0.
20. Ikeya M, 1978. Electron spin resonance as a method of dating. Archaeometry 20(2): 147–158, DOI 10.1111/j.1475-4754.1978.tb00225.x.
21. Leko VK and Komarova LA, 1973. Kinetics of the etching of quartz glass in hydrofluoric acid. State Scientific-Research Institute of Quartz Glass. Translated from Steklo i Keramika 11(15): 754–755.
22. Li M, Wilkinson D and Patchigolla K, 2005. Comparison of particle size distributions measured using different techniques. Particulate Science and Technology 23(3): 265–284, DOI 10.1080/02726350590955912.
23. Mason JA, Jacobs PM, Greene RSB and Nettleton WD, 2003. Sedimentary aggregates in the Peoria Loess of Nebraska, USA. CATENA 53(4): 377–397, DOI 10.1016/S0341-8162(03)00073-0.
24. Moska P, Bluszcz A, Poręba G, Tudyka K, Adamiec G, Szymak A and Przybyła A, 2021. Luminescence dating procedures at the Gliwice luminescence dating laboratory. Geochronometria 48(1): 1–15, DOI 10.2478/geochr-2021-0001.
25. Porat N, Faerstein G, Medialdea A and Murray AS, 2015. Re-examination of common extraction and purification methods of quartz and feldspar for luminescence dating. Ancient TL 33(1): 9.
26. Poręba G, Śnieszko Z, Moska P and Mroczek P, 2019. Deposits of Neolithic water soil erosion in the loess region of the Małopolska Upland (S Poland) – A case study of the settlement micro-region in Bronocice. Quaternary International 502: 45–59, DOI 10.1016/j.quaint.2018.09.018.
27. Schaetzl RJ, Forman SL and Attig JW, 2014. Optical ages on loess derived from outwash surfaces constrain the advance of the Laurentide Ice Sheet out of the Lake Superior Basin, USA. Quaternary Research 81(2): 318–329, DOI 10.1016/j.yqres.2013.12.003.
28. Tudyka K, Koruszowic M, Osadnik R, Poręba G, Moska P, Szymak A, Bluszcz A, Zhang J, Kolb T and Adamiec G, 2021. μRate. https://miu-rate.polsl.pl/, v2021.0.4, Gliwice, Poland, Accessed 2021 November 23.
29. Wintle AG and Adamiec G, 2017. Optically stimulated luminescence signals from quartz: A review. Radiation Measurements 98: 10–33, DOI 10.1016/j.radmeas.2017.02.003.
30. Wintle AG and Murray AS, 2006. A review of quartz optically stimulated luminescence characteristics and their relevance in single-aliquot regeneration dating protocols. Radiation Measurements 41(4): 369–391, DOI 10.1016/j.radmeas.2005.11.001.
31. Zheng W, Hu X, Tannant DD, Zhang K and Xu C, 2019. Characterization of two- and three-dimensional morphological properties of fragmented sand grains. Engineering Geology 263: 105358, DOI 10.1016/j.enggeo.2019.105358.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-b0f4d8d6-f20d-4530-8729-7dd72276f71b