References
- Agnihotri R, Kumar R, Prasad M, Sharma C, Bhatia S and Arya B, 2014. Experimental setup and standardization of a continuous flow stable isotope mass spectrometer for measuring stable isotopes of carbon, nitrogen and sulfur in environmental samples. Mapan 29: 195–205.
- ANRPC, (n.d.). Monthly nr statistical report. WEB site: <
http://www.Anrpc.Org/html/news-secretariat-details.Aspx?Id=9&pid=39&nid=9690 >. Accessed 2023 June 20. - ASTM:D1506-15, 2020. Standard test methods for carbon black—ash content. WEB site: <
https://www.Astm.Org/d1506-15r20.Html >. Accessed 2024 January 19. - ASTM:D1765-17, (n.d.). Standard classification system for carbon blacks used in rubber products. WEB site: <
https://www.Astm.Org/d1765-17.Html >. Accessed 2023 March 08. - CIO, 2022. Reference radiocarbon values for 100% biogenic carbon (14Cbio) based on atmospheric 14CO2, WEB site: <
https://www.Rug.Nl/research/centre-for-isotope-research/customers/tools/reference-radiocarbon-values-palstra-andmeijer?Lang=en >. Accessed 2022 June 12. - Contec, (n.d.). Carbon black tire grades: Sustainable opportunities for the manufacturing industry. WEB site: <
https://contec.Tech/carbon-black-grades-sustainable-alternatives/ >. Accessed 2023 March 08. - Donnet JB, 2017. Carbon Black: Science and Technology. New York,
https://doi.org/10.1201/9781315138763 . - EN16640, 2017. Bio-based products - bio-based carbon content - determination of the bio-based carbon content using the radiocarbon method. WEB site: <
https://standards.Iteh.Ai/catalog/standards/sist/c5b5c847-51e4-448f-8d96-236190a4a145/sist-en-16640-2017 >. Accessed 2023 November 22. - Fan Y, Fowler GD and Zhao M, 2020. The past, present and future of carbon black as a rubber reinforcing filler–a review. Journal of Cleaner Production 247: 119115.
- Gill KA, Michczyńska DJ, Michczyński A, Piotrowska N, Kłusek M, Końska K, Wróblewski K, Nadeau MJ and Seiler M, 2022. Study of bio-based carbon fractions in tires and their pyrolysis products. Radiocarbon 64(6): 1457–1469.
- Haverly MR, Fenwick SR, Patterson FP and Slade DA, 2019. Bio-based carbon content quantification through AMS radiocarbon analysis of liquid fuels. Fuel 237: 1108–1111.
- Hua Q, Turnbull JC, Santos GM, Rakowski AZ, Ancapichún S, De Pol-Holz R, Hammer S, Lehman SJ, Levin I and Miller JB, 2021. Atmospheric radiocarbon for the period 1950–2019. Radiocarbon 64(4): 723–745.
- IAEA-CH-6, (n.d.). Reference products for environment and trade. WEB site: <
https://nucleus.Iaea.Org/sites/referencematerials/pages/iaea-ch-6.Aspx >. Accessed 2023 June 26. - IAEA-NBS, (n.d.). Reference material for δ13C and δ2H. WEB site: <
https://nucleus.Iaea.Org/sites/referencematerials/shared%20documents/referencematerials/stableisotopes/nbs-22/rs-nbs22.Pdf >. Accessed 2023 June 26. - Intharapat P, Kongnoo A and Kateungngan K, 2013. The potential of chicken eggshell waste as a bio-filler filled epoxidized natural rubber (enr) composite and its properties. Journal of Polymers and the Environment 21: 245–258.
- Khodabakhshi S, Fulvio PF and Andreoli E, 2020. Carbon black re-born: Structure and chemistry for renewable energy harnessing. Carbon 162: 604–649.
- Kunioka M, Taguchi K, Ninomiya F, Nakajima M, Saito A and Araki S, 2014. Biobased contents of natural rubber model compound and its separated constituents. Polymers 6(2): 423–442.
- Kutschera W, 2019. The half-life of 14C—why is it so long? Radiocarbon 61(5): 1135–1142.
- Multiflow I, 2012. Multiflow user guide. V1.1. WEB site: <
http://support.Isoprime.Co.Uk/resolve/index.Php?/knowledgebase/article/view/35/26/multiflow-user-guide >. Accessed 2023 November 2. - Němec M, Wacker L and Gäggeler H, 2010. Optimization of the graphitization process at age-1. Radiocarbon 52(3): 1380–1393.
- Pawlyta J, Pazdur A, Rakowski AZ, Miller BF and Harkness DD, 1997. Commissioning of a Quantulus 1220™ liquid scintillation beta spectrometer for measuring 14C and 3H at natural abundance levels. Radiocarbon 40(1): 201–209.
- Pazdur A, Fogtman M, Michczyński A and Pawlyta J, 2003. Precision of 14C dating in Gliwice radiocarbon laboratory. Firi programme. Geochronometria 22(1): 27–40.
- Pehlken A and Essadiqi E, 2005. Scrap tire recycling in Canada. CANMET Materials Technology Laboratory Report MTL 8: 1–62.
- Piotrowska N, 2013. Status report of AMS sample preparation laboratory at GADAM centre, Gliwice, Poland. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 294: 176–181.
- Robertson CG and Hardman NJ, 2021. Nature of carbon black reinforcement of rubber: Perspective on the original polymer nanocomposite. Polymers 13(4): 538.
- Stuiver M and Polach HA, 1977. Discussion reporting of 14C data. Radiocarbon 19(3): 355–363.
- Synal HA, Stocker M and Suter M, 2007. MICADAS: A new compact radiocarbon AMS system. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 259(1): 7–13.
- Ustrzycka A, 2020. Spektrometria mas lekkich izotopów stabilnych w badaniach ekosystemu jeziornego (light isotope mass spectrometry for lake ecosystem studies). Phd thesis, Silesian University of Technology, Institute of Physics - CSE: 90pp (in Polish).
- Wacker L, Christl M and Synal HA, 2010a. BATS: A new tool for AMS data reduction. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 268(7–8): 976–979.
- Wacker L, Němec M and Bourquin J, 2010b. A revolutionary graphitisation system: Fully automated, compact and simple. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 268(7–8): 931–934.