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F. Sommer, V. Dietze, A. Baum, J. Sauer, S. Gilge, C. Maschowski, and R. Giere, "Tire abrasion as a major source of microplastics in the environment", Aerosol Air Qual. Res., 18, 2014 (2018).
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2 |
S. Wagner, T. Huffer, P. Klockner, M. Wehrhahn, T. Hofmann, and T. Reemtsma, "Tire wear particles in the aquatic environment - A review on generation, analysis, occurrence, fate and effects", Wear Res., 139, 83 (2018).
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3 |
M. Dall'Osto, D. C. S. Beddows, J. K. Gietl, O. A. Olatunbosun, X. Yang, and R. M. Harrison, "Characteristics of tyre dust in polluted air: Studies by single particle mass spectrometry (ATOFMS)", Atmos. Environ., 94, 224 (2014).
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4 |
J. M. Panko, K. M. Hitchcock, G. W. Fuller, and D. Green, "Evaluation of tire wear contribution to PM2.5 in urban environments", Atmosphere, 10, 99 (2019).
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5 |
ASTM D5963, "Standard Test Method for Rubber Property - Abrasion Resistance (Rotary Drum Abrader)".
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6 |
ISO 4649, "Rubber, vulcanized, or thermoplastic - Determination of abrasion resistance using a rotating cylindrical drum device".
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7 |
J.-H. Lee, J. Lee, T. J. Han, and H. M. Jeong, "Improvement of abrasion resistance and friction of rubber blend composition", Elast. Compos., 55, 161 (2020).
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8 |
M. Salehi, J. W. M. Noordermeer, L. A. E. M. Reuvekamp, W. K. Dierkes, and A. Blume, "Measuring rubber friction using a Laboratory Abrasion Tester (LAT100) to predict car tire dry ABS braking", Tribol. Int., 131, 191 (2019).
DOI
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9 |
K. A. Grosch, "Rubber abrasion and tire wear", Rubber Chem. Technol., 81, 470 (2008).
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10 |
ISO 23233:2009, "Rubber, vulcanized or thermoplastic - Determination of resistance to abrasion using a driven, vertical abrasive disc".
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11 |
S.-S. Choi, S. R. Yang, E. Chae, and C. E. Son, "Influence of carbon black contents and rubber compositions on formation of wear debris of rubber vulcanizates", Elast. Compos., 55, 108 (2020).
DOI
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12 |
ASTM D2228, "Standard Test Method for Rubber Property - Relative Abrasion Resistance by Pico Abrader Method".
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