Platt Kathryn L, Yushchenko Oleksandr, Laszakovits Juliana R, Zhang Yiwen, Pflug Nicholas C, McNeill Kristopher
Institute of Biogeochemistry and Pollutant Dynamics, ETH Zurich, 8092 Zurich, Switzerland.
Department of Chemistry, SUNY ESF, Syracuse, New York 13210, United States.
Environ Sci Technol. 2025 Jul 1;59(25):12900-12909. doi: 10.1021/acs.est.4c12896. Epub 2025 Jun 16.
A ubiquitously used tire rubber antidegradant, 6PPD (-(1,3-dimethylbutyl)-'-phenyl--phenylenediamine), and its toxic ozonation product, 6PPD-quinone (-(1,3-dimethylbutyl)-'-phenyl--phenylenediamine quinone), have become recognized as important environmental pollutants since 6PPD-quinone (6PPD-Q) was identified as the likely cause of decades of mass Coho salmon kills. The reactivity of 6PPD, 6PPD-Q, and similar phenylenediamines requires study to better understand their environmental fate. This study explores the aquatic reactivity of 6PPD, -isopropyl-'-phenyl-1,4-phenylenediamine (IPPD), and 6PPD-Q through thermal and photochemical pathways using both steady-state photochemistry and time-resolved laser spectroscopy techniques. 6PPD was found to rapidly degrade in the dark, with its degradation rate being highly dependent on the pH, temperature, and oxygen concentrations. IPPD behaves similarly to 6PPD. In contrast, 6PPD-Q is much more stable in the dark. All three chemicals are degraded via direct photochemistry. Regarding indirect photochemistry, CDOM* plays a role in the degradation of 6PPD and IPPD but not 6PPD-Q, while O does not play a significant role for any of the compounds. Reaction rate constants are reported as well as 6PPD-Q molar yields from 6PPD, which were minimal for all aqueous pathways examined. 6PPD-Q may have a longer environmental lifetime as there are fewer degradation pathways. This research will help us to better understand and control these chemicals in the environment.
一种广泛使用的轮胎橡胶抗降解剂6PPD(N-(1,3-二甲基丁基)-N'-苯基对苯二胺)及其有毒的臭氧化产物6PPD-醌(N-(1,3-二甲基丁基)-N'-苯基对苯二胺醌),自6PPD-醌(6PPD-Q)被确定为数十年来银大麻哈鱼大量死亡的可能原因以来,已被公认为重要的环境污染物。6PPD、6PPD-Q和类似对苯二胺的反应活性需要进行研究,以更好地了解它们在环境中的归宿。本研究通过稳态光化学和时间分辨激光光谱技术,探索了6PPD、N-异丙基-N'-苯基-1,4-苯二胺(IPPD)和6PPD-Q在热和光化学途径中的水生反应活性。研究发现,6PPD在黑暗中迅速降解,其降解速率高度依赖于pH值、温度和氧气浓度。IPPD的行为与6PPD相似。相比之下,6PPD-Q在黑暗中要稳定得多。所有三种化学物质都通过直接光化学降解。关于间接光化学,溶解有机质(CDOM*)在6PPD和IPPD的降解中起作用,但在6PPD-Q的降解中不起作用,而单线态氧(O)对任何一种化合物都不起重要作用。文中还报道了反应速率常数以及6PPD生成6PPD-Q的摩尔产率,在所研究的所有水相途径中,该产率都很低。由于降解途径较少,6PPD-Q在环境中的寿命可能更长。这项研究将有助于我们更好地理解和控制环境中的这些化学物质。
