Enhanced photochemical formation of active nitrogen species from aqueous nitrate in the presence of halide ions

IF 3.3 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES Frontiers in Environmental Science Pub Date : 2024-08-22 DOI:10.3389/fenvs.2024.1466512

Yilong Zhao, Chengwei Liu, Xiang Tu, Wenkai Huang, Yu Liu, Hongbo Fu

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Abstract

Field observations have confirmed that halide ions are widely distributed among aerosols from the marine boundary layer and on the surfaces of ice and snow in polar regions. Consequently, the coexistence of halide ions may play a more significant role in nitrate photolysis than previously thought. In this study, we simultaneously measured HONO, NO2, and NO2−in situ to gain a deeper understanding of the coexisting system, including the photogenerated nitrogen products and the effects on nitrate photolysis rates due to enhanced aqueous nitrite and HONO transfer rates by halides. The presence of halides significantly increased the photogenerated nitrogen products across various molar ratios ([X–]/[NO3−]) at pH 3.5. By eliminating oxygen flux, the transformation of the primary photogenerated products was affected, resulting in higher concentrations of N(III) as both HONO and NO2−. Experiments involving OH scavengers indicated that the attack from·OH initiated by halides leads to side reactions that enhance nitrate photolysis. Both theoretical calculations and nitrate actinometry were used to determine the photolysis rate of nitrate solutions, which together indicated that the presence of halides enhances nitrate photolysis. A newly developed model was used to determine the HONO transfer rate, finding that the presence of halides ([X–]/[NO3−] = 0.2) enhanced the evaporation of N(III) in solution by factors of 0.68, 0.95, and 1.27 for Cl−, Br−, and I−, respectively. To our knowledge, this is the first determination of halide effects on the mass transfer of HONO. The enhanced nitrate photolysis rate can be attributed to the differential surface effects of halides and parallel reactions initiated via ·OH stemming from nitrate photolysis, with varying rates leading to different quantities of nitrogenous products. Additionally, simultaneous measurements of photoproducts in both gas and condensed phases are recommended to better constrain the rate constants of NO3− photolysis.

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在卤化物离子存在的情况下，硝酸盐水溶液中活性氮物质的光化学形成得到增强

实地观测证实，卤化离子广泛分布于海洋边界层气溶胶和极地冰雪表面。因此，卤化离子的共存可能在硝酸盐光解过程中发挥着比以前想象的更重要的作用。在这项研究中，我们同时对 HONO、NO2 和 NO2 进行了现场测量，以深入了解共存系统，包括光生成的氮产物以及卤化物增强水体亚硝酸盐和 HONO 转移率对硝酸盐光解率的影响。在 pH 值为 3.5 时，不同摩尔比（[X-]/[NO3-]）下，卤化物的存在明显增加了光生氮产物。通过消除氧通量，主要光生产物的转化受到了影响，导致以 HONO 和 NO2- 形式存在的 N（III）浓度升高。涉及羟基清除剂的实验表明，由卤化物引发的羟基攻击会导致副反应，从而增强硝酸盐的光解作用。理论计算和硝酸盐光度测定法都被用来确定硝酸盐溶液的光解速率，它们共同表明卤化物的存在会增强硝酸盐的光解。利用新开发的模型确定了 HONO 的转移率，发现卤化物的存在（[X-]/[NO3-] = 0.2）增强了溶液中 N(III)的蒸发，Cl-、Br- 和 I- 的系数分别为 0.68、0.95 和 1.27。据我们所知，这是首次测定卤化物对 HONO 质量转移的影响。硝酸盐光解速率的提高可归因于卤化物的不同表面效应以及硝酸盐光解产生的-OH引发的平行反应，不同的速率会产生不同数量的含氮产物。此外，建议同时测量气相和凝聚相中的光产物，以便更好地确定 NO3- 光解的速率常数。

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来源期刊

Frontiers in Environmental Science Environmental Science-General Environmental Science

CiteScore

4.50

自引率

8.70%

发文量

2276

审稿时长

12 weeks

期刊介绍： Our natural world is experiencing a state of rapid change unprecedented in the presence of humans. The changes affect virtually all physical, chemical and biological systems on Earth. The interaction of these systems leads to tipping points, feedbacks and amplification of effects. In virtually all cases, the causes of environmental change can be traced to human activity through either direct interventions as a consequence of pollution, or through global warming from greenhouse case emissions. Well-formulated and internationally-relevant policies to mitigate the change, or adapt to the consequences, that will ensure our ability to thrive in the coming decades are badly needed. Without proper understanding of the processes involved, and deep understanding of the likely impacts of bad decisions or inaction, the security of food, water and energy is a risk. Left unchecked shortages of these basic commodities will lead to migration, global geopolitical tension and conflict. This represents the major challenge of our time. We are the first generation to appreciate the problem and we will be judged in future by our ability to determine and take the action necessary. Appropriate knowledge of the condition of our natural world, appreciation of the changes occurring, and predictions of how the future will develop are requisite to the definition and implementation of solutions. Frontiers in Environmental Science publishes research at the cutting edge of knowledge of our natural world and its various intersections with society. It bridges between the identification and measurement of change, comprehension of the processes responsible, and the measures needed to reduce their impact. Its aim is to assist the formulation of policies, by offering sound scientific evidence on environmental science, that will lead to a more inhabitable and sustainable world for the generations to come.