Atmospheric chemistry of hydrogen fluoride

IF 3 4区 地球科学 Q2 ENVIRONMENTAL SCIENCES
Meng-Dawn Cheng
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引用次数: 15

Abstract

Although a large volume of monitoring and computer simulation data exist for global coverage of HF, study of HF in the troposphere is still limited to industry whose primary interest is the safety and risk assessment of HF release because it is a toxic gas. There is very limited information on atmospheric chemistry, emission sources, and the behavior of HF in the environment. We provide a comprehensive review on the atmospheric chemistry of HF, modeling the reactions and transport of HF in the atmosphere, the removal processes in the vertical layer immediately adjacent to the surface (up to approximately 500?m) and recommend research needed to improve our understanding of atmospheric chemistry of HF in the troposphere. The atmospheric chemistry, emissions, and surface boundary layer transport of hydrogen fluoride (HF) are summarized. Although HF is known to be chemically reactive and highly soluble, both factors affect transport and removal in the atmosphere, the chemistry can be ignored when the HF concentration is at a sufficiently low level (e.g., 10 ppmv). At a low concentration, the capability for HF to react in the atmosphere is diminished and therefore the species can be mathematically treated as inert during the transport. At a sufficiently high concentration of HF (e.g., kg/s release rate and thousands of ppm), however, HF can go through a series of rigorous chemical reactions including polymerization, depolymerization, and reaction with water to form molecular complex. As such, the HF species cannot be considered as inert because the reactions could intimately influence the plume’s thermodynamic properties affecting the changes in plume temperature and density. The atmospheric residence time of HF was found to be less than four (4) days, and deposition (i.e., atmosphere to surface transport) is the dominant mechanism that controls the removal of HF and its oligomers from the atmosphere. The literature data on HF dry deposition velocity was relatively high compared to many commonly found atmospheric species such as ozone, sulfur dioxide, nitrogen oxides, etc. The global average of wet deposition velocity of HF was found to be zero based on one literature source. Uptake of HF by rain drops is limited by the acidity of the rain drops, and atmospheric particulate matter contributes negligibly to HF uptake. Finally, given that the reactivity of HF at a high release rate and elevated mole concentration cannot be ignored, it is important to incorporate the reaction chemistry in the near-field dispersion close to the proximity of the release source, and to incorporate the deposition mechanism in the far-field dispersion away from the release source. In other words, a hybrid computational scheme may be needed to address transport and atmospheric chemistry of HF in a range of applications. The model uncertainty will be limited by the precision of boundary layer parameterization and ability to accurately model the atmospheric turbulence.

Abstract Image

氟化氢的大气化学
尽管存在大量的HF全球覆盖监测和计算机模拟数据,但对流层HF的研究仍然局限于工业领域,其主要兴趣是HF释放的安全性和风险评估,因为它是一种有毒气体。关于大气化学、排放源和HF在环境中的行为的信息非常有限。我们对HF的大气化学进行了全面的回顾,模拟了HF在大气中的反应和传输,以及在与地表相邻的垂直层(高达约500 μ m)的去除过程,并推荐了提高我们对对流层中HF大气化学的理解所需的研究。综述了氟化氢(HF)的大气化学、排放和表面边界层输运。虽然已知HF具有化学反应性和高度可溶性,但这两个因素都会影响大气中的迁移和去除,当HF浓度足够低时(例如,10 ppmv),化学作用可以忽略不计。在低浓度下,HF在大气中的反应能力减弱,因此在数学上可以将该物质在运输过程中视为惰性物质。然而,在足够高的HF浓度下(例如,kg/s释放速率和数千ppm), HF可以经历一系列严格的化学反应,包括聚合、解聚和与水的反应,形成分子复合物。因此,HF不能被认为是惰性的,因为这些反应会密切影响羽流的热力学性质,从而影响羽流温度和密度的变化。HF在大气中的停留时间小于4天,沉积(即从大气到地面的输送)是控制HF及其低聚物从大气中去除的主要机制。与臭氧、二氧化硫、氮氧化物等常见大气物质相比,HF干沉降速度的文献数据相对较高。根据一份文献资料,发现HF湿沉积速度的全球平均值为零。雨滴对HF的吸收受到雨滴酸度的限制,大气颗粒物对HF吸收的贡献可以忽略不计。最后,考虑到HF在高释放速率和高摩尔浓度下的反应性不容忽视,在接近释放源的近场分散中纳入反应化学,在远离释放源的远场分散中纳入沉积机制是很重要的。换句话说,在一系列应用中,可能需要一种混合计算方案来解决HF的输运和大气化学问题。模式的不确定性将受到边界层参数化精度和精确模拟大气湍流能力的限制。
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来源期刊
Journal of Atmospheric Chemistry
Journal of Atmospheric Chemistry 地学-环境科学
CiteScore
4.60
自引率
5.00%
发文量
16
审稿时长
7.5 months
期刊介绍: The Journal of Atmospheric Chemistry is devoted to the study of the chemistry of the Earth''s atmosphere, the emphasis being laid on the region below about 100 km. The strongly interdisciplinary nature of atmospheric chemistry means that it embraces a great variety of sciences, but the journal concentrates on the following topics: Observational, interpretative and modelling studies of the composition of air and precipitation and the physiochemical processes in the Earth''s atmosphere, excluding air pollution problems of local importance only. The role of the atmosphere in biogeochemical cycles; the chemical interaction of the oceans, land surface and biosphere with the atmosphere. Laboratory studies of the mechanics in homogeneous and heterogeneous transformation processes in the atmosphere. Descriptions of major advances in instrumentation developed for the measurement of atmospheric composition and chemical properties.
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