Itahashi Syuichi, Mathur Rohit, Hogrefe Christian, Zhang Yang
Environmental Science Research Laboratory, Central Research Institute of Electric Power Industry (CRIEPI), 1646 Abiko, Abiko, Chiba 270-1194, Japan.
Environmental Protection Agency (EPA), Computational Exposure Division, National Exposure Research Laboratory, Office of Research and Development, Research Triangle Park, NC 27711, USA.
Atmos Chem Phys. 2020 Mar 23;20(6):3373-3396. doi: 10.5194/acp-20-3373-2020.
Stratospheric intrusion and trans-Pacific transport have been recognized as a potential source of tropospheric ozone over the US. The state-of-the-science Community Multiscale Air Quality (CMAQ) modeling system has recently been extended for hemispheric-scale modeling applications (referred to as H-CMAQ). In this study, H-CMAQ is applied to study the stratospheric intrusion and trans-Pacific transport during April 2010. The results will be presented in two companion papers. In this Part 1 paper, model evaluation for tropospheric ozone (O) is presented. Observations at the surface, by ozonesondes and airplane, and by satellite across the Northern Hemisphere are used to evaluate the model performance for O. H-CMAQ is able to capture surface and boundary layer (defined as surface to 750hPa) O with a normalized mean bias (NMB) of -10%; however, a systematic underestimation with an NMB up to -30% is found in the free troposphere (defined as 750-250hPa). In addition, a new air mass characterization method is developed to distinguish influences of stratosphere-troposphere transport (STT) from the effects of photochemistry on O levels. This method is developed based on the ratio of O and an inert tracer indicating stratospheric O to examine the importance of photochemistry, and sequential intrusion from upper layer. During April 2010, on a monthly average basis, the relationship between surface O mixing ratios and estimated stratospheric air masses in the troposphere show a slight negative slope, indicating that high surface O values are primarily affected by other factors (i.e., emissions), whereas this relationship shows a slight positive slope at elevated sites, indicating that STT has a possible impact at elevated sites. STT shows large day-to-day variations, and STT impacts can either originate from the same air mass over the entire US with an eastward movement found during early April, or stem from different air masses at different locations indicated during late April. Based on this newly established air mass characterization technique, this study can contribute to understanding the role of STT and also the implied importance of emissions leading to high surface O. Further research focused on emissions is discussed in a subsequent paper (Part 2).
平流层侵入和跨太平洋输送已被认为是美国对流层臭氧的一个潜在来源。最新的科学水平的社区多尺度空气质量(CMAQ)建模系统最近已扩展用于半球尺度建模应用(称为H-CMAQ)。在本研究中,H-CMAQ被用于研究2010年4月期间的平流层侵入和跨太平洋输送。结果将在两篇配套论文中呈现。在这第1部分论文中,给出了对流层臭氧(O)的模型评估。利用北半球各地的地面观测、臭氧探空仪和飞机观测以及卫星观测来评估模型对O的性能。H-CMAQ能够以-10%的归一化平均偏差(NMB)捕捉地面和边界层(定义为地面至750百帕)的O;然而,在自由对流层(定义为750 - 250百帕)中发现存在系统性低估,NMB高达-30%。此外,开发了一种新的气团表征方法,以区分平流层 - 对流层输送(STT)对O水平的影响与光化学作用的影响。该方法基于O与指示平流层O的惰性示踪剂的比率来研究光化学以及上层的连续侵入的重要性。在2010年4月期间,按月平均计算,对流层中地面O混合比与估计的平流层气团之间的关系呈现出轻微的负斜率,表明高地面O值主要受其他因素(即排放)影响,而在高处站点这种关系呈现出轻微的正斜率,表明STT在高处站点可能有影响。STT表现出较大的逐日变化,并且STT的影响要么源于4月初发现的整个美国上空向东移动的同一气团,要么源于4月下旬不同位置的不同气团。基于这种新建立的气团表征技术,本研究有助于理解STT的作用以及导致高地面O的排放的隐含重要性。后续论文(第2部分)将讨论针对排放的进一步研究。
