J. Barten, L. Ganzeveld, G. Steeneveld, B. Blomquist, H. Angot, S. Archer, L. Bariteau, Ivo Beck, M. Boyer, P. von der Gathen, D. Helmig, D. Howard, J. Hueber, H. Jacobi, T. Jokinen, T. Laurila, Kevin M. Posman, L. Quéléver, J. Schmale, M. Shupe, M. Krol
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引用次数: 3
Abstract
Dry deposition to the surface is one of the main removal pathways of tropospheric ozone (O3). We quantified for the first time the impact of O3 deposition to the Arctic sea ice on the planetary boundary layer (PBL) O3 concentration and budget using year-round flux and concentration observations from the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) campaign and simulations with a single-column atmospheric chemistry and meteorological model (SCM). Based on eddy-covariance O3 surface flux observations, we find a median surface resistance on the order of 20,000 s m−1, resulting in a dry deposition velocity of approximately 0.005 cm s−1. This surface resistance is up to an order of magnitude larger than traditionally used values in many atmospheric chemistry and transport models. The SCM is able to accurately represent the yearly cycle, with maxima above 40 ppb in the winter and minima around 15 ppb at the end of summer. However, the observed springtime ozone depletion events are not captured by the SCM. In winter, the modelled PBL O3 budget is governed by dry deposition at the surface mostly compensated by downward turbulent transport of O3 towards the surface. Advection, which is accounted for implicitly by nudging to reanalysis data, poses a substantial, mostly negative, contribution to the simulated PBL O3 budget in summer. During episodes with low wind speed (<5 m s−1) and shallow PBL (<50 m), the 7-day mean dry deposition removal rate can reach up to 1.0 ppb h−1. Our study highlights the importance of an accurate description of dry deposition to Arctic sea ice in models to quantify the current and future O3 sink in the Arctic, impacting the tropospheric O3 budget, which has been modified in the last century largely due to anthropogenic activities.
干沉降到地面是对流层臭氧(O3)的主要清除途径之一。利用多学科北极气候漂移观测站(MOSAiC)的全年通量和浓度观测数据,以及单柱大气化学和气象模式(SCM)的模拟,首次量化了O3沉积对北极海冰行星边界层(PBL) O3浓度和收支的影响。基于涡旋协方差O3表面通量观测,我们发现中位表面阻力约为20,000 s m−1,导致干沉积速度约为0.005 cm s−1。这种表面阻力比许多大气化学和输送模型中传统使用的值大一个数量级。SCM能够准确地表示年周期,冬季最大值超过40 ppb,夏末最小值约为15 ppb。然而,观测到的春季臭氧消耗事件没有被SCM捕获。在冬季,模拟的PBL O3收支受地表干沉积控制,主要由O3向地表的向下湍流输送补偿。通过重新分析数据,平流对夏季模拟PBL O3预算的贡献很大,但大部分是负的。在低风速(<5 m s−1)和浅边界层(<50 m)条件下,7天平均干沉降去除率可达1.0 ppb h−1。我们的研究强调了在模式中准确描述干沉积对北极海冰的重要性,以量化北极当前和未来的O3汇,影响对流层O3收支,这在上个世纪主要是由于人为活动而被修改的。
期刊介绍:
A new open-access scientific journal, Elementa: Science of the Anthropocene publishes original research reporting on new knowledge of the Earth’s physical, chemical, and biological systems; interactions between human and natural systems; and steps that can be taken to mitigate and adapt to global change. Elementa reports on fundamental advancements in research organized initially into six knowledge domains, embracing the concept that basic knowledge can foster sustainable solutions for society. Elementa is published on an open-access, public-good basis—available freely and immediately to the world.