Luís Filipe Escusa dos Santos, Hannah C. Frostenberg, Alejandro Baró Pérez, Annica M. L. Ekman, Luisa Ickes, Erik S. Thomson
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International regulations aiming to reduce SO<sub>x</sub> and particulate matter (PM) emissions, mandate ships to burn fuels with reduced sulfur content or alternatively, use wet scrubbing as exhaust after-treatment when using fuels with sulfur contents exceeding regulatory limits. Compliance measures affect the physicochemical properties of exhaust particles and their cloud condensation nuclei (CCN) activity in different ways, with the potential to have both direct and indirect impacts on atmospheric processes such as the formation and lifetime of clouds. Given the relatively pristine Arctic environment, ship exhaust particle emissions could be a large perturbation to natural baseline Arctic aerosol concentrations. Low-level stratiform mixed-phase clouds cover large areas of the Arctic region and play an important role in the regional energy budget. Results from laboratory marine engine measurements, which investigated the impact of fuel sulfur content (FSC) reduction and wet scrubbing on exhaust particle properties, motivate the use of large eddy simulations to further investigate how such particles may influence the micro- and macrophysical properties of a stratiform mixed-phase cloud case observed during the Arctic Summer Cloud Ocean Study campaign. Simulated enhancements of ship exhaust particles predominantly affected the liquid-phase properties of the cloud and led to a decrease in liquid surface precipitation, increased cloud albedo and increased longwave surface warming. The magnitude of the impact strongly depended on ship exhaust particle concentration, hygroscopicity, and size where the effect of particle size dominated the impact of hygroscopicity. While low FSC exhaust particles were mostly observed to affect cloud properties at exhaust particle concentrations of 1000 cm<sup>-3</sup>, exhaust wet scrubbing already led to significant changes at concentrations of 100 cm<sup>-3</sup>. Additional simulations with cloud ice water path increased from ≈5.5 g m<sup>-2</sup> to ≈9.3 g m<sup>-2</sup>, show more muted responses to ship exhaust perturbations but revealed that exhaust perturbations may even lead to a slight radiative cooling effect depending on the microphysical state of the cloud. 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引用次数: 0
摘要
摘要由于温室气体浓度增加和气候系统中的反馈过程,北极地区地表变暖,导致海冰范围和厚度持续下降。随着海冰的消退,未来航运活动很可能会在经济活动的推动下增加,而且通过更短的贸易航线可以节省时间和燃料。此外,在过去的十年中,全球航运业一直受到法规变化的影响,从而影响到废气颗粒的物理化学特性。旨在减少硫氧化物和微粒物质(PM)排放的国际法规要求船舶燃烧硫含量较低的燃料,或者在使用硫含量超过法规限制的燃料时使用湿式洗涤作为尾气后处理。合规措施会以不同的方式影响废气颗粒的物理化学特性及其云凝结核 (CCN) 活性,有可能对云的形成和寿命等大气过程产生直接和间接影响。鉴于北极环境相对原始,船舶废气颗粒排放可能会对北极气溶胶的自然基线浓度造成巨大干扰。低层平流混合相云覆盖了北极地区的大片区域,在区域能量预算中发挥着重要作用。实验室船用发动机测量的结果研究了降低燃料硫含量(FSC)和湿式洗涤对废气颗粒特性的影响,这促使我们使用大涡模拟来进一步研究这些颗粒如何影响在北极夏季云海研究活动中观测到的平流混合相云的微观和宏观物理特性。模拟的船舶废气颗粒增强主要影响了云的液相特性,导致液面降水减少、云反照率增加和长波表面增温。影响的大小在很大程度上取决于船舶废气颗粒的浓度、吸湿性和大小,其中颗粒大小的影响在吸湿性的影响中占主导地位。虽然在废气颗粒浓度为 1000 cm-3 时,观察到低 FSC 废气颗粒对云特性的影响最大,但在浓度为 100 cm-3 时,废气湿式洗涤已经导致了显著的变化。在将云冰水路径从≈5.5 g m-2 增加到≈9.3 g m-2 的其他模拟中,对船舶废气扰动的反应更加微弱,但发现根据云的微物理状态,废气扰动甚至可能导致轻微的辐射冷却效应。因此,航运活动对北极云特性的区域影响可能在很大程度上取决于船舶燃料类型、船舶是否使用湿式洗涤器以及决定主要云特性的环境热力学条件。
Potential impacts of marine fuel regulations on Arctic clouds and radiative feedbacks
Abstract. Increased surface warming over the Arctic, triggered by increased greenhouse gas concentrations and feedback processes in the climate system, has been causing a steady decline in sea-ice extent and thickness. With the retreating sea-ice, shipping activity will likely increase in the future driven by economic activity and the potential for realizing time and fuel savings from transiting shorter trade routes. Moreover, over the last decade, the global shipping sector has been subject to regulatory changes, that affect the physicochemical properties of exhaust particles. International regulations aiming to reduce SOx and particulate matter (PM) emissions, mandate ships to burn fuels with reduced sulfur content or alternatively, use wet scrubbing as exhaust after-treatment when using fuels with sulfur contents exceeding regulatory limits. Compliance measures affect the physicochemical properties of exhaust particles and their cloud condensation nuclei (CCN) activity in different ways, with the potential to have both direct and indirect impacts on atmospheric processes such as the formation and lifetime of clouds. Given the relatively pristine Arctic environment, ship exhaust particle emissions could be a large perturbation to natural baseline Arctic aerosol concentrations. Low-level stratiform mixed-phase clouds cover large areas of the Arctic region and play an important role in the regional energy budget. Results from laboratory marine engine measurements, which investigated the impact of fuel sulfur content (FSC) reduction and wet scrubbing on exhaust particle properties, motivate the use of large eddy simulations to further investigate how such particles may influence the micro- and macrophysical properties of a stratiform mixed-phase cloud case observed during the Arctic Summer Cloud Ocean Study campaign. Simulated enhancements of ship exhaust particles predominantly affected the liquid-phase properties of the cloud and led to a decrease in liquid surface precipitation, increased cloud albedo and increased longwave surface warming. The magnitude of the impact strongly depended on ship exhaust particle concentration, hygroscopicity, and size where the effect of particle size dominated the impact of hygroscopicity. While low FSC exhaust particles were mostly observed to affect cloud properties at exhaust particle concentrations of 1000 cm-3, exhaust wet scrubbing already led to significant changes at concentrations of 100 cm-3. Additional simulations with cloud ice water path increased from ≈5.5 g m-2 to ≈9.3 g m-2, show more muted responses to ship exhaust perturbations but revealed that exhaust perturbations may even lead to a slight radiative cooling effect depending on the microphysical state of the cloud. The regional impact of shipping activity on Arctic cloud properties may, therefore, strongly depend on ship fuel type, whether ships utilize wet scrubbers, and ambient thermodynamic conditions that determine prevailing cloud properties.
期刊介绍:
Atmospheric Chemistry and Physics (ACP) is a not-for-profit international scientific journal dedicated to the publication and public discussion of high-quality studies investigating the Earth''s atmosphere and the underlying chemical and physical processes. It covers the altitude range from the land and ocean surface up to the turbopause, including the troposphere, stratosphere, and mesosphere.
The main subject areas comprise atmospheric modelling, field measurements, remote sensing, and laboratory studies of gases, aerosols, clouds and precipitation, isotopes, radiation, dynamics, biosphere interactions, and hydrosphere interactions. The journal scope is focused on studies with general implications for atmospheric science rather than investigations that are primarily of local or technical interest.