引入 "累积浓度玫瑰 "的新概念,研究超细粒子从机场向邻近居民区的迁移情况

IF 5.2 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES Atmospheric Chemistry and Physics Pub Date : 2024-01-05 DOI:10.5194/acp-24-137-2024
Julius Seidler, Markus N. Friedrich, Christoph K. Thomas, Anke C. Nölscher
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引用次数: 0

摘要

摘要。机场周围往往是城市居民区,这既是研究机场对当地空气质量潜在影响的动力,也是一项挑战。机场是超细粒子(UFPs)的一个相关来源,由于其尺寸较小(粒子直径 Dp≤100 nm),可能会对人类健康造成危害。然而,在城市环境中,超细粒子来源于多种生物源和人为源。在此,我们对机场附近的 UFP 进行了调查,以将其对当地空气质量的影响与其他城市来源区分开来。我们介绍了在慕尼黑机场附近两个地点测定的空气中 UFP 浓度和大小分布的观测和分析结果。因此,我们在机场北面和南面设立了两个新的测量站,但这两个测量站既不位于盛行风向轴上,也不受飞越影响。这样的设置使我们能够探索主要由平流驱动的 UFPs 在人口最稠密的邻近居民区的分布情况。观测时间涵盖 2021 年 8 月至 2022 年 7 月的一整年。我们分三步分析了数据集。(1) 首先,我们利用机场 10 米高处报告的风力数据推导出 UFP 浓度玫瑰,以代表当地风场。在风向(包括从机场吹来的风向)方面,粒子数浓度的增加和模态最大值向较小流动直径的转移变得非常明显。在机场运行时段的白天,北站和南站的颗粒数浓度中值分别是夜间的 2.2 倍和 1.6 倍。然而,我们的数据具有很高的变异性,而且由于周围有其他潜在的 UFP 来源,并且假设当地风场是均匀的,因此基于方向的分析具有不确定性。(2) 接下来,我们利用两个 5.3 米高度测量站的气流观测数据得出了浓度玫瑰。虽然年浓度玫瑰图原则上得出了与第一步分析相同的结论,但 UFP 和风的季节性和昼夜变化非常明显。影响因素可能是城市当地的其他 UFP 来源、绿色植被导致的表面粗糙度增加以及大气边界层的发展。(3) 为了评估一年中慕尼黑机场方向相对于所有其他方向可能出现的 UFP 平流,我们利用当地和现场尺度的风力数据计算了累积浓度玫瑰。在当地风场均匀的假设下,从机场方向吹来的气流中采样的所有 UFPs 的比例分别为 21% (N322) 和 40% (S229)。考虑到当地背景,从慕尼黑机场到邻近居民区的 UFP 平流范围在北部为 10%,在南部为 14%。必须指出的是,这些数值强调的是机场对当地空气质量最大影响的相对幅度,因为它们并没有区分来自机场和其他测量点的 UFP 来源。此外,与 COVID-19 前相比,这些数值整合了机场未达到满负荷运行的时间段。
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Introducing the novel concept of cumulative concentration roses for studying the transport of ultrafine particles from an airport to adjacent residential areas
Abstract. Airports are often surrounded by urban residential areas, which is both a motivation and challenge for studying their potential impact on local air quality. Airports are a relevant source of ultrafine particles (UFPs), which can pose a risk to human health due to their small size (particle diameter Dp≤100 nm). However, in urban environments, UFPs originate from a multitude of biogenic and anthropogenic sources. Here, we investigate UFPs in close proximity to an airport to disentangle their impact on local air quality from other urban sources. We present observations and analyses of airborne UFP concentrations and size distributions determined at two sites in close proximity to Munich Airport. Therefore, two novel measurement stations were established north and south of the airport but were neither situated on the axis of prevailing wind directions nor impacted by fly overs. This set-up allowed us to explore a mainly advection-driven distribution of UFPs into the most populated adjacent residential areas. The observation period covered a full year from August 2021 to July 2022. We analysed the data set in three steps. (1) First, we derived UFP concentration roses using the wind data as reported at 10 m height at the airport to represent the local wind field. An increase in particle number concentrations and a shift of the modal maximum towards smaller mobility diameters became evident for wind directions, including those approaching from the airport. During the airport's operation hours during the daytime, median particle number concentrations were 2.2- and 1.6-fold compared to nighttime at the northern station and the southern station. However, our data had a high variability, and the direction-based analysis was uncertain due to other potential UFP sources in the surroundings and the assumption of a homogeneous, local wind field. (2) Next, we derived concentration roses employing the airflow observations from the two measuring stations at 5.3 m height. While the annual concentration rose in principle yielded the same conclusions as the first analysis step, a significant seasonal and diurnal variability of UFPs and wind became evident. The influencing factors were likely other urban local UFP sources, an increased surface roughness due to green vegetation, and the atmospheric boundary layer development. (3) In order to assess the possible advection of UFPs from the direction of Munich Airport relative to all other directions over the course of the year, we calculated cumulative concentration roses with both local- and site-scale wind data. Under the assumption of a homogeneous local wind field, the fraction of all UFPs sampled in airflows approaching from the airport's direction was 21 % (N322) and 40 % (S229). Considering a local background, the range of UFP advection from Munich Airport to the adjacent residential areas was up to 10 % in the north and 14 % in the south. It has to be noted that these values highlight the relative magnitude of the maximum impact of the airport on local air quality as they do not distinguish between UFP sources from the airport and other measuring sites. Additionally, they integrate over a time period during which the airport did not reach its full capacity compared to pre-COVID-19 times.
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来源期刊
Atmospheric Chemistry and Physics
Atmospheric Chemistry and Physics 地学-气象与大气科学
CiteScore
10.70
自引率
20.60%
发文量
702
审稿时长
6 months
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.
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