Numerical simulation of the radioactive contamination of Ukraine after the Chornobyl disaster: the influence of the input meteorological data on the results uncertainty

IF 0.6 Q4 GEOCHEMISTRY & GEOPHYSICS Geofizicheskiy Zhurnal-Geophysical Journal Pub Date : 2023-05-14 DOI:10.24028/gj.v45i2.278332
O. Skrynyk, S. Bubin
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Abstract

In this article we assess the sensitivity of the numerical simulations of the radioactive 137Cs contamination of Ukraine caused by the Chornobyl nuclear power plant accident in 1986 to the input meteorological data. The atmospheric transport, dispersion, and deposition (dry scavenging and rain washout) of the radioactive aerosols was simulated using the CALPUFF dispersion model. The source parameterization of the 137Cs emissions during the active phase of the catastrophe (26 April—May 5 of 1986) was adopted from the previously published literature results. Seventeen different versions/realizations of the input meteorology for CALPUFF simulations were prepared with the regional prognostic meteorological model WRF by combining the available global atmospheric reanalyses for 1986 (NNRP, ERA-Interim, ERA5, CFSR) and the model’s physical parameterizations (microphysics, radiation processes, boundary/surface layer physics). The assessment of the simulation uncertainty was carried out in two different ways. In the first approach, the uncertainty was estimated as the width of the distribution of the calculated 137Cs surface concentrations (adjusted to the logarithmic scale), which were obtained with different versions of the input meteorology. The second approach was based on the statistical comparison of the calculated 137Cs contaminations and the corresponding measured values obtained during a complex assessment of the aftermath of the disaster made at the beginning of 1990s. Two statistical metrics were used: the geometric mean bias and the geometric mean variance. The results of our study demonstrate that even when using somewhat unified meteorological data (atmospheric reanalysis), the results of the radioactive contamination calculations at the same spatial locations can differ by several orders of magnitude. We find that the uncertainty depends not only on the distance to the source of the emissions but also on the physical mechanism (wet or dry deposition) responsible for the formation of the local contamination
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切尔诺贝利灾难后乌克兰放射性污染的数值模拟:输入气象资料对结果不确定性的影响
在本文中,我们评估了1986年切尔诺贝利核电站事故对乌克兰放射性137Cs污染的数值模拟对输入气象数据的敏感性。使用CALPUFF扩散模型模拟了放射性气溶胶的大气传输、扩散和沉积(干清除和雨水冲刷)。灾难活跃阶段(1986年4月26日至5月5日)137Cs排放的源参数化采用了先前发表的文献结果。通过结合1986年可用的全球大气再分析(NNRP、ERA Interim、ERA5、CFSR)和该模型的物理参数化(微观物理、辐射过程、边界/表层物理),用区域预测气象模型WRF为CALPUFF模拟准备了17个不同版本/实现的输入气象学。模拟不确定性的评估采用了两种不同的方式。在第一种方法中,不确定性被估计为计算的137Cs表面浓度的分布宽度(调整为对数尺度),这些浓度是用不同版本的输入气象学获得的。第二种方法是基于对1990年代初对灾难后果进行复杂评估期间计算的137Cs污染和相应测量值的统计比较。使用了两种统计指标:几何平均偏差和几何平均方差。我们的研究结果表明,即使使用某种程度上统一的气象数据(大气再分析),在相同空间位置的放射性污染计算结果也可能相差几个数量级。我们发现,不确定性不仅取决于到排放源的距离,还取决于导致局部污染形成的物理机制(湿沉积或干沉积)
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来源期刊
Geofizicheskiy Zhurnal-Geophysical Journal
Geofizicheskiy Zhurnal-Geophysical Journal GEOCHEMISTRY & GEOPHYSICS-
自引率
60.00%
发文量
50
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