美国东部非城市臭氧浓度时空变化特征

Brian K. Eder , Jerry M. Davis, Peter Bloomfield
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引用次数: 67

摘要

采用主成分分析方法研究了1985-1990年期间美国东部非城市地区每日1小时最大臭氧浓度的时空变化。利用Kaiser's Varimax正交旋转法,划定了6个相邻的子区域或“影响区”,共占总方差的64.02%。各子区域的O3特征在统计上是独特的,且与反气旋的路径和频率有很好的对应关系。与整个区域相比,大西洋中部和南部次区域观察到更高的平均日1小时最大浓度。东北和西南分区域的浓度接近区域平均水平,五大湖和佛罗里达分区域的浓度最低。观测值超过120 ppb的百分比在大西洋中部和西南次区域最大,在东北和南部次区域接近区域平均值,在五大湖和佛罗里达次区域最低。对与分区域有关的主成分得分的时间序列的检查表明,大湖区和大西洋中部分区域倾向于观察到更强的季节周期,最大浓度分别发生在6月的最后一周和7月的第一周。在东北和南部分区域,这种季节性的强度有所减弱,时间也有所推迟,分别推迟到7月底和8月初。西南分区域的季节性大大减弱,最大浓度推迟到8月中旬。佛罗里达分区域的季节性在强度和时间上都是独一无二的,因为最高浓度始终发生在4月和5月。然后对时间序列进行去季节化,并计算自相关和光谱密度估计,显示佛罗里达州(自相关显著滞后4天)、南部(3天)和西南(3天)次区域的持久性更为普遍。相反,自相关性仅在东北部滞后一天,在五大湖和大西洋中部次区域滞后两天。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A characterization of the spatiotemporal variability of non-urban ozone concentrations over the eastern United States

The spatial and temporal variability of the daily 1-h maximum O3 concentrations over non-urban areas of the eastern United States of America was examined for the period 1985–1990 using principal component analysis. Utilization of Kaiser's Varimax orthogonal rotation led to the delineation of six contiguous subregions or “influence regimes” which together accounted for 64.02% of the total variance. Each subregion displayed statistically unique O3 characteristics and corresponded well with the path and frequency of anticyclones. When compared to the entire domain, the mid-Atlantic and south subregions observe higher mean daily 1-h maximum concentrations. Concentrations are near the domain average for the northeast and southwest subregions and are lowest in the Great Lakes and Florida subregions. The percentage of observations exceeding 120 ppb were greates in the mid-Atlantic and southwest subregions, near the domain average in the northeast and south subregions, and lowest in the Great Lakes and Florida subregions.

Examination of the time series of the principal component scores associated with the subregions indicated that Great Lakes and mid-Atlantic subregions tend to observe a stronger seasonal cycle, with maximum concentrations occurring during the last week in June and first week in July, respectively. The strength of this seasonality is weakened for the northeast and south subregions and its timing delayed, until the end of July and the first of August, respectively. The southwest subregion experiences a greatly diminished seasonality, with maximum concentrations delayed until the middle of August. The seasonality found in the Florida subregion is unique in both its strength and timing, as the highest concentrations consistently occur during the months of April and May. The time series were then deseasonalized and autocorrelations and spectral density estimates calculated, revealing that persistence is much more prevalent in the Florida (autocorrelation significant to a lag of 4 days), south (3 days) and southwest (3 days) subregions. Conversely, autocorrelations are only significant to a lag of one day in the northeast and two days for the Great Lakes and mid-Atlantic subregions.

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