东北暖季干线统计分析

Statistical analysis of drylines in Northeast China

  • 摘要: 基于常规地面观测、高空观测和卫星、雷达资料,对2003—2017年中国东北地区暖季(5—8月)干线时空分布、气象要素等进行了统计分析。研究发现,东北地区干线主要出现在东北平原和辽宁西部,干线发生频率呈现南多北少的趋势。干线大多呈西南—东北向,宽度为90—120 km,长度在100—800 km。东北区域暖季年均干线发生频率为15.5%。干线发生频率年际变化不明显,年均逐旬变化显著且呈正弦曲线状,其中5月中下旬—6月下旬和8月中、下旬为波峰,干线发生频率在20%以上,7月低于10%,为波谷。干线湿侧气压相比干侧略高1 hPa,两侧温度大多在24℃以上,温差一般为1—4℃,露点梯度和比湿梯度范围分别为9.6—15℃/(100 km)和4.5—8.3 g/(kg·100 km),相当位温梯度在9.6—19 K/(100 km)。干线两侧要素及其梯度值逐旬变化显著,其中两侧湿度、温度和湿度梯度值8月呈增大趋势,而温度梯度绝对值呈减小趋势。在共计286例干线中有40%的干线触发了对流,6月上、中旬干线触发对流比率最高(超过60%)。干线是否触发对流与其所在位置关系不大。对流干线湿度梯度略大于无对流干线。无对流干线和对流干线探空要素的最显著区别是湿侧对流有效位能值,前者在1200 J/kg以下,后者基本在1200 J/kg以上,最高甚至能达到3000 J/kg。

     

    Abstract: Based on conventional surface observations, soundings, satellite and radar data, temporal and spatial distributions and meteorological elements of the drylines in the warm season (May—August) in Northeast China (40°—53°N, 115°—135°E) during 2003—2017 are analyzed. The research shows that the drylines in Northeast China are mainly located in the Northeast China Plain and western Liaoning province, and the occurrence frequency of drylines is higher in the south than in the north. Most of the drylines are oriented along the southwest—northeast direction, with a width of 90—120 km and a length of 100—800 km. The annual average occurrence frequency of drylines in the warm season in Northeast China is 15.5%. The frequency of dryline occurrence shows no obvious interannual change, but the annual change is significant and presents a sinusoidal curve, with the peaks of more than 20% occurring from mid-late May to late June and mid-late August and the bottom of less than 10% occurring in July. The air pressure on wet side of the dryline is slightly higher than that on the dry side by 1 hPa, and the temperatures on both sides are mostly above 24℃. The temperature difference between the two sides is generally between 1 and 4℃. The dew point gradient and specific humidity gradient ranges are 9.6—15℃/(100 km) and 4.5—8.3 g/(kg·100 km), respectively. The equivalent potential temperature gradient is about 9.6—19 K/(100 km). The time series of the above the elements and their gradient values on both sides of the dryline change significantly. The temperature and humidity on both sides and the gradient of humidity increase from May to August, while the absolute value of temperature gradient decreases. Among the total 286 drylines, 40% of the drylines triggered convection. In the middle and early June, the percentage of the drylines that can trigger convection is the highest, reaching up to more than 60%. Whether the dryline can trigger convection has little to do with its location. The humidity gradient of convective drylines is slightly larger than that of non-convective drylines. The most significant difference of sounding elements between non-convective drylines and convective drylines lies in the value of CAPE on the wet side. The former is below 1200 J/kg on the wet side, while the latter is above 1200 J/kg on the wet side, with the highest value reaching about 3000 J/kg.

     

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