Based on daily precipitation data, upper-air observation data and ERA5 hourly reanalysis data with 0.25°×0.25° resolution from 2010 to 2020, the rainstorms caused by the northwest vortex in Shaanxi are counted, and the characteristics of rainstorms caused by the northwest vortex with and without influence of typhoon are comparatively analyzed. The results show that the rainstorms caused by the northwest vortex in Shaanxi mostly occurred in July and August, and it occurred more in northern Shaanxi. The night rain characteristics of the rainstorms are obvious. The rainstorm intensity was stronger under influence of typhoon, and the falling area was to the north of two latitudes than that without influence of typhoon. The northwest vortex, which caused rainstorms in Shaanxi, was located at about 7-8 latitudes to the north of the ridge line of the western Pacific subtropical high. The northwest vortex had the dynamic characteristics of convergence at low level and divergence at high level. The upward motion of the northwest vortex was strengthened by the topographic forcing uplift, and the low-level water vapor transport and convergence provided favorable conditions for the occurrence of rainstorms caused by the northwest vortex. Under the influence of typhoon, the subtropical high was westward and northward, the water vapor and energy in the periphery of the typhoon were transported to the northwest vortex with the southwesterly low-level jet, the atmosphere at lower layer of the northwest vortex was convective instability, and the positive vorticity advection in front of the high trough and strong divergence on the right side of the high-level jet promoted the development and enhancement of the vortex, the strong updrafts on the south and east sides of the vortex triggered the release of unstable energy and formed strong frontogenesis in northern Shaanxi, the frontogenesis further enhanced the vertical movement on the south and east sides of the vortex, which caused heavy rainstorms on the south and east sides of the vortex. When there was no influence of typhoon, the subtropical high was eastward and southward, the southwest wind speed was smaller and the water vapor transport was weaker, the southwest wind in front of the plateau trough transported water vapor from the Bay of Bengal and the South China Sea to Shaanxi, the atmosphere at lower layer of the northwest vortex was stable, the strong updraft was located in the south of the vortex, the cold and warm air converged in central and southern Shaanxi, which resulted in scattered weak frontogenesis and caused rainstorms in the south of the vortex center.

In order to get a deeper understanding of the water vapor characteristics and sources of rainstorms in semi-arid areas in Northwest China, and improve the ability of rainstorm forecasting in this area, based on upper-air and surface observation data and European Centre for Medium-Range Weather Forecasts (ECMWF) fifth-generation global atmospheric reanalysis (ERA5) (0.25 × 0.25),the characteristics of water vapor transport and budget of two large-scale rainstorm processes with different intensities occurring in northern Shaanxi under different circulation on July 11 and August 9, 2022 were analyzed. Hybrid Single-Particle Lagrangian Integrated Trajectory (HYSPLIT) model was used to quantitatively analyze the source and contribution rate of water vapor. The results show that the high level trough, low level shear line and vortex and low level jet were the main influence systems of the rainstorm occurring on July 11. 700 hPa cyclonic convergence and 850 hPa low vortex strengthened and moved slowly, causing regional rainstorms. The short-wave trough and low-level shear line were the main influence systems of the rainstorm process on August 9, and the secondary circulation on both sides of the shear line lifted the warm and humid air flow outside the West Pacific Subtropical High (referred to as "West Pacific Sub-high") triggering the release of unstable energy and forming a large-scale convective rainstorm weather. On July 11, the vertically integrated water vapor fluxes from ground to 300 hPa was stronger, 700 hPa southwest jet and the 850 hPa southeast jet formed two obvious water vapor transport belts. The strong convergence lasted longer, the wet layer was deep and the weather process was dominated by stable precipitation. On August 9, under the control of subtropical high, the atmosphere over northern Shaanxi had high temperature and humidity, and the total amount of precipitable water was large. The water vapor transport was weak and the strong convergence maintenance time was short, the wet layer was thinner, but the energy was sufficient, the weather process was dominated by convective precipitation. On July 11, the water vapor net income mainly came from the ground to 500 hPa, of which accounted for 52% during 800-500 hPa. The water vapor income of the eastern boundary below 800 hPa increased rapidly during the precipitation intensification stage and the combination of increased zonal income and strong meridional income keeps the regional net income at a high value, resulting in regional heavy rain. On August 9, almost all of the water vapor net income came from meridional income, and the water vapor net income mainly came from the ground to 800 hPa (accounting for 88%). The 700 hPa shear line moving southward and the convergence in the north of Yulin increased, reduced the outflow of the southerly wind, significantly increased the meridional income of water vapor, and strengthens the rainstorm. Water vapor backward trajectories with HYSPLIT model showed that on July 11, water vapor mainly came from tropical oceans, and the South China Sea contributed the most, the local and surrounding near surface atmosphere with high specific humidity also contributed significantly. On August 9, the water vapor mainly came from the high specific humidity atmosphere in the near-surface layer of the inland, followed by the South China Sea.

Based on conventional sounding observation data, ground encryption observation data and EC-interim reanalysis data with high resolution (0.25°×0.25°), the rainstorm process in northern and central part of Shaanxi Province during August 21-22, 2018 was comprehensively analyzed. The precipitation forecast based on the model was tested, and comparison of circulation conditions, water vapor conditions, energy conditions and instability mechanism of the heavy rainfall in the northern Shaanxi and the western part of the Guanzhong plain was focused on. The results show that cold air brought by the plateau trough and warm air brought by the subtropical high met in the central part of Shaanxi, which provided a favorable circulation background for the heavy rainfall. The shear line on 700 hPa provided a dynamic uplift condition for rainfall. The northwest cold front in the Hexi Corridor moved southward. The stable precipitation behind the cold front dominated in  the northern Shaanxi, while the convective precipitation triggered by the cold front dominated in Guanzhong area. During the rainstorm, the water vapor transport was weak, the local water vapor content was high, and the vertical gradient of humidity in western part of the Guanzhong plain was large, which was conducive to enhancement of convection and increase of rainfall intensity. Before the rainstorm, there were obvious convective instability in the middle and lower layers in western and central part of the Guanzhong plain and the convective effective potential energy (CAPE) was larger. Weak cold air triggered release of unstable energy in the Guanzhong plain and produced further convective rainstorm. However, there was a neutral stratification with weak unstable energy in northern Shaanxi. Conditionally symmetrical instability in the middle and lower layers resulted in strong oblique updraft, heavy rain and rainstorm. The frontogenesis of cold and warm air intersection in the Guanzhong plain was the triggering mechanism of convective rainstorm in this area. For large-scale precipitation, the forecast based on the model was stronger, but for convective precipitation, the  forecast  based on the model was weaker.

Based on the routine upper level and surface meteorological observation data, the temperature of black body(TBB) data from FY-2G satellite and ECWMF dataset with a spatial resolution of 0.125°×0.125°, a regional snowstorm occurring in Shaanxi Province on 3 January 2018 was analyzed. The results show that the regional snowstorm occurred under the background of 500 hPa deep trough caused by cut-off low, 700 hPa southwest jet and 850 hPa easterly air flow. The efficient water vapor from Bay of Bengal and East China Sea was transited by strong low level southwest jet and easterly air flow, respectively, which was one of the main causes of the snowstorm. The intrusion of cold flow in middle level was the main trigger mechanism. Strong upward motion caused by the upper level divergence and low level convergence and the development and maintenance of positive vorticity in middle and low level were the dynamic mechanism of the snowstorm. The meso-β scale convective cloud cluster with minimum TBB  of -50 ℃ developed in the process of eastward moving of convective cloud cluster with the length of 1100 km, the width of 40 km and TBB equal to or less than -40 ℃, which caused the short-time heavy snowfall with precipitation intensity more than or equal to 2 mm·h-1. As an elevated convection case, the updraft increased due to the slantwise convection triggered by conditional symmetric instability. The echo band was parallel to 0-6 km vertical wind shear, and the snow area was consistent with the moving direction of the flow.