Effect of Water Vapor Transport on a Typical Rainstorm Process in the Arid Region of Southern Xinjiang: Observations and Numerical Simulations
Abstract
:1. Introduction
2. Materials and Methods
2.1. Data Introduction
2.1.1. Study Area
2.1.2. Ground Observation Data
2.1.3. Reanalysis Data
2.1.4. Satellite Data
2.2. Model and Methods
2.2.1. Water Vapor Flux
2.2.2. WRF Model
3. Results
3.1. Precipitation Overview
3.2. Large-Scale Circulation Background
3.3. Physical Mechanism Analysis
3.4. Mesoscale Features
3.5. Analysis of Water Vapor Characteristics
3.6. Numerical Simulation
3.6.1. WRF Simulation Result Verification
3.6.2. Water Vapor Influence and Mechanism Analysis
4. Conclusions and Discussion
- (1)
- The rainstorm weather in southern Xinjiang occurred in 100 hPa South Asian high pressure was “east high west low” double distribution with a large-scale circulation background, 200 hPa high altitude southwest jet, 500 hPa Upper the Lake Balkhash vortex, the Iranian and the Ural Mountains have a ridge of high pressure, at 700 hPa there are troughs and wind shear, and the ground convergence led to the rainstorm. The configuration of low-level convergence and high-level divergence and the vertical upward motion provide favorable dynamic conditions for the rainstorm. The high temperature and high humidity at low levels are favorable for the establishment and maintenance of convectively unstable layer junctions over the rainstorm area. The TBB low value corresponds well with the rainfall fallout area.
- (2)
- The water vapor from heavy rainfall came primarily from the Black Sea, the Caspian Sea, the Aral Sea, the Arabian Sea, the Bay of Bengal, and Central Asia; the moisture arrived in the Southland Basin with a westerly, southwesterly, and easterly path. The northern, western, and southern boundaries show a net inflow, and the eastern boundary is a net outflow. Water vapor is mainly imported into the southern basin from 500 to 300 hPa at the southern boundary and 700–500 hPa at the western, northern, and eastern boundaries, and exported from 500 to 300 hPa at the eastern boundary.
- (3)
- Changes in water vapor content have a strong influence on the intensity and extent of precipitation, with the southern boundary water vapor transport contributing the most to precipitation during this storm. When water vapor increases (decreases) in the storm area, upward motion is enhanced (weakened), low-level convergence upper-level dispersion is enhanced (weakened), water vapor transport to the middle and upper levels increases (decreases), and precipitation increases (decreases).
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Physical Parameter | Namelist Variable | Model/Scheme |
---|---|---|
Microphysics | mp_physics | WRF Single-Moment 6-class scheme |
Longwave radiation | ra_lw_physics | RRTMG scheme |
Shortwave radiation | ra_sw_physics | RRTMG scheme |
Surface Layer | sf_sfclay_physics | MM5 similarity |
Land surface | sf_surface_physics | Noah Land Surface Model |
Planetary Boundary layer | bl_pbl_physics | Yonsei University scheme |
Cumulus Parameterization | cu_physics | Kain–Fritsch scheme |
Test Name | Test Scheme |
---|---|
Control | Control test |
Sense_E | Shut down the water vapor transport at the eastern boundary |
Sense_W | Shut down the water vapor transport at the western boundary |
Sense_S | Shut down the water vapor transport at the southern boundary |
Sense_N | Shut down the water vapor transport at the northern boundary |
Sense_0.25Q | The entire layer of water vapor in the entire area is reduced to 25% of the original |
Sense_0.5Q | The entire layer of water vapor in the entire area is reduced to 50% of the original |
Sense_1.5Q | The entire layer of water vapor in the entire area is increased to 150% of the original |
Sense_2Q | The entire layer of water vapor in the entire area is increased to 200% of the original |
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Jin, C.; He, Q.; Huang, Q. Effect of Water Vapor Transport on a Typical Rainstorm Process in the Arid Region of Southern Xinjiang: Observations and Numerical Simulations. Remote Sens. 2023, 15, 4082. https://doi.org/10.3390/rs15164082
Jin C, He Q, Huang Q. Effect of Water Vapor Transport on a Typical Rainstorm Process in the Arid Region of Southern Xinjiang: Observations and Numerical Simulations. Remote Sensing. 2023; 15(16):4082. https://doi.org/10.3390/rs15164082
Chicago/Turabian StyleJin, Chen, Qing He, and Qian Huang. 2023. "Effect of Water Vapor Transport on a Typical Rainstorm Process in the Arid Region of Southern Xinjiang: Observations and Numerical Simulations" Remote Sensing 15, no. 16: 4082. https://doi.org/10.3390/rs15164082
APA StyleJin, C., He, Q., & Huang, Q. (2023). Effect of Water Vapor Transport on a Typical Rainstorm Process in the Arid Region of Southern Xinjiang: Observations and Numerical Simulations. Remote Sensing, 15(16), 4082. https://doi.org/10.3390/rs15164082