Your search keyword '"Hu, Jiaxi"' showing total 3 results

1. Tracking and characterization of convective cells through their maturation into stratiform storm elements using polarimetric radar and lightning detection.

Author

Hu, Jiaxi, Rosenfeld, Daniel, Zrnic, Dusan, Williams, Earle, Zhang, Pengfei, Snyder, Jeffrey C., Ryzhkov, Alexander, Hashimshoni, Eyal, Zhang, Renyi, and Weitz, Richard

Subjects

*RADAR, *LIGHTNING, *RADAR meteorology, *TRACKING algorithms, *TIME series analysis, *CELLS

Abstract

Polarimetric radars make it possible to retrieve information on hydrometeors types, sizes and concentrations. Additional information on cloud electrification can be obtained from Lightning Mapping Arrays (LMAs). To study the development time and height of the hydrometeors and electrification require tracking their evolution within the lifecycle of convective cells. A new methodology for multi-cell identification and tracking (MCIT) is presented in this study. The algorithm in this study is different from traditional tracking methods; this new algorithm is applied to time series of radar volume scans. It tracks local maxima of vertically integrated liquid (VIL) water by identifying the two cells in consecutive radar scans that have maximum common VIL. The vertical profile of the polarimetric variables is used for constructing the time-height cross section of the cells' microphysical properties around the peak reflectivity as a function of height. The LMA sources that occur within the cell area are integrated as a function of height as well for each time step, as determined by the radar volume scans. The result of the tracking can provide insights on the evolution of storms, hydrometer types, precipitation initiation and cloud electrification under different thermodynamic and aerosol conditions. The details of the MCIT algorithm, its products and their performance for different type of storms are described in this paper. • Development of a novel cloud cell tracking algorithm. • Tracking cloud types include: convective and stratiform, isolated and clustered. • Tracking cloud cells through maturation into stratiform storm elements. • Use a synergy of polarimetric radar, satellite, lightning detection and model data. • Algorithm has flexible output options and possibilities for further studies. [ABSTRACT FROM AUTHOR]

Published

2019

2. Polarimetric Signatures in Landfalling Tropical Cyclones.

Author

Homeyer, Cameron R., Fierro, Alexandre O., Schenkel, Benjamin A., Didlake Jr., Anthony C., McFarquhar, Greg M., Hu, Jiaxi, Ryzhkov, Alexander V., Basara, Jeffrey B., Murphy, Amanda M., and Zawislak, Jonathan

Subjects

*TROPICAL cyclones, *WIND shear, *RADAR, *ATMOSPHERIC temperature, *HURRICANES, *ALTITUDES

Abstract

Polarimetric radar observations from the NEXRAD WSR-88D operational radar network in the contiguous United States, routinely available since 2013, are used to reveal three prominent microphysical signatures in landfalling tropical cyclones: 1) hydrometeor size sorting within the eyewall convection, 2) vertical displacement of the melting layer within the inner core, and 3) dendritic growth layers within stratiform regions of the inner core. Size sorting signatures within eyewall convection are observed with greater frequency and prominence in more intense hurricanes, and are observed predominantly within the deep-layer environmental wind shear vector-relative quadrants that harbor the greatest frequency of deep convection (i.e., downshear and left-of-shear). Melting-layer displacements are shown that exceed 1 km in altitude compared to melting-layer altitudes in outer rainbands and are complemented by analyses of archived dropsonde data. Dendritic growth and attendant snow aggregation signatures in the inner core are found to occur more often when echo-top altitudes are low (≤10 km MSL), nearer the −15°C isotherm commonly associated with dendritic growth. These signatures, uniquely observed by polarimetric radar, provide greater insight into the physical structure and thermodynamic characteristics of tropical cyclones, which are important for improving rainfall estimation and the representation of tropical cyclones in numerical models. [ABSTRACT FROM AUTHOR]

Published

2021

3. Distinct Impacts of Aerosols on an Evolving Continental Cloud Complex during the RACORO Field Campaign.

Author

Lin, Yun, Wang, Yuan, Pan, Bowen, Hu, Jiaxi, Liu, Yangang, and Zhang, Renyi

Subjects

*ATMOSPHERIC aerosols, *CONVECTION (Meteorology), *CLOUD dynamics, *THERMODYNAMICS, *LIGHT absorption

Abstract

A continental cloud complex, consisting of shallow cumuli, a deep convective cloud (DCC), and stratus, is simulated by a cloud-resolving Weather Research and Forecasting Model to investigate the aerosol microphysical effect (AME) and aerosol radiative effect (ARE) on the various cloud regimes and their transitions during the Department of Energy Routine Atmospheric Radiation Measurement Aerial Facility Clouds with Low Optical Water Depths Optical Radiative Observations (RACORO) campaign. Under an elevated aerosol loading with AME only, a reduced cloudiness for the shallow cumuli and stratus resulted from more droplet evaporation competing with suppressed precipitation, but an enhanced cloudiness for the DCC is attributed to more condensation. With the inclusion of ARE, the shallow cumuli are suppressed owing to the thermodynamic effects of light-absorbing aerosols. The responses of DCC and stratus to aerosols are monotonic with AME only but nonmonotonic with both AME and ARE. The DCC is invigorated because of favorable convection and moisture conditions at night induced by daytime ARE, via the so-called aerosol-enhanced conditional instability mechanism. The results reveal that the overall aerosol effects on the cloud complex are distinct from the individual cloud types, highlighting that the aerosol-cloud interactions for diverse cloud regimes and their transitions need to be evaluated to assess the regional and global climatic impacts. [ABSTRACT FROM AUTHOR]

Published

2016