Publication Abstracts

Fridlind et al. 2019

Fridlind, A.M., M. van Lier-Walqui, S. Collis, S.E. Giangrande, R.C. Jackson, X. Li, T. Matsui, R. Orville, M.H. Picel, D. Rosenfeld, A. Ryzhkov, R. Weitz, and P. Zhang, 2019: Use of polarimetric radar measurements to constrain simulated convective cell evolution: A pilot study with Lagrangian tracking. Atmos. Meas. Tech., 12, 2979-3000, doi:10.5194/amt-12-2979-2019.

To probe the potential value of a radar-driven field campaign to constrain simulation of isolated convection subject to a strong aerosol perturbation, convective cells observed by the operational KHGX weather radar in the vicinity of Houston, Texas, are examined individually and statistically. Cells observed in a single case study of onshore flow conditions during July 2013 are first examined and compared with cells in a regional model simulation. Observed and simulated cells are objectively identified and tracked from observed or calculated positive specific differential phase (KDP) above the melting level, which is related to the presence of supercooled liquid water. Several observed and simulated cells are subjectively selected for further examination. Below the melting level, we compare sequential cross sections of retrieved and simulated raindrop size distribution parameters. Above the melting level, we examine time series of KDP and radar differential reflectivity (ZDR) statistics from observations and calculated from simulated supercooled rain properties, alongside simulated vertical wind and supercooled rain mixing ratio statistics. Results indicate that the operational weather radar measurements offer multiple constraints on the properties of simulated convective cells, with substantial value added from derived KDP and retrieved rain properties. The value of collocated three-dimensional lightning mapping array measurements, which are relatively rare in the continental US, supports the choice of Houston as a suitable location for future field studies to improve the simulation and understanding of convective updraft physics. However, rapid evolution of cells between routine volume scans motivates consideration of adaptive scan strategies or radar imaging technologies to amend operational weather radar capabilities. A 3-year climatology of isolated cell tracks, prepared using a more efficient algorithm, yields additional relevant information. Isolated cells are found within the KHGX domain on roughly 40% of days year-round, with greatest concentration in the northwest quadrant, but roughly 5-fold more cells occur during June through September. During this enhanced occurrence period, the cells initiate following a strong diurnal cycle that peaks in the early afternoon, typically follow a south-to-north flow, and dissipate within 1 h, consistent with the case study examples. Statistics indicate that ∼ 150 isolated cells initiate and dissipate within 70 km of the KHGX radar during the enhanced occurrence period annually, and roughly 10 times as many within 200 km, suitable for multi-instrument Lagrangian observation strategies. In addition to ancillary meteorological and aerosol measurements, robust vertical wind speed retrievals would add substantial value to a radar-driven field campaign.

Export citation: [ BibTeX ] [ RIS ]

BibTeX Citation

  author={Fridlind, A. M. and van Lier-Walqui, M. and Collis, S. and Giangrande, S. E. and Jackson, R. C. and Li, X. and Matsui, T. and Orville, R. and Picel, M. H. and Rosenfeld, D. and Ryzhkov, A. and Weitz, R. and Zhang, P.},
  title={Use of polarimetric radar measurements to constrain simulated convective cell evolution: A pilot study with Lagrangian tracking},
  journal={Atmospheric Measurement Techniques},

[ Close ]

RIS Citation

ID  - fr05300j
AU  - Fridlind, A. M.
AU  - van Lier-Walqui, M.
AU  - Collis, S.
AU  - Giangrande, S. E.
AU  - Jackson, R. C.
AU  - Li, X.
AU  - Matsui, T.
AU  - Orville, R.
AU  - Picel, M. H.
AU  - Rosenfeld, D.
AU  - Ryzhkov, A.
AU  - Weitz, R.
AU  - Zhang, P.
PY  - 2019
TI  - Use of polarimetric radar measurements to constrain simulated convective cell evolution: A pilot study with Lagrangian tracking
JA  - Atmos. Meas. Tech.
JO  - Atmospheric Measurement Techniques
VL  - 12
SP  - 2979
EP  - 3000
DO  - 10.5194/amt-12-2979-2019
ER  -

[ Close ]

• Return to 2019 Publications

• Return to Publications Homepage