The Microphysical Structure and Evolution of Hawaiian Rainband Clouds. Part I: Radar Observations of Rainbands Containing High Reflectivity Cores

Marcin J. Szumowski Department of Atmospheric Sciences, University of Illinois at Urbana–Champaign, Urbana, Illinois, andIllinois State Water Survey, Champaign, Illinois

Search for other papers by Marcin J. Szumowski in
Current site
Google Scholar
PubMed
Close
,
Robert M. Rauber Department of Atmospheric Sciences, University of Illinois at Urbana–Champaign, Urbana, Illinois

Search for other papers by Robert M. Rauber in
Current site
Google Scholar
PubMed
Close
,
Harry T. Ochs III Department of Atmospheric Sciences, University of Illinois at Urbana–Champaign, Urbana, Illinois, andIllinois State Water Survey, Champaign, Illinois

Search for other papers by Harry T. Ochs III in
Current site
Google Scholar
PubMed
Close
, and
L. J. Miller National Center for Atmospheric Research, Boulder, Colorado

Search for other papers by L. J. Miller in
Current site
Google Scholar
PubMed
Close
Restricted access

We are aware of a technical issue preventing figures and tables from showing in some newly published articles in the full-text HTML view.
While we are resolving the problem, please use the online PDF version of these articles to view figures and tables.

Abstract

Radar reflectivity factors exceeding 60 dBZ are documented within shallow (<3 km), warm (>0°C), summertime tropical rainbands offshore of the island of Hawaii. Dual-Doppler radar measurements from the Hawaiian Rainband Project are used to document the formation, evolution, and kinematic structure of the high reflectivity cores. The authors show that extremely high radar reflectivities (50–60 dBZ) can develop from echo free regions (−20 dBZ) within approximately 15 min and are preceded by 5–9 m s−1 peak updrafts. High reflectivities (>50 dBZ) typically first formed in the middle or upper part of the clouds. Over the next 10–15 min, the mature high reflectivity cores extended vertically through the cloud depth and then collapsed to the surface as the updrafts weakened. A near-upright orientation of most updrafts producing these high reflectivity cores is conceptually consistent with the idea that large raindrops grow in the highest liquid water content while falling through the updraft core. Strong outflows near the inversion led to the formation of sloped radar echo overhangs surrounding the cells. The bases of the overhangs descended to the surface with time, leading to an overall increase in the width of the rainbands. Short-lived downdrafts were present in the upper part of the clouds in mature and dissipating stages of cells’ life cycles but were not observed in the lower parts of the cloud, even in intense precipitation shafts.

Corresponding author address: Marcin J. Szumowski, Department of Atmospheric Sciences, University of Illinois at Urbana–Champaign, 105 S. Gregory, Urbana, IL 61801.

Abstract

Radar reflectivity factors exceeding 60 dBZ are documented within shallow (<3 km), warm (>0°C), summertime tropical rainbands offshore of the island of Hawaii. Dual-Doppler radar measurements from the Hawaiian Rainband Project are used to document the formation, evolution, and kinematic structure of the high reflectivity cores. The authors show that extremely high radar reflectivities (50–60 dBZ) can develop from echo free regions (−20 dBZ) within approximately 15 min and are preceded by 5–9 m s−1 peak updrafts. High reflectivities (>50 dBZ) typically first formed in the middle or upper part of the clouds. Over the next 10–15 min, the mature high reflectivity cores extended vertically through the cloud depth and then collapsed to the surface as the updrafts weakened. A near-upright orientation of most updrafts producing these high reflectivity cores is conceptually consistent with the idea that large raindrops grow in the highest liquid water content while falling through the updraft core. Strong outflows near the inversion led to the formation of sloped radar echo overhangs surrounding the cells. The bases of the overhangs descended to the surface with time, leading to an overall increase in the width of the rainbands. Short-lived downdrafts were present in the upper part of the clouds in mature and dissipating stages of cells’ life cycles but were not observed in the lower parts of the cloud, even in intense precipitation shafts.

Corresponding author address: Marcin J. Szumowski, Department of Atmospheric Sciences, University of Illinois at Urbana–Champaign, 105 S. Gregory, Urbana, IL 61801.

Save
  • Austin, G., R. M. Rauber, H. T. Ochs III, and L. J. Miller, 1996: Trade wind clouds and Hawaiian rainbands. Mon. Wea. Rev.,124, 2126–2151.

  • Beard, K. V., D. B. Johnson, and D. Baumgardner, 1986: Aircraft observations of large raindrops in warm, shallow, convective clouds. Geophys. Res. Lett.,19, 991–994.

  • Chong, M., and J. Testud, 1983: Three-dimensional wind field analysis from dual-Doppler radar data. Part III: The boundary condition: An optimum determination based on a variational concept. J. Climate Appl. Meteor.,22, 1227–1241.

  • Fujiwara, M., 1967: Raindrop-size distribution in warm rain as measured in Hawaii. Tellus,19, 393–402.

  • Lavoie, R. L., 1967: Background data for the warm rain project. Tellus,19, 348–353.

  • List, R. L., and J. R. Gillespie, 1976: Evolution of raindrop spectra with collision-induced breakup. J. Atmos. Sci.,33, 2007–2013.

  • Low, T. B., and R. List, 1982: Collision, coalescence, and breakup of raindrops. J. Atmos. Sci.,39, 1591–1618.

  • Miller, L. J., and R. G. Strauch, 1974: A dual-Doppler radar method for the determination of wind velocities within a precipitating weather systems. Remote Sens. Environ.,3, 219–235.

  • ———, J. E. Dye, and B. E. Martner, 1983: Dynamical–microphysical evolution of a convective storm in a weakly sheared environment. Part II: Airflow and precipitation trajectories from Doppler radar observations. J. Atmos. Sci.,40, 2097–2109.

  • ———, C. G. Mohr, and A. J. Weinheimer, 1986: The simple rectification to Cartesian space of folded radial velocities from Doppler radar sampling. J. Atmos. Oceanic Technol.,3, 162–174.

  • Mohr, C. G., and R. L. Vaughan, 1979: An economical procedure for Cartesian interpolation and display of reflectivity data in three-dimensional space. J. Appl. Meteor.,18, 661–670.

  • ———, L. J. Miller, R. L. Vaughan, and H. W. Frank, 1986: The merger of mesoscale datasets into a common Cartesian format for efficient and systematic analyses. J. Atmos. Oceanic Technol.,3, 143–161.

  • Mordy, W. A., and L. E. Eber, 1954: Observations of rainfall from warm clouds. Quart. J. Roy. Meteor. Soc.,80, 48–57.

  • Rauber, R. M., K. V. Beard, and B. M. Andrews, 1991: A mechanism for giant raindrop formation in warm, shallow, convective clouds. J. Atmos. Sci.,48, 1791–1797.

  • Ray, P. S., K. K. Wagner, K. W. Johnson, J. J. Stephens, W. C. Bumgarner, and E. A. Mueller, 1978: Triple-Doppler observations of a convective storm. J. Appl. Meteor.,17, 1201–1212.

  • ———, C. L. Ziegler, W. C. Bumgarner, and R. J. Serafin, 1980: Single- and multiple-Doppler radar observations of tornadic storms. Mon. Wea. Rev.,108, 1607–1625.

  • Rogers, R. R., 1967: Doppler radar investigation of Hawaiian rain. Tellus,19, 433–455.

  • Semonin, F. G., E. A. Mueller, G. A. Stout, and D. W. Staggs, 1968: Radar analysis of warm rain showers. Tellus,20, 227–238.

  • Squires, P., 1952a: The growth of cloud drops by condensation I. General characteristics. Aust. J. Sci. Res.,5, 59–86.

  • ———, 1952b: The growth of cloud drops by condensation II. The formation of large cloud drops. Aust. J. Sci. Res.,5, 473–499.

  • ———, 1958a: The microstructure and colloidal stability of warm clouds. Part I. The relation between structure and stability. Tellus,10, 256–261.

  • ———, 1958b: The microstructure and colloidal stability of warm clouds. Part II. The causes of the variations in the microstructure. Tellus,10, 262–271.

  • Takahashi, T., 1977: A study of Hawaiian warm showers based on aircraft observation. J. Atmos. Sci.,34, 1773–1790.

  • ———, 1981: Warm rain study in Hawaii—Rain initiation. J. Atmos. Sci.,38, 347–369.

  • ———, K. Yoneyama, and Y. Tsubota, 1989: Rain duration in Hawaiian trade wind rainbands—Aircraft observation. J. Atmos. Sci.,46, 937–955.

All Time Past Year Past 30 Days
Abstract Views 0 0 0
Full Text Views 420 177 48
PDF Downloads 123 27 2