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Sensitivity of An Idealized Tropical Cyclone To The Configuration of The Global Forecast SYSTEM–EDDY Diffusivity Mass Flux Planetary Boundary Layer Scheme

Abstract

The intensity and structure of simulated tropical cyclones (TCs) are known to be sensitive to the planetary boundary layer (PBL) parameterization in numerical weather prediction models. In this paper, we use an idealized version of the Hurricane Weather Research and Forecast system (HWRF) with constant sea-surface temperature (SST) to examine how the configuration of the PBL scheme used in the operational HWRF affects TC intensity change (including rapid intensification) and structure. The configuration changes explored in this study include disabling non-local vertical mixing, changing the coefficients in the stability functions for momentum and heat, and directly modifying the Prandtl number (Pr), which controls the ratio of momentum to heat and moisture exchange in the PBL. Relative to the control simulation, disabling non-local mixing produced a ~15% larger storm that intensified more gradually, while changing the coefficient values used in the stability functions had little effect. Varying Pr within the PBL had the greatest impact, with the largest Pr (~1.6 versus ~0.8) associated with more rapid intensification (~38 versus 29 m s?1 per day) but a 5–10 m s?1 weaker intensity after the initial period of strengthening. This seemingly paradoxical result is likely due to a decrease in the radius of maximum wind (~15 versus 20 km), but smaller enthalpy fluxes, in simulated storms with larger Pr. These results underscore the importance of measuring the vertical eddy diffusivities of momentum, heat, and moisture under high-wind, open-ocean conditions to reduce uncertainty in Pr in the TC PBL.

Article / Publication Data
Active/Online
YES
Volume
12
Available Metadata
Accepted On
February 19, 2021
DOI ↗
Fiscal Year
NOAA IR URL ↗
Peer Reviewed
YES
Publication Name
Atmosphere
Published On
February 23, 2021
Final Online Publication On
February 23, 2021
Publisher Name
MDPI
Print Volume
12
Print Number
2
Page Range
284
Issue
2
Submitted On
January 26, 2021
Project Type
LAB SUPPORTED
URL ↗

Authors

Authors who have authored or contributed to this publication.

  • Evan A. Kalina - lead Gsl
    Cooperative Institute for Research in Environmental Sciences, University of Colorado Boulder
    NOAA/Global Systems Laboratory
  • Mrinal Biswas - second None
    National Center for Atmospheric Research
    1850 Table Mesa Drive, Boulder, Colorado
  • Jun A. Zhang - third Aoml
    Other
  • Kathryn M. Newman - fourth Ncar
    National Center for Atmospheric Research
    1850 Table Mesa Drive, Boulder, Colorado