Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 14-Day Trial for You or Your Team.

Learn More →

Reconstruction of Thermodynamic Cycles in a High-Resolution Simulation of a Hurricane

Reconstruction of Thermodynamic Cycles in a High-Resolution Simulation of a Hurricane AbstractThe relationship between energy transport and kinetic energy generation in a hurricane is analyzed. The hydrological cycle has a negative impact on the generation of kinetic energy. First, in a precipitating atmosphere, mechanical work must also be expended in order to lift water. Second, the injection of water vapor at low relative humidity and its removal through condensation and precipitation reduces the ability of a thermodynamic cycle to generate work. This reduction can be directly quantified in terms of the change in the Gibbs free energy between the water added and removed.A newly developed approach—namely, the mean airflow as Lagrangian dynamics approximation— is used to extract thermodynamic cycles from the standard output of a numerical simulation of a hurricane. While convection in the outer rainbands is inefficient at producing kinetic energy, the deepest overturning circulation associated with the rising air within the eyewall is an efficient heat engine that produces about 70% as much kinetic energy as a comparable Carnot cycle. This confirms that thermodynamic processes play a central role in hurricane formation and intensification and that the thermodynamic cycles in a hurricane are characterized by high generation of kinetic energy that differ significantly from those found in atmospheric convection. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Journal of the Atmospheric Sciences American Meteorological Society

Reconstruction of Thermodynamic Cycles in a High-Resolution Simulation of a Hurricane

Download PDF
15 pages

Loading next page...
1
 
/lp/ams/reconstruction-of-thermodynamic-cycles-in-a-high-resolution-simulation-DdibcNwH4I

References

References for this paper are not available at this time. We will be adding them shortly, thank you for your patience.

Publisher
American Meteorological Society
Copyright
Copyright © American Meteorological Society
ISSN
1520-0469
DOI
10.1175/JAS-D-16-0353.1
Publisher site
See Article on Publisher Site

Abstract

AbstractThe relationship between energy transport and kinetic energy generation in a hurricane is analyzed. The hydrological cycle has a negative impact on the generation of kinetic energy. First, in a precipitating atmosphere, mechanical work must also be expended in order to lift water. Second, the injection of water vapor at low relative humidity and its removal through condensation and precipitation reduces the ability of a thermodynamic cycle to generate work. This reduction can be directly quantified in terms of the change in the Gibbs free energy between the water added and removed.A newly developed approach—namely, the mean airflow as Lagrangian dynamics approximation— is used to extract thermodynamic cycles from the standard output of a numerical simulation of a hurricane. While convection in the outer rainbands is inefficient at producing kinetic energy, the deepest overturning circulation associated with the rising air within the eyewall is an efficient heat engine that produces about 70% as much kinetic energy as a comparable Carnot cycle. This confirms that thermodynamic processes play a central role in hurricane formation and intensification and that the thermodynamic cycles in a hurricane are characterized by high generation of kinetic energy that differ significantly from those found in atmospheric convection.

Journal

Journal of the Atmospheric SciencesAmerican Meteorological Society

Published: Oct 12, 2017

References

  • Dissipative heating and hurricane intensity
    Bister, M.; Emanuel, K. A.
  • Rewriting the climatology of the tropical North Atlantic and Caribbean Sea atmosphere
    Dunion, J. P.
  • An air-sea interaction theory for tropical cyclones. Part I: Steady maintenance
    Emanuel, K. A.
  • Tropical cyclones
    Emanuel, K. A.
  • Constrained work output of the moist atmospheric heat engine in a warming climate
    Laliberté, F.; Zika, J.; Mudryk, L.; Kushner, P. J.; Kjellsson, J.; Döös, K.
  • Isentropic analysis of a simulated hurricane
    Mrowiec, A. A.; Pauluis, O. M.; Zhang, F.
  • Water vapor and mechanical work: A comparison of Carnot and steam cycles
    Pauluis, O.
  • The mean air flow as Lagrangian dynamics approximation and its application to moist convection
    Pauluis, O.
  • Entropy budget of an atmosphere in radiative–convective equilibrium. Part I: Maximum work and frictional dissipation
    Pauluis, O.; Held, I. M.
  • Entropy budget of an atmosphere in radiative–convective equilibrium. Part II: Latent heat transport and moist processes
    Pauluis, O.; Held, I. M.
  • Satellite estimates of precipitation-induced dissipation in the atmosphere
    Pauluis, O.; Dias, J.
  • Isentropic analysis of convective motions
    Pauluis, O.; Mrowiec, A.
  • Frictional dissipation in a precipitating atmosphere
    Pauluis, O.; Balaji, V.; Held, I. M.
  • An air–sea interaction theory for tropical cyclones. Part II: Evolutionary study using axisymmetric nonhydrostatic numerical model
    Rotunno, R.; Emanuel, K. A.
  • Effect of environmental shear, sea-surface temperature, and ambient moisture on the formation and predictability of tropical cyclones: An ensemble-mean perspective
    Tao, D.; Zhang, F.
  • Hurricane heat engines
    Willoughby, H. E.
  • Effects of vertical wind shear on the predictability of tropical cyclones
    Zhang, F.; Tao, D.