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Horizontal divergence of typhoon-generated gravity waves in the upper troposphere and lower stratosphere (UTLS) and its influence on typhoon evolution

Atmospheric Chemistry and Physics (2014) 14(7) 3175-3182
DOI: 10.5194/acp-14-3175-2014
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Abstract

The characteristics of horizontal divergence induced by typhoon-generated gravity waves (HDTGWs) and the influence of HDTGW on typhoon evolution are investigated based on the simulation results of Typhoon Saomai (2006) using the Weather Research and Forecasting (WRF) model. The power spectral density of HDTGW shows dominant powers at horizontal wavelengths of 20-30 km and at periods of less than 1 h. This is associated with gravity waves generated by vigorous convective clouds in an inner core region of the typhoon. However, the domain-averaged HDTGW in the upper troposphere and lower stratosphere had a spectral peak at 24 h, which is well correlated with the minimum sea-level pressure of the typhoon, especially during a rapidly developing period. The 24 h period of the averaged HDTGW stems from the inertia-gravity waves generated by the convective clouds in the spiral rainbands, and showed no clear association with the thermal tides or the diurnal variation of precipitation. © Author(s) 2014.

Figures

  • Fig. 1. (a) Time–height cross section of the domain-averaged HDTGW from 12 to 18 km a.g.l. Dashed and solid lines denote negative (convergence) and positive (divergence) values, respectively. (b) Time series of total divergence at 16 km a.g.l. (red), HDTGW (blue) and minimum sea-level pressure (dot dashed). (c) Time series of HDTGW at 16 km a.g.l. (blue), domain-averaged vertical velocity averaged over 3 to 15 km a.g.l. (red dashed), and domainaveraged 30 min accumulated precipitation amount (brown). (d) Time–height cross section of the vertical mass transport. (e) The power spectral density (PSD) of the HDTGW with respect to frequency at selected heights from 14 to 17 km a.g.l.
  • Fig. 2. (a) HDTGW at 16 km a.g.l., (b) radar reflectivity at 400 hPa, (c) total horizontal divergence at 16 km a.g.l. at 03:00 UTC, 9 August, and (d) phase difference between the total horizontal divergence and HDTGW shown in (a) and (c). In (d), gray and white regions denote in phase and out of phase between (a) and (c), respectively. Note that blue color denotes cloud-covering area in (a), (c), and (d). (e) x–z cross section of zonal wind (contour) superimposed on HDTGW (shaded) at y = 600 km on 03:00 UTC, 9 August. Gray shaded region shows cloud-covering area. In (e), solid and dashed contours denote positive and negative values, respectively, with 6 m s−1 intervals from −21 m s−1 to 21 m s−1.
  • Fig. 3. PSDs of the HDTGW with respect to the (a) horizontal wavelength and (b) period in each propagation direction with 45◦ intervals at 16 km a.g.l.
  • Fig. 4. (a) Hovmöller diagram of azimuthally averaged precipitable water (PW) in the simulation of typhoon Saomai. Dashed and dotted lines in (a) denote locations of spectral analyses performed in (c) and (d), respectively. (b) The same as in (a) except for the vertical velocity (color) at 1.5 km a.g.l. superimposed on the horizontal wind speed at 1.5 km a.g.l. from 25 to 50 m s−1 with 5 m s−1 intervals. The power spectrum of PW with respect to frequency are shown at (c) 40 km and (d) 180 km from the typhoon center. Dashed and dotted lines in (c) and (d) represent red noise and the 95 % confidence level, respectively.
  • Fig. 5. (a) PSD of the HDTGW at 16 km a.g.l. with respect to the horizontal phase speed (radius) and propagation direction (azimuthal angle) in the total (left), inner core (middle), and outer rainbands (right) regions of D3. The inner core is defined by a 150 km radius from the typhoon center, and the outer rainband region is defined by a region subtracting the inner core region from D3. Two dashed rings in each circle in (a) represent phase speeds of 20 and 40 m s−1, respectively. Time–height cross sections of domainaveraged HDTGW in the inner core and outer rainband regions are shown in (b) and (c), respectively.

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APA

Kim, S. H., Chun, H. Y., & Jang, W. (2014). Horizontal divergence of typhoon-generated gravity waves in the upper troposphere and lower stratosphere (UTLS) and its influence on typhoon evolution. Atmospheric Chemistry and Physics, 14(7), 3175–3182. https://doi.org/10.5194/acp-14-3175-2014

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