CONVECTION IN TROPICAL CYCLONES John Molinari and David Vollaro University at Albany, SUNY Northeast Tropical Conference Rensselaerville, NY June 2009.

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Presentation transcript:

CONVECTION IN TROPICAL CYCLONES John Molinari and David Vollaro University at Albany, SUNY Northeast Tropical Conference Rensselaerville, NY June 2009

Distribution of the potential for severe cells in tropical cyclones using CAMEX dropsondes Application to Tropical Storm Gabrielle (2001)

Molinari and Vollaro (2008): used CAMEX sondes to evaluate the environment of intense local cells in Hurricane Bonnie (1998) using midlatitude convective parameters EHI: energy-helicity index Empirical index for predicting supercells (and tornadoes) in midlatitudes EHI is the product of normalized cell-relative helicity (0-3 km) and normalized CAPE

Hurricane Bonnie study has been repeated for all CAMEX storms Next: distribution of EHI with respect to the center of all tropical cyclones sampled by dropsondes in the CAMEX experiments, rotated with respect to ambient vertical wind shear, for large and small ambient shear.

SHEAR Distribution of EHI values with respect to ambient wind shear in CAMEX-observed tropical cyclones. Left panel: small ambient shear. Right panel: large ambient shear. Gray circles: severe cells unlikely. Red circles: likelihood grows with circle diameter. AMBIENT SMALL SHEAR <10 M/S LARGE SHEAR ≥10 M/S r = 400 km

Infrared satellite image at 0715 UTC 14 September. Also shown are Air Force reconnaissance 850 hPa winds ( UTC) and cloud- to-ground lightning flashes from UTC. Surface winds are at 0700 UTC. TROPICAL STORM GABRIELLE (2001)

Potential vorticity and winds on the  = 350K surface at 0000 UTC 14 September 2001.

Potential vorticity and winds on the  = 350K surface at 1200 UTC 14 September 2001.

Infrared satellite image (colors) at 1800 UTC 13 September Red shading indicates Tb < -72ºC. Yellow numbers indicate 0-3 km helicity values (m 2 s -2 ) calculated from ECMWF analyses at the same time. The hurricane symbol shows the best track center.

Same as previous, but for 6 hours later, at 0000 UTC 14 September.

Same as previous, but for an additional 6 hours later, at 0600 UTC 14 September. The asterisk indicates the location of center reformation less than three hours later. Reconnaissance aircraft found a 972 hPa pressure at that point, 20 hPa lower than 3 hours before.

Next: radar reflectivity from Tampa, 70 km northeast of the newly developing center Focused on area of asterisk in previous image Circles will indicate mesocyclones detected by the automated radar algorithm Entire image is about 60 km across 5 minutes of lightning is shown by + signs (positive cloud-to-ground flash) and – signs (negative C-G flash)

mesocyclone ζ = 2.9 X s -1 z= 2-7 km; D = 10km

ζ = 2.8 X s -1 D = 14 km

Schematic supercell from Lemon and Doswell (1979) 20 dBZ contour

TS Gabrielle summary Upper trough approached a weak tropical storm Ambient shear increased, and in-up-out flow strengthened downshear As a direct result, helicity rose downshear Long-lived cells developed in the same region One of these cells appeared to become the location of a center reformation