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A Case Study of Heavy Precipitation Occurring in Continental Environment

A Case Study of Heavy Precipitation Occurring in Continental Environment. To investigate a case of a heavy winter precipitation event of 7 January 2002 that was a challenge to operational forecasters. John R. Gyakum, McGill Paul A. Sisson, NWS Ron McTaggart-Cowan, McGill

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A Case Study of Heavy Precipitation Occurring in Continental Environment

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  1. A Case Study of Heavy Precipitation Occurring in Continental Environment • To investigate a case of a heavy winter precipitation event of 7 January 2002 that was a challenge to operational forecasters. • John R. Gyakum, McGill • Paul A. Sisson, NWS • Ron McTaggart-Cowan, McGill • Garry Toth, Met Svc Canada • Peter Lewis, MSC • John K. Parker, MSC

  2. A Cooperative program for Operational Meteorology, Education, and Training (COMET) Cooperative Outreach Project Cold-Season Quantitative Precipitation Forecasting for the Burlington, Vermont Region National Weather Service Burlington, VT USA McGill University Montreal, QC, Canada

  3. Outline • Synoptic Overview • Diagnosis • Mesoscale Modelling using MC2 • Summary

  4. Synoptic Overview Summary • 12-18” Snowfall in 3-6hrs in narrow mesoscale band KALY-KVSF-KLEB • Little if any orographic enhancement • 16:1 Snow to water ratios • 3-4”/hr snowfall rates for ~3 hrs • Cloud to ground Lightning detected at KPOU. • Surface Low Track ACY-ISP-PVD-PYM • Intense Upper-level mesoscale trough

  5. Snowfall ending 12 UTC 7 Jan 02 3 inch 3 inch 3 inch 3 inch 6 inch KBTV 6 inch 12 inch 3 inch 3 inch KLEB 12 inch KVSF 12 inch 6 inch 12 inch

  6. 24-h Precipitation (in) ending 12 UTC 7 January 2002 KBTV

  7. Springfield VT ASOS (KVSF)0.80”= 12.0” Snow • KVSF 070654Z AUTO VRB04KT 2 1/2SM -SN BR BKN012 OVC021 00/M01 A2946 RMK AO2 SLP983 P0012 T00001006= • KVSF 070554Z AUTO 35004KT 1/4SM +SN FG OVC002 00/M01 A2949 RMK AO2 SLP990 P0020 60068 T00001006 10000 21011 56039= • KVSF 070454Z AUTO VRB03KT 1/2SM SN FG OVC003 00/M01 A2949 RMK AO2 SLP993 P0019 T00001006 400281033= • KVSF 070354Z AUTO 00000KT 1/4SM +SN FZFG OVC002 M01/M01 A2954 RMK AO2 SLP010 P0014 T10061006= • KVSF 070254Z AUTO 36003KT 1/2SM SN FZFG BKN003 OVC010 M01/M01 A2960 RMK AO2 PRESFR SLP032 P0008 60015 T10061011 58047= • KVSF 070154Z AUTO 00000KT 3/4SM -SN BR VV004 M01/M01 A2966 RMK AO2 SLP052 P0006 T10061011= • KVSF 070054Z AUTO 00000KT 1 1/2SM -SN BR OVC014 M01/M02 A2970 RMK AO2 SLP066 P0001 T10111017=

  8. Reflectivity (dbZ) 02-09 UTC 7 Jan 2002

  9. 03 UTC 7 January CG LightningRUC SLP METAR KPOU

  10. 500 hPa Heights at 00Z 7 Jan 2002 SLP 06 UTC

  11. Albany Sounding 00 UTC 7 Jan 2002

  12. ETA Analysis at 500 hPa

  13. ETA Analysis at 500 hPa

  14. ETA Analysis at 500 hPa

  15. ETA Analysis at 500 hPa

  16. ETA 36 hr Forecast From

  17. NCEP Short Range Ensemble Forecast (SREF) from 21 UTC 5 Jan 2002

  18. Mesoscale Modeling Model Description MC2 version 4.9.3 • Non-hydrostatic, semi-implicit time step, semi-Lagrangian advection • Kain-Fritsch Convective Paramertization(36km,12km) • Three one-way nest domains • (36km,12km,3km)

  19. 36km 12 km 3 km Nesting Strategy KBTV

  20. MC2 36-h Forecast 12-h Precipitation Accumulation (mm) valid 12 UTC 7 January 2002 36-km 12-km

  21. Precipitable Water (mm)24-h Forecast valid 00 UTC 7 Jan 2002 36-km 12-km

  22. Dynamic Tropopause (DT) • Defined as 1.5 Potential Vorticity unit surface • (where 1 PVU is 1.0 X 10-6 K m2 kg-1 s-1) • DT separates high PV air in the stratosphere from lower PV in the troposphere • Useful for a concise display of jets and upper troughs which usually are at a maximum at the DT • Advections of lower potential temperature (higher pressure) on the DT are favorable for cyclogenesis

  23. Potential Temperature (K) Dynamic Tropopause (DT;1.5 PVU)24-h Forecast valid 00 UTC 7 Jan 2002 36-km 12-km

  24. Dynamic Trop 21 – 03 UTC

  25. Dynamic Trop 21 – 03 UTC

  26. Dynamic Trop 21 – 03 UTC

  27. 500 hPa Heights Vorticity 21-03 UTC

  28. 500 hPa Heights Vorticity 21-03 UTC

  29. 500 hPa Heights Vorticity 21-03 UTC

  30. Coupling Index (CI) • Bosart and Lackmann MWR 1995 • Theta(Dyn Trop) – Theta-e (850hPa) • “…crude measure of tropospheric lapse rate” • “ …small positive or negative values indicate where deep convection is possible, given the existence of a suitable lifting mechanism.” • MC2 variation of CI • “Best” or most unstable CI using maximum theta sfc-850 hPa

  31. Coupling IndexTheta(DT) – Theta-e max(850hPa)00 UTC 7 January 2002 36-km 12-km

  32. Time Lapse CI

  33. Time Lapse CI

  34. Time Lapse CI

  35. Potential Vorticity (PVU) X-Section CYMX-KACKEquivalent Potential Temp (K) shaded27-hr fcst valid 3 UTC 7 Jan 2002 Lowering DT Convective Instability KLEB

  36. Poor? AWIPS substitutes • For CI use Showalter Index (SI) • Temp (500 hPa) – Temp (lifted from 850 hPa) • For DT use single1.5 PVU contours on multiple theta surfaces

  37. ETA Showalter Index3-hr fcst valid 0300 UTC 7 Jan 2002

  38. Summary • The 7 January 2002 Heavy Precipitation Event was a challenge to Operational Forecasters • Band of intense precipitation occurred north of forecasted precipitation maximum 24-36-h in advance • 12km MC2 captured important detail at the dynamic tropopause • Deep layer instability appeared to be important in location and intensity of precipitation • 36km MC2 did not capture this detail • Precipitable Water may have been deficient at 12-km and contributed to lower QPF

  39. Future Work • Nudge Precipitable Water near band location • Move 3km grid to the heavy precipitation area • Will use in a Warning Event Simulation for BTV forecasters in 2002 • Have forecasters look at the DT based Coupling Index to assess tropospheric stability • RUC use AWIPS Volume Browser Difference Function; other NCEP models DT grids soon? • Move MC diagnostics into AWIPS (via LDAD)

  40. McGill UniversityReal-Time MC2 • http://132.206.43.151:5080/realtime/ • Dynamic Tropopause and PV diagnostics • 00Z Initial time

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