1 / 47

Heavy Rain Climatology of Upper Michigan

Heavy Rain Climatology of Upper Michigan. Jonathan Banitt National Weather Service Marquette MI. What will be covered. Overview of Heavy Rainfall events in Upper Michigan Study Methodology Brief case study Examples of each pattern type associated with heavy rainfall

xannon
Download Presentation

Heavy Rain Climatology of Upper Michigan

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Heavy Rain Climatology of Upper Michigan Jonathan Banitt National Weather Service Marquette MI

  2. What will be covered • Overview of Heavy Rainfall events in Upper Michigan • Study Methodology • Brief case study Examples of each pattern type associated with heavy rainfall • Composites of Patterns from NCEP/NCAR Reanalysis data

  3. Top Rainfall Events In Coop Site Records (1888 to present)Greatest amounts in 24 hour reporting period Location Date Amount • Ironwood 21 July 1909 6.72 inches (171 mm) • Ironwood 17 July 1942 6.70 inches (170 mm) • Big Bay 12 May 2006 5.93 inches (151 mm) • Ironwood 1 November 1909 5.61 inches (142 mm) • Kenton 14 July 1980 5.45 inches (138 mm) • Ishpeming 29 July 1949 5.35 inches (136 mm) • Grand Marais 26 October 1905 5.27 inches (134 mm) • Stambaugh 15 July 1999 5.20 inches (132 mm) • Marquette 12 May 2006 5.12 inches (130 mm) • Grand Marais 7 May 1908 5.08 inches (129 mm) • Ironwood 22 July 1909 5.00 inches (127 mm)

  4. Location of observation sites used in the study

  5. Events at each station(1966-2009) 24 hour rainfall amounts of 2.00 inches (51mm) or greater

  6. Events at selected stations by month

  7. Methodology • 19 Sites used that had continuous data during the period from 1966 through 2009 • Rainfall events (rainfall amount of 2.00 inches or greater during a 24 period) obtained by query of Midwest Climate Center database • Case designated if 2.00 inch or greater rainfall observed at two or more of the 19 designated sites. Cases on consecutive days were consolidated. • Characteristics of each case were examined using NCEP/NCAR 6-hour reanalysis data and Daily Weather Maps • Time of case (6 hourly) was determined when the precipitable water and instability values were greatest • Cases could be classified similar to types described by Maddox (1979) in flash flood study. One additional type was designated.

  8. Maddox Synoptic Type Flash Flood Event (Type 1) Surface 850 mb 500 mb Maddox, et al. (1979)

  9. Type 1 case 24 April 2002 • Strong progressive mid level trough • North-South oriented surface front • Heavy rain occurred to the east (in the warm sector) ahead of the front

  10. 4/24/02 12z 500 mbObs, Heights, Temps

  11. 4/25/02 00z 500 mbObs, Heights, Temps

  12. 4/24/02 12z Surface Pressure and Obs

  13. 4/25/02 00z Surface Pressure and Obs

  14. Composite Radar Loop 4/24/02 09z to 4/25/02 03z(image interval 1 hour)

  15. Rainfall amounts (inches)

  16. Maddox Frontal Type Flash Flood Event (Type 2) Surface 850 mb 500 mb Maddox, et al. (1979)

  17. Type 2 case 4 September 2007 • West northwest mid level flow • West-East oriented surface frontal system extending from low pressure over the northern plains • Heavy rain occurred to the north or cool side of the front • Frontogenesis played a large role

  18. 9/4/07 00z IR Satellite, 500 mb height, MSL

  19. IR Satellite and 1 hour lightning loop 9/4/07 00z-18z(image interval 1 hour)

  20. Composite Radar Loop 9/04/07 00z to 18z(image interval 1 hour)

  21. Rainfall amounts (inches)

  22. 9/4/07 09z 00 RUC 00 hr fcst850 mb wind, temp, dewpoint and 2-D Frontogenesis(image) 14 16

  23. 9/04/07 09z RUC 00 hr fcst Cross Section 2D-Frontogenesis(image), Theta, ageo vertical circulation 600 700 850 41 NW CMX

  24. Type 3 • Strong surface low • Heavy rain to the left of the surface low track • 850-500 mbFrontogenesis / deformation region • Trowal often present • Terrain enhancement often plays a role L

  25. Type 3 case 10 to 13 May 2003 • Strong mid level trough deepened to a closed low • Intensifying and occluding surface low moved to the northeast through central Wisconsin into eastern Upper Michigan • Heavy rain occurred to the left of the low track typical of cold season precipitation events • Trowal region developed and significant orographic enhancement occurred over north central Upper Michigan during the last half of the event

  26. IR Satellite loop 05/10/03 06z to 05/13/03 00z500 mb, surface analysis (image interval 6 hours)

  27. Composite Radar Loop 05/10/03 18z to 05/12/03 22z(image interval 2 hours)

  28. 300K Surface 5/11/03 06z to 18z Eta fcst300K omega, pressure, streamlines (image interval 3 hours)

  29. Precipitation from 5/10/03 to 5/13/03

  30. Upper Michigan Topographymin 578 ft (176m) max 1979 ft (603m)

  31. Impacts from May 2003 heavy rain event

  32. Heavy Rain Cases Type 2 (34 Cases) Type 1 (24 Cases) Type 3 (15 Cases) 1969 06 27 00Z 1969 08 07 06Z 1970 09 21 12Z 1970 10 28 06Z 1972 06 20 06Z 1973 08 30 00Z 1976 08 11 18Z 1977 08 31 06Z 1978 08 16 00Z 1979 06 15 18Z 1979 07 25 06Z 1983 08 19 12Z 1983 09 04 18Z 1987 07 12 00 Z 1987 08 13 00Z 1990 06 12 06Z 1991 10 29 06Z 1993 07 06 00Z 1993 09 14 00Z 1983 10 11 18Z 1985 11 01 18Z 2002 04 24 12Z 2002 08 01 00Z 2003 09 14 00z 1985 09 03 06Z 1987 08 01 12Z 1988 08 02 12Z 1988 08 17 06Z 1989 06 07 18Z 1990 08 18 06Z 1991 07 29 06Z 1992 07 02 06Z 1999 07 09 06Z 1999 07 15 00Z 2000 07 27 06Z 2005 07 24 06Z 2005 09 19 18Z 2005 10 05 00Z 2007 09 04 12Z 2007 09 21 12Z 2007 10 06 06Z 1966 10 15 06Z 1970 05 31 00Z 1970 07 19 12Z 1970 09 02 12Z 1972 08 16 12Z 1972 09 26 06Z 1975 08 28 12Z 1977 07 14 12Z 1977 11 03 00Z 1978 07 20 00Z 1978 08 23 06Z 1978 09 11 06Z 1980 08 21 00Z 1981 06 14 06Z 1981 08 02 18Z 1982 08 03 12Z 1985 04 19 12Z 1967 10 08 12Z 1967 10 25 00Z 1973 05 01 12Z 1976 05 16 06Z 1978 05 13 00Z 1979 10 22 06Z 1982 07 11 06Z 1983 05 29 06Z 1985 10 04 18Z 1986 10 12 06Z 1992 11 21 00Z 2003 05 11 06Z 2004 05 23 18Z 2006 05 12 00Z 2009 05 28 06Z

  33. Cases each month(73 total)

  34. Type by month

  35. Moisture and instability characteristics(maximum values during the 24 hour period) Type 1 Mean precipitable water 39.9 mm Standard deviation 6.7 Mean best 4-layer lifted index -2.3 Standard deviation 2.3 Type 2 Mean precipitable water 39.3 mm Standard deviation 6.4 Mean best 4-layer lifted index -2.5 Standard deviation 2.1 Type 3 Mean precipitable water 29.5 mm Standard deviation 6.2 Mean best 4-layer lifted index 2.4 Standard deviation 2.1

  36. ESRL Composites web site

  37. MSLP Composite Mean Type 1 Type 2 Type 3

  38. 500 mb Composite Mean (m) Type 1 Type 2 Type 3

  39. 500 mb Composite Anomaly Type 1 Type 2 Type 3

  40. 250 mb vector wind Composite Mean (m/s) Type 1 Type 2 Type 3

  41. 700 mb Specific Humidity Composite Mean (Kg/Kg) Type 1 Type 2 Type 3

  42. 700 mb SH Composite Anomaly Type 1 Type 2 Type 3

  43. 850 mb Specific Humidity Composite Mean Type 1 Type 2 Type 3

  44. 850 mb SH Composite Anomaly Type 1 Type 2 Type 3

  45. 850 mb vector wind Composite Mean Type 1 Type 2 Type 3

  46. Precipitable Water Composite Anomaly (mm) Type 1 Type 2 Type 3

  47. Summary • Heavy rainfall in Upper Michigan most likely in the late Summer and early Fall • Inland locations showed a more distinct mid Summer maximum compared to locations where stable lake influences were more dominant • Heavy Rainfall cases over Upper Michigan could be partitioned into three main pattern types • Composite analyses of each pattern type showed familiar large scale forcing signals • Low and Mid level moisture streams from the southwest were apparent • Pattern recognition and awareness of heavy rainfall characteristics unique to the local area can increase success in forecasting these relatively rare events

More Related