A simple parameterization of sea surface cooling beneath a hurricane inner core

1. Andrea Schumacher CIRA / CSU Mark DeMaria NOAA / NESDIS / STAR Isaac Ginis and Biju Thomas University of Rhode Island A simple parameterization of sea surface cooling beneath a hurricane inner core 28th Conference on Hurricanes and Tropical Meteorology, 5/2/08 17A.4

2. Outline • Motivation: hurricane-ocean feedback • Methodology & Data • Inner Core Parameters • Development of simple parameterization • Evaluation & Results • Summary & Future Work 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

3. Motivation Well observed that TCs impact upper ocean T structure Example: Cold wake (upwelling) Cold wake Rita 9/22/05 12 UTC (HWRF SST) 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

4. Motivation Also, upper ocean can have a significant impact on maintaining and/or modifying TC structure and intensity (Cione & Ulhorn, 2003) Example: SST-dependent MPI (DeMaria and Kaplan, 1994), Where T is SST, T0 is a specified reference temperature, and A, B, and C are constants. MPI = A + BC(T-T0) 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

5. Motivation Suggests Ocean / Hurricane Feedback Hurricane Surface Winds MPI Enthalpy Flux Convection ??? Upwelling ? Sea Surface Temperature 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

6. Motivation These effects most important in inner core region Cold Wake, dSST ~ 3-4º C Inner Core, dSST ~ 1 ºC Suggests Ocean / Hurricane Feedback Hurricane Surface Winds Cold wake MPI Enthalpy Flux Convection ??? Upwelling ? Inner Core Sea Surface Temperature 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

7. Cione & Ulhorn (2003) Even small dSST in the inner core region can lead to substantial changes in ocean heat content extracted and hence intensity Inner core enthalpy flux (sensible + latent), Hcore, related to upper-ocean heat content extracted by TC, QH,ext by: 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

8. Motivation (Cont…) • Forecasting TC intensity: Need to quantify dSSTIC • Very difficult to measure, sparse observations • Necessary to develop parameterization • Currently, Statistical Hurricane Intensity Prediction Scheme (SHIPS) includes a parameterization for dSSTIC • Developed from ??? • Depends on latitude, initial SST, & translational speed • Are there other storm and ocean-related parameters that should be included? 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

9. Approach • In lieu of observations, use the HWRF ocean-atmosphere coupled model fields • Explore possible statistical relationships between dSSTIC and (measurable) parameters • First step to consider a simple statistical relationship: multiple linear regression 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

10. Data • HWRF atmosphere-ocean coupled model • Grid spacing: approx. 0.19 °lon, 0.17 °lat • Domain: 98.5-50 °W, 10-47.5 °N • Reruns of named Atlantic storms from 2004-2006 • 35 of 55 named storms available in reruns • 491 forecast runs • Each run, used analysis and forecasts for t = 24, 48, 72, 96, and 120 h • Data fields used • Ocean temperature by depth • TC intensity • TC position 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

11. Parameters Only three independent parameters were considered for this preliminary study: • TC Intensity (Vmax) • Surface wind speed should directly correlate with magnitude of ocean upwelling beneath inner core • TC Translational Speed (Spd) • The more time a TC inner core spends over the same area of ocean, the more upwelling should occur • Ocean Heat Content (OHC) • The larger the ocean heat content, the deeper the ocean mixed layer, and hence the longer/stronger the upwelling needed to bring colder water to surface 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

12. OHC vs. Latitude HWRF-derived OHC 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

13. Inner Core Calculations • Inner core defined as area within 60 km radius of storm center (consistent with Cione and Ulhorn, 2003) • Averaged all points within area to calculate inner core value • If more than 10% of data points invalid (eg. over land), case not used • Data processing resulted in 1399 cases to be used in multiple regression 60 km 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

14. Regression Analysis • Dependent variable: dSSTIC = SSTIC(t=0) – SSTIC(t=t’) • All variables normalized before multiple regression • Regression coefficients: 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

15. Regression Analysis • Vmax positive  larger intensity, larger SSTIC cooling • Spd negative  faster moving, smaller SSTIC cooling • OHC negative  higher OHC, smaller SSTIC cooling 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

16. Evaluation • To test, parameterizations implemented in the SHIPS model • Run over developmental dataset (1982 – 2006) • Only times where altimetry-derived OHC available were used, 1995 – 2006 • 4 test runs • No parameterization • Current param (CP) • Linear param (LP) • Quadratic param (QP) 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

17. Evaluation (Cont…) • All parameterizations improve forecast skill after t = 24 h • CP shows greater improvement before t = 84 h • LP & QP show greater improvement at later forecast times * % forecast improvement is calculated in relation to using no dSSTIC parameterization at all in SHIPS. 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08

18. Summary / Future Work • In the HWRF model, Vmax, Spd and OHC all appear to have an impact on dSSTIC • Testing on SHIPS reanalysis data shows new parameterizations generally improve SHIPS forecast, especially at later forecast times • Current parameterization still outperforms at early forecast times  more work to be done • Physical motivation for new parameterizations is reasonable, keep working on improvements • Other parameters? • TC structure, wind radii • Thermocline depth 28th Conf on Hurricanes and Tropical Meteorology, 5.2.08