TASK 3: Evaluating Observation Strategies Tropical Cyclone Cold Wakes

1. TASK 3: Evaluating Observation Strategies Tropical Cyclone Cold Wakes Chris Old and Chris Merchant School of GeoSciences, The University of Edinburgh ESA Data Assimilation Projects, Progress Meeting 2 15th July 2013, The University of Reading

2. Overview • Tropical cyclones represent a challenge for many forecast models because: • TC development strongly coupled to ocean [Cione & Uhlhorn, 2003; Lloyud & Vecchi, 2011] • Gradients generated are poorly resolved at typical model resolutions [Bender & Ginis, 2000] • Development of TC dependent on: [Jacob & Shay, 2003; Vincent et al., 2012] • depth of pre-existing ocean surface mixed layer • strength of surface mixed layer stratification prior to storms passage • TC intensity is driven by a evaporation/condensation heat engine. • Direct feedback between TC and ocean surface layer through (near-inertial) wind-driven overturning. • Warm surface waters forced downward, cool deep water forced upward, increasing column integrated PE. • Overturning leads to cooling of surface water, reducing evaporation, weakening the heat engine. • Cold wake forms if TC translation speed exceeds phase speed of first baroclinic mode. [Jaimes & Shay, 2010] • Limited impact on pole-ward heat transport. (Winter mixed layer releases heat) [Jansen et al., 2010; Vincent et al., 2012] • Measurable impact on amplitude of seasonal SST (10% reduction). [Vincent et al., 2012] • Seasonal SST buffering may have climatic impact. • Tropical cyclones present a strongly coupled process suitable for testing a coupled model system. Introduction

3. Microwave vs TIR Based SSTs • Thermal Infrared • The majority of SST products are based on thermal infrared measurements of the surface temperature. • TIR sensors do not measure through cloud, so will not measure the SST in the vicinity of tropical cyclones. • TIR only SST products will underestimate the surface cooling associated the passage of tropical cyclones. • Microwave • Microwave based sensor can measure through cloud so can measure TC cold wakes. [Wentz et al., 2000] • MW has broader footprint compared with TIR sensors. • SST estimates contaminated by land signals from with ~75km of the coast. • SST retrieval poor in regions of high wind speed, sun glint, rainfall, and near sea ice. • Available MW Based SST Products [Chelton & Wentz, 2005] • TMI (TRMM Microwave Imager) December 1997 to Present • Non-sun-synchronous orbit, inclination 35°, global coverage between 40°S and 40°N. • Footprint 46km, scan swath 878km. • Gridded SST product at 0.25° × 0.25°, accuracy ±0.5°C. • AMSR-E (Advanced Microwave Scanning Radiometer for EOS) June 2002 to December 2010 • Sun-synchronous orbit, inclination 98.14°, global coverage between 90°S and 90°N. • Footprint 56km, scan swath 1450km. • Gridded SST product at 0.25° × 0.25°, accuracy ±0.4°C. Introduction

4. Microwave SST Products Gridded AMSR-E Coverage ( 2 June 2003 ) • Gridded AMSR-E dataSeparated in ascending/descending.Equator Crossing Times (local): 1:30 PM – ascending 1:30 AM – descending Ground track repeat: 16 daysDaily record - incomplete coverage.Includes TC cold wake obs. • Optimally Interpolated AMSR-E dataRepresents daily minimum SST.Corresponds to ~8 AM SST.Diurnal warming removed empirically.SST values > 3σ of mean from all data within 100km of obs location removed.Daily record - complete coverage.Extreme TC cold wake obs removed. OI AMSR-E Coverage ( 2 June 2003 ) Introduction

5. Tropical Cyclone Tracks • IBTrACS archive provides best available tropical cyclone track data from a number of agencies. • Archive covers 1848 to present day for tropical depressions through to super storms (Cat. 5 Hurricanes). • Records include time, position, max. sustained wind, mean sea-level pressure, basin of origin, nature of storm. • Data available from www.ncdc.noaa.gov/oa/ibtracs/[Knapp et al., 2010] Introduction

6. Test Case: Hurricane Frances, 2004 • Aim to compare AMSR-E and ERA-Interim SST over TC cold wake. • Extract TC track locations from IBTrACS archive. • Extract time series of SST data at each track location for all points within 200km of each location. • Calculate spatial average SST time series at each location. • Remove climatology to get anomaly (used Pathfinder). • Find time of minimum SST anomaly. ERA-Interim / MW SST Comparison

7. AMSR-E – ERA-Interim SST Comparison ERA-Interim / MW SST Comparison

8. Tropical Cyclone Cold Wake Diagnostic • Need to generate adjustments to TIR-based SST products accounting for missed period of cold wake SSTs. • Adjustment needs to capture both development and decay of tropical cyclone impact on SSTs. • IBTrACS archive used to identify location of tropical cyclones for generating local adjustments. • OI TMI/AMSR-E SST products are used as basis for adjustment to obtain daily full global coverage. • Gridded TMI/AMSR-E SST data used, when available, to compensate for smoothing of OI SSTs. • SST adjustment product generated at TMI/AMSR-E data resolution ( i.e. 0.25° × 0.25° ). • SST cold wake adjustment product will be daily record. • As a demonstration of the diagnostic adjustments to the ERA-Interim SSTs for 2004 were constructed. TC Cold Wake Diagnostic

9. Methodology • Extract all tropical storm track segments around the globe from IBTrACS archive for the day being processed. • Extract 30 day time series of OI TMI/AMSR-E SST data and TIR-only SST data for all points within a fixed distance of each track segment, covering 7 days prior to 22 days after the storm passage. TC Cold Wake Diagnostic

10. Methodology (cont.) • Calculate median SST( ) for each time series; (Median not biased by outliers.)Used to adjust for relative bias (season and location dependent) between MW and TIR SST data. • Calculate anomalies about TC Cold Wake Diagnostic

11. Methodology (cont.) • Calculate cold wake adjustment • Find ΔSSTmin and tminwithin 5 days of TC passage, and set ΔSST(x, y, t) = ΔSSTmin ; { tpass t tmin } • Add observations from gridded TMI/AMSR-E data where available within this SST minimum period. Only use data between 4 PM and 8 AM (local time) to avoid diurnal warming effects. TC Cold Wake Diagnostic

12. Methodology (cont.) Store time series results in corresponding daily fields of the final data product. TC Cold Wake Diagnostic

13. Threshold For Cold Wake Adjustment Expected uncertainty in ΔSST is To capture missed cold wake signal accept only ΔSST  -0.7 °C ( elsewhere set to ΔSST = 0.0 °C ) TC Cold Wake Diagnostic

14. Time Series of Wake Adjustments TC Cold Wake Diagnostic

15. Discussion • Use of TC Cold Wake Adjustment product • Can be added to SST data used for model boundary condition • Can be used to test whether coupled system produces better representation of TC SSTs • These apply equally to the CERA and the single column model developments. • Next Step • Identify SST product to be used to drive CERA model during development. • Identify which years to generate the adjustments for. • Generate adjustment product for SST data. • NOTE: The IDL code used to generate the example adjustment for the ERA-Interim SST can be applied to any SST product.The code takes approximately 30 minutes to generate a year of daily cold wake SST adjustments. Discussion

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