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CALIPSO Ocean Products: Progress

CALIPSO Ocean Products: Progress. Advisors: Mike Behrenfeld and Chuck McClain Ball Aerospace: Carl Weimer CNES: Jacques Pelon NASA LaRC: Yongxiang Hu, Sharon Rodier, Chip Trepte, Bill Hunt NASA NRC Postdoc Program: Pengwang Zhai and Damien Josset Stevens Institute of Tech: Knut Stamnes

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CALIPSO Ocean Products: Progress

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  1. CALIPSO Ocean Products: Progress Advisors: Mike Behrenfeld and Chuck McClain Ball Aerospace: Carl Weimer CNES: Jacques Pelon NASA LaRC: Yongxiang Hu, Sharon Rodier, Chip Trepte, Bill Hunt NASA NRC Postdoc Program: Pengwang Zhai and Damien Josset Stevens Institute of Tech: Knut Stamnes ODU: Richard Zimmerman and Victoria Hill SAIC: Jim Koziana Bigelow: William Balch HSRL and RSP instruments: Chris Hostetler and Brian Cairns Supported by NASA HQ ocean biogeochemistry program and radiation science program Paula and Hal: Thanks!

  2. Outline • CALIPSO lidar measurements: introduction • Sub-surface particulate backscatter from cross-polarization profiling: progress • Highlight: a self-calibration method is developed for CALIPSO ocean subsurface lidar backscatter product (good for future trend analysis) • Air-sea gas exchange velocity from lidar measurements of ocean surface mean square slope • Other studies that supports ocean color program • aerosol optical depth estimates without microphysics assumption • identification of smoke aerosols • modeling and sensitivity studies with polarimeter measurements

  3. CALIPSO and A-Train CALIPSO: Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation CALIPSO is 75 seconds behind Aqua, with MODIS, CERES, AMSR, …, onboard

  4. CALIPSO PayloadThree Near Nadir Viewing Instruments Lidar Imaging Infrared Radiometer (IIR) High-resolution image (swath product) CALIOP Cloud-Aerosol Lidar with Orthogonal Polarization 1 meter CALIOP Receiver Telescope Vertical profiles ofatmosphere 2 wavelength polarization sensitive lidar: WFC 1064 nm, 532 nm (parallel and perpendicular) Wide Field Camera (WFC) CALIOP Laser Transmitter High-resolution image (125m resolution) IIR CALIPSO Payload

  5. Altitude Region 0.3 degree

  6. Ocean Study Using Lidar in Space • 532nm Cross-Polarization: Particulate Backscatter • 1064nm: Air-sea gas transfer velocity; wind speed • 532nm Co-polarization: aerosol correction

  7. CALIPSO cross polarization channel ocean subsurface integrated backscatter (Lc) Lc = (total lidar backscatter in water) / ( atmospheric two way transmittance) total lidar backscatter in water = sum [lidar backscatter] (unit: 1/sr) Atmospheric two way transmittance = exp (- 2* atmospheric optical depth)

  8. Progress in lidar subsurface backscatter Study • Self-calibration (solving daytime calibration issue): • the new ocean subsurface CALIPSO backscatter is self-calibrated • Lc = subsurface particulate backscatter / atmospheric twoway transmittance • = theoretical Cox-Munk Reflectance (from CloudSat or AMSR-E) • * [calib * uncalib subsurface signal] / [calib * uncalib ocean surface signal] • Solving issues related to instrumentation • new crosstalk correction (co-polarization vs cross polarization); cross-pol low-gain change from Feb 2007; … • Monte Carlo simulation of multiple scattering and its impact on the signal: significant contribution from multiple scatter; more going studies; needs help on characterizing particulate scattering phase matrix

  9. CALIPSO sub-surface backscatter: 2007 and 2008

  10. CALIPSO sub-surface backscatter: Night vs Day No big problem with daytime: Self calibration worked!

  11. CALIPSO sub-surface backscatter: MarAprMay vs SepOctNov

  12. CALIPSO sub-surface backscatter: DecJanFebvsJunJulAug

  13. 7m/s vs 11 m/s thresholds: impact of bubbles V<7 m/s V<11 m/s

  14. 7m/s vs 11 m/s thresholds: impact of bubbles V<7 m/s V<11 m/s

  15. Link between Bbp and lidar cross-polarization particulate backscatter DLc DLc= (1+m)Bbp/(2abeam)*[1-exp(-2abeamDH/(1+m))] *f(particle shape) *exp(-2abeam H0/(1+m)) abeam: beam attenuation m: multiple scatter contribution Integrated lidar subsurface backscatter [Sum(DLc)] is proportional to (1+m)Bbp/abeam When (1+m)*(beam attenuation ) of a size bin is >>1, 1-exp(-2abeamDH/(1+m))]=1 Backscatter of individual vertical bin, DLc, of the profile is proportional to Bbp whenDH is small and 1-exp(-2abeamDH/(1+m))= 2abeamDH/(1+m) Effective depth and backscatter profile product (under development): extra information help separate Bbpand abeam

  16. Validating Aerosol Correction using Ocean Surface Co-polarization Component (HSRL: Sept. 04, 2007; from Chris Hostetler, John Hair, and others of the NASA LaRC HSRL group. Thanks!)

  17. Comparison with MODIS(January 2007) 1064nm optical depth from CALIPSO/AMSR 532nm optical depth from CALIPSO/AMSR 550nm optical depth from MODIS

  18. Identifying Absorbing AerosolsUsing Lidar Ratio (e.g. smoke: around 70) from Ocean Surface BackscatterEffective Lidar Ratio = Beam Attenuation / Backscatter = [1-exp(-2t)]/(2g)]

  19. Application of lidar measurements: gas transfer velocity Ocean and the missing carbon sink Atmospheric increase (3.2 PgC/yr) = Emissions from fossil fuels (6.3) + Net emissions from changes in land use (2.2) - Oceanic uptake (2.4) - Missing carbon sink (2.9) From Woods Hole Reserch Center Website Combined with errors in partial pressure, the uncertainty of a factor of two in air-sea gas transfer velocity can lead to unacceptable error in global ocean flux of CO2 (Wallace, 1995)

  20. Application of lidar measurements: gas transfer velocity Relation between carbon uptake and gas transfer velocitty CO2 Uptake = Air-sea Gas transfer velocity k x (660/Sc)n x solubility x D(Pco2)

  21. Air-sea gas transfer – wind speed relation : A source of uncertainty in Ocean Carbon Uptake R.A. Feely, C.L. Sabine, T. Takahashi, and R. Wanninkhof, 2001: Uptake and Storage of Carbon Dioxide in the Ocean: The Global CO2 Survey, Oceanography, 14/4, 18-32.

  22. CALIPSO mean square slope <S2> improves gas transfer velocity(Jahne et al 1984; Hara et al 1995; Bock et al 1999; Frew et al 2004, …) wave slope variance correlates with gas transfer velocity better than wind speed and wind stress Frew et al, 2004, JGR

  23. Mean square slope <tan2q> is directly measured by CALIPSO: ocean surface backscatter Ocean Surface Backscatter g = C* [ sec4q/<tan2q> exp(- 0.5 tan2q / < tan2q > ] = C / <tan2q> At 532nm and 1064nm, Fresnel reflection is valid for all surface waves

  24. Carbon Uptake Comparison: F(Wind) (AMSR) vs F(<S2>) (CALIPSO)

  25. Combined Active/passive:Modeling and Sensitivity Studies for ACE • Fast and accurate coupled ocean-atmospheric model for polarized radiative transfer • Sensitivity studies: how can polarization help • Objectives: using polarization measurements to help improve lidar data analysis

  26. Model Description • A vector radiative transfer model has been developed for a coupled atmosphere ocean system. • It is based on successive order of scattering method. • It converges fast for optically thin or absorptive media. • Various state of art techniques have been employed to enhance performance. • A reference can be found at: Peng-Wang Zhai, Yongxiang Hu, Charles R. Trepte, and Patricia L. Lucker, "A vector radiative transfer model for coupled atmosphere and ocean systems based on successive order of scattering method," Opt. Express 17, 2057-2079 (2009) 
http://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-17-4-2057

  27. Sensitivity of Radiance and Degree of Polarization to Layer Depth I1, P1: plankton layer at 10 m below surface I2, P2: 50 m below surface Unit of I1 and I2: Wm-2mm-1 I1 (I1-I2) P1 (P1-P2)

  28. Radiance and Degree of Polarization Sensitivity to Size Case 1: effective size 1 mm Case 3: effective size 30 mm I3 (I3-I1) Unit of I1 and I2: Wm-2mm-1 P3 (P3-P1)

  29. Summary and Discussion • Highlight: a self-calibration method is developed for CALIPSO ocean subsurface lidar backscatter product (good for trend analysis) • CALIPSO sub-surface integrated lidar backscatter (cross-polarization) is ready to release; depolarization ratio and vertical profiling of backscatter are still work in progress • Preliminary study is done on the air-sea gas transfer velocity product • ACE proof of concept: modeling and sensitivity studies of combined lidar/polarimeter for ocean color

  30. HSRL lidar and RSP polarimeter flights over routes where in situ measurements are available Purpose: Learning from the success of ocean color vacarious calibration, we want to examine the potential of using several well defined targets (e.g. ocean surface) as the “moby” equivalent for lidar/radar and polarimeter How: A few aircraft measurement flights supported by CALIPSO over various targets, in situ measurements of optical properties, and polarized radiative transfer modeling to assess how well we can understand those targets Preliminary plan: flights this summer/fall near NASA Stennis and/or Langley (exact time and location to be decided: need your suggestions and collaborations on in situ measurements ) My email: yongxiang.hu-1@nasa.gov Phone: 757 864 9824

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