Simultaneously inferring above‐cloud absorbing aerosol optical thickness and underlying liquid phase cloud optical and microphysical properties using MODIS

The regional haze over the southeast (SE) Atlantic Ocean induced by biomass burning in southern Africa can be problematic for passive imager-based retrievals of the underlying quasi-permanent marine boundary layer (MBL) clouds and for estimates of top-of-atmosphere (TOA) aerosol direct radiative effect (DRE). Here an algorithm is introduced to simultaneously retrieve above-cloud aerosol optical thickness (AOT), the cloud optical thickness (COT), and cloud effective particle radius (CER) of the underlying MBL clouds while also providing pixel-level estimates of retrieval uncertainty. This approach utilizes reflectance measurements at six Moderate Resolution Imaging Spectroradiometer (MODIS) channels from the visible to the shortwave infrared. Retrievals are run under two aerosol model assumptions on 8 years (2006–2013) of June–October Aqua MODIS data over the SE Atlantic, from which a regional cloud and above-cloud aerosol climatology is produced. The cloud retrieval methodology is shown to yield COT and CER consistent with those from the MODIS operational cloud product (MOD06) when forcing AOT to zero, while the full COT-CER-AOT retrievals that account for the above-cloud aerosol attenuation increase regional monthly mean COT and CER by up to 9% and 2%, respectively. Retrieved AOT is roughly 3 to 5 times larger than the collocated 532 nm Cloud-Aerosol Lidar with Orthogonal Polarization (CALIOP) retrievals, though closer agreement is observed with the CALIOP 1064 nm retrievals, a result consistent with previous case study analyses. Regional cloudy-sky above-cloud aerosol DRE calculations are also performed that illustrate the importance of the aerosol model assumption and underlying cloud retrievals.

[1]  Andrew K. Heidinger,et al.  Molecular Line Absorption in a Scattering Atmosphere. Part II: Application to Remote Sensing in the O2 A band , 2000 .

[2]  Zhibo Zhang,et al.  New Directions: Emerging Satellite Observations of Above-cloud Aerosols and Direct Radiative Forcing , 2013 .

[3]  M. Garstang,et al.  The long‐range transport of southern African aerosols to the tropical South Atlantic , 1996 .

[4]  C. Cox Statistics of the sea surface derived from sun glitter , 1954 .

[5]  B. Holben,et al.  An Accuracy Assessment of the CALIOP/CALIPSO Version 2/Version 3 Daytime Aerosol Extinction Product Based on a Detailed Multi-Sensor, Multi-Platform Case Study , 2011 .

[6]  E. Wilcox Stratocumulus cloud thickening beneath layers of absorbing smoke aerosol , 2010 .

[7]  Jonathan H. Jiang,et al.  Touring the atmosphere aboard the A-Train , 2010 .

[8]  K. Stamnes,et al.  Numerically stable algorithm for discrete-ordinate-method radiative transfer in multiple scattering and emitting layered media. , 1988, Applied optics.

[9]  Robert Wood,et al.  Satellite-derived direct radiative effect of aerosols dependent on cloud cover , 2009 .

[10]  D. Tanré,et al.  Retrieval of aerosol microphysical and optical properties above liquid clouds from POLDER/PARASOL polarization measurements , 2012 .

[11]  J. Slusser,et al.  On Rayleigh Optical Depth Calculations , 1999 .

[12]  W. Wiscombe Improved Mie scattering algorithms. , 1980, Applied optics.

[13]  B. Albrecht Aerosols, Cloud Microphysics, and Fractional Cloudiness , 1989, Science.

[14]  W. Collins,et al.  Radiative forcing by long‐lived greenhouse gases: Calculations with the AER radiative transfer models , 2008 .

[15]  Min Min,et al.  On the influence of cloud fraction diurnal cycle and sub-grid cloud optical thickness variability on all-sky direct aerosol radiative forcing , 2014 .

[16]  M. King,et al.  Determination of the optical thickness and effective particle radius of clouds from reflected solar , 1990 .

[17]  C. Rodgers,et al.  Retrieval of atmospheric temperature and composition from remote measurements of thermal radiation , 1976 .

[18]  Steven Platnick,et al.  Estimate of the impact of absorbing aerosol over cloud on the MODIS retrievals of cloud optical thickness and effective radius using two independent retrievals of liquid water path , 2009 .

[19]  Jens Redemann,et al.  Simultaneous retrieval of aerosol and cloud properties during the MILAGRO field campaign , 2011 .

[20]  Ricardo Todling,et al.  The GEOS-5 Data Assimilation System-Documentation of Versions 5.0.1, 5.1.0, and 5.2.0 , 2008 .

[21]  H. Fuelberg,et al.  A meteorological overview of the TRACE A period , 1996 .

[22]  Eric M. Wilcox,et al.  Direct and semi-direct radiative forcing of smoke aerosols over clouds , 2011 .

[23]  Jim Haywood,et al.  Evolution of biomass burning aerosol properties from an agricultural fire in southern Africa , 2003 .

[24]  David M. Winker,et al.  The global 3-D distribution of tropospheric aerosols as characterized by CALIOP , 2012 .

[25]  W. Munk,et al.  Measurement of the Roughness of the Sea Surface from Photographs of the Sun’s Glitter , 1954 .

[26]  P. Formenti,et al.  The mean physical and optical properties of regional haze dominated by biomass burning aerosol measured from the C-130 aircraft during SAFARI 2000 , 2003 .

[27]  Sundar A. Christopher,et al.  Global Monitoring and Forecasting of Biomass-Burning Smoke: Description of and Lessons From the Fire Locating and Modeling of Burning Emissions (FLAMBE) Program , 2009, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[28]  Steven Platnick,et al.  Estimating the direct radiative effect of absorbing aerosols overlying marine boundary layer clouds in the southeast Atlantic using MODIS and CALIOP , 2013 .

[29]  J. Randerson,et al.  Assessing variability and long-term trends in burned area by merging multiple satellite fire products , 2009 .

[30]  T. Eck,et al.  A review of biomass burning emissions part III: intensive optical properties of biomass burning particles , 2004 .

[31]  Steven Platnick,et al.  Multilayer Cloud Detection with the MODIS Near-Infrared Water Vapor Absorption Band , 2010 .

[32]  J. Haywood,et al.  Solar radiative forcing by biomass burning aerosol particles during SAFARI 2000: A case study based on measured aerosol and cloud properties , 2003 .

[33]  S. Twomey The Influence of Pollution on the Shortwave Albedo of Clouds , 1977 .

[34]  P. Formenti,et al.  Radiative properties and direct radiative effect of Saharan dust measured by the C-130 aircraft during SHADE: 1. Solar spectrum , 2003 .

[35]  D. C. Robertson,et al.  MODTRAN cloud and multiple scattering upgrades with application to AVIRIS , 1998 .

[36]  M. Kirkpatrick,et al.  The impact of humidity above stratiform clouds on indirect aerosol climate forcing , 2004, Nature.

[37]  Jim Haywood,et al.  The effect of overlying absorbing aerosol layers on remote sensing retrievals of cloud effective radius and cloud optical depth , 2004 .

[38]  S. Twomey Pollution and the Planetary Albedo , 1974 .

[39]  Hiren Jethva,et al.  Retrieval of Aerosol Optical Depth above Clouds from OMI Observations: Sensitivity Analysis and Case Studies , 2012 .

[40]  François-Marie Bréon,et al.  Analysis of aerosol‐cloud interaction from multi‐sensor satellite observations , 2010 .

[41]  D. Winker,et al.  The CALIPSO Automated Aerosol Classification and Lidar Ratio Selection Algorithm , 2009 .

[42]  Mark A. Vaughan,et al.  The Retrieval of Profiles of Particulate Extinction from Cloud-Aerosol Lidar Infrared Pathfinder Satellite Observations (CALIPSO) Data: Algorithm Description , 2009 .

[43]  J. Kar,et al.  Evaluation of CALIOP 532 nm AOD over opaque water clouds , 2014 .

[44]  Oleg Dubovik,et al.  Global aerosol optical properties and application to Moderate Resolution Imaging Spectroradiometer aerosol retrieval over land , 2007 .

[45]  Shepard A. Clough,et al.  Atmospheric radiative transfer modeling: a summary of the AER codes , 2005 .

[46]  Robert Pincus,et al.  Reconciling Simulated and Observed Views of Clouds: MODIS, ISCCP, and the Limits of Instrument Simulators in Climate Models , 2011 .

[47]  J. Randerson,et al.  Global fire emissions and the contribution of deforestation, savanna, forest, agricultural, and peat fires (1997-2009) , 2010 .

[48]  Zhibo Zhang,et al.  A Novel Method for Estimating Shortwave Direct Radiative Effect of Above-Cloud Aerosols Using CALIOP and MODIS Data , 2013 .

[49]  Tristan S. L'Ecuyer,et al.  The impact of explicit cloud boundary information on ice cloud microphysical property retrievals from infrared radiances , 2003 .

[50]  O. Torres,et al.  How do A‐train sensors intercompare in the retrieval of above‐cloud aerosol optical depth? A case study‐based assessment , 2013 .

[51]  Steven Platnick,et al.  An assessment of differences between cloud effective particle radius retrievals for marine water clouds from three MODIS spectral bands , 2011 .

[52]  M. Thomas,et al.  A global survey of aerosol-liquid water cloud overlap based on four years of CALIPSO-CALIOP data , 2010 .

[53]  D. Winker,et al.  Overview of the CALIPSO Mission and CALIOP Data Processing Algorithms , 2009 .

[54]  Piet Stammes,et al.  Retrieval of the aerosol direct radiative effect over clouds from spaceborne spectrometry , 2012 .

[55]  Lorraine Remer,et al.  A Color Ratio Method for Simultaneous Retrieval of Aerosol and Cloud Optical Thickness of Above-Cloud Absorbing Aerosols From Passive Sensors: Application to MODIS Measurements , 2013, IEEE Transactions on Geoscience and Remote Sensing.

[56]  W. Collins,et al.  The NCEP–NCAR 50-Year Reanalysis: Monthly Means CD-ROM and Documentation , 2001 .

[57]  Jianglong Zhang,et al.  Evaluating the impact of aerosol particles above cloud on cloud optical depth retrievals from MODIS , 2014 .

[58]  W. Paul Menzel,et al.  The MODIS cloud products: algorithms and examples from Terra , 2003, IEEE Trans. Geosci. Remote. Sens..

[59]  Didier Tanré,et al.  Aerosol Remote Sensing over Clouds Using A-Train Observations , 2009 .

[60]  Zhaoyan Liu,et al.  Quantifying above‐cloud aerosol using spaceborne lidar for improved understanding of cloudy‐sky direct climate forcing , 2008 .

[61]  David M. Winker,et al.  Use of probability distribution functions for discriminating between cloud and aerosol in lidar backscatter data , 2004 .

[62]  Kathleen A. Powell,et al.  CALIOP and AERONET aerosol optical depth comparisons: One size fits none , 2013 .

[63]  Zhaoyan Liu,et al.  Retrieving Optical Depths and Lidar Ratios for Transparent Layers Above Opaque Water Clouds From CALIPSO Lidar Measurements , 2007, IEEE Geoscience and Remote Sensing Letters.

[64]  David M. Winker,et al.  Fully Automated Detection of Cloud and Aerosol Layers in the CALIPSO Lidar Measurements , 2009 .

[65]  S. Piketh,et al.  A seasonal trend of single scattering albedo in southern African biomass‐burning particles: Implications for satellite products and estimates of emissions for the world's largest biomass‐burning source , 2013 .

[66]  Omar Torres,et al.  Improvements to the OMI near-UV aerosol algorithm using A-train CALIOP and AIRS observations , 2013 .

[67]  F. Bréon,et al.  Aerosol indirect effect on warm clouds over South-East Atlantic, from co-located MODIS and CALIPSO observations , 2012 .

[68]  Michael D. King,et al.  Correction of Rayleigh scattering effects in cloud optical thickness retrievals , 1997 .

[69]  David M. Winker,et al.  The CALIPSO Lidar Cloud and Aerosol Discrimination: Version 2 Algorithm and Initial Assessment of Performance , 2009 .