NRL Monterey Aerosol Group Members and Expertise Anthony BucholtzRadiative measurements, tactical decision aids James R. Campbell Cloud and aerosol Lidar Cynthia A. CurtisProducts, distribution, transitions Edward J. HyerSatellite data quality, biomass burning Elizabeth A. ReidField deployments, data analysis Jeffrey S. ReidAerosol microphysics, radiation and observability Annette L. WalkerGlobal dust sources, operators Douglas L. Westphal Global and regional aerosol modeling James Campbell Naval Research Laboratory Monterey, CA 23 April 2014 Collaborative Possibilities for CalWater2
Coastal Facility for Atmospheric Research (CFAR) NREL site Purpose : Operational testing of NRL-MRY's atmospheric instrument suites prior to deployment. Long-term measurements in a coastal marine environment for model validation. Reference 'standards' for validation and calibration of field instruments. CFAR Rooftop Observation Deck ‘First Light’ on 29Dec2013
-MPLNet Lidar -Time-height distribution of: - aerosols and clouds - aerosol optical depth (estimate) -523 nm eye-safe lidar; night and day -Polarization-sensitive (pending) -AERONET Sun Photometer -Aerosol Optical Depth: 340, 380, 440, 500, 675, 870, 940, and 1020 nm -High daytime temporal resolution -Potentially multiple instruments -Solar/IR/UV Radiometers -Total, Direct, Diffuse Solar Radiation at surface -Downwelling IR irradiance at surface -Downwelling UV at surface -Ceilometer -Cloud base heights Coastal Facility for Atmospheric Research (CFAR) Instrumentation -Weather Stations, IR Hygrometer/CO2, and Visiometer -Surface met conditions -Lateral Visibility - Gas Monitors (Ozone and SO2) -Mass concentrations -Aerosol particle sizing -Aerosol size distribution and concentration at surface -Aerosol Particle Samplers -Mass concentrations and physical properties -Aerosol Particle Scattering and Absorption All instrumentation is deployable
CFAR Lidar Profiling of Asian Dust Instrument will become polarization-sensitive in FY15 Still, without depolarization, dust scattering is very distinct in lidar measurements
Aerosol/Cloud Airborne Measurement Capability CIRPAS Twin Otter Utilization of CIRPAS Aircraft * Run by NPS in partnership with Cal Tech * Full complement of instrumentation to support atmospheric and oceanographic research: - Met: T, P, RH, dropsondes - Cloud/Aerosol: size, concentration, composition - Radiation (in development): up and downwelling solar/IR flux, AOD Eliminates one of the biggest sources of error and the most time-consuming data reduction step in airborne radiometer measurements Platform level to within +/ deg Development of Stabilized Platform/Radiometer Package
Navy Aerosol Analysis and Prediction System (NAAPS) The U.S. Navy Aerosol Analysis and Prediction System (NAAPS) is an operational global aerosol transport model used to forecast visibility conditions for fleet operations and motivate basic research. 6-day forecasts every 6 hours of global sulfate, SO 2, dust, smoke and sea-salt mass concentrations. Grid:.33°x.33° degree; 25 sigma levels to 100 mb
NAAPS Support and Source Product Development FLAMBÉ: Global Fire Emissions in Near Real Time Active Fire detections from NASA/Geostationary Satellites 4,000/day from MODIS-Terra 8,000/day from MODIS-Aqua Hourly estimates of carbon, trace gas, and particulate emissions Reid, J. S. 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, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2, , Hyer, E. J., and Chew, B. N.: Aerosol transport model evaluation of an extreme smoke episode in Southeast Asia, Atmos. Environ., 44, , NRL Monterey Dust Source Database Using Machine Learning to identify active global dust sources at 1 km 2 resolution Combined MODIS and multi-spectral geostationary algorithms used to identify active dust regions Walker, A. L., M. Liu, S. D. Miller, K. A. Richardson, and D. L. Westphal (2009), Development of a dust source database for mesoscale forecasting in southwest Asia, J. Geophys. Res., 114, D18207, doi: /2008JD
International Cooperative for Aerosol Prediction: Formalizing the Aerosol Prediction Community After an initial 2010 Monterey meeting, aerosol forecast system developers meet annually under the ICAP umbrella. Developers do not officially speak for their lab or make commitments, but rather gather discuss problems and best practices. ICAP allows developers to speak as a community and make scientific recommendations. “Ticket to Ride” is a global aerosol model running at least quasi operationally or a global satellite data provider. Current model members: BSC, ECMWF, JMA, NASA GMAO, NOAA NCEP, NRL, UKMO ICAP has made significant headway in convincing international agencies to expend resources on aerosol forecasting problems. EUMETSAT