North American Visibility
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Seasonal Bext
Horizontal Visibility: Determined by the Extinction Coefficient, Bext Bext can be estimated from surface visual range data and WebCams The dry BEXT (say RH = 50%) can also be estimated from the weighed sum of the mass concentrations of aerosol types: Bext = (a1*Dust + a2*Smoke + a3*Haze + a4*Salt + a5*Soot) The weights a1…a5 are the mass extinction efficiencies for each species. The chemical species concentrations are obtained from filter samples followed by chemical analysis
Aerosol Types and Vertical Layering At any given geographic location, the aerosol is composed of multiple types, e.g. dust, smoke and haze The aerosol types most frequently reside in different layers As a consequence, horizontal visibility is influenced by the aerosol in the surface layer while the vertical and slant visibility is determined by the layers in the aerosol column containing multiple aerosol types and layers.
WMO Global Surface Meteorological Network
Visibility over North America: A Global Perspective
Surface Visibility
AVHRR
ShipObs
POLDER
SeaWiFS, TOMS and Surface Extinction Surface reflectance derived from the SeaWiFS satellite data for May The spectral reflectance data were rendered as a "true color" digital image by combining the blue (0.412 m), green (0.550 m), and red (0.670 m) channels. The TOMS absorbing aerosol index (green, levels 12 and 30) and the visibility-derived extinction coefficients are superimposed as green contours (red, levels 0.2. and 0.4 km -1 ).
3D SeaWiFS May 14, 1998
Average Excess TOMS Index for Mar., Apr., May 1998 Excess TOMS absorbing aerosol index averaged for March, April, May 1998 compared to The insert depicts the 1998 smoke impact from a global perspective.
Fire Locations
Surface Ozone Concentration Superposition of daily maximum ozone and aerosol extinction maps derived from surface visibility.
Visibility Module: Calculates visibility from aerosol concentration and humidity data
SeaWiFS Surface Reflectance on Clear and Smoky Days Spectral reflectance data derived from the SeaWiFS sensor on May 15, 1998; b) Excess aerosol backscattering over water.
Synopsis During a ten-day period, May 7-17, 1998, smoke from fires in Central America drifted northward into the USA and Canada. The smoke caused exceedances of the PM standard, health alerts, and impairment of air traffic, as well as major reductions of visual range, and red sunsets. It was a major air pollution event covered by the research community as well as by the national media.
Background Throughout the spring of 1998, thousands of fires in Central America have been burning as it happens every spring but the 1998 fires are said to be about twice as intense as the normal year. Unlike earlier years, the research community has followed with keen interest the 1998 Central American fires by a variety of UV, visible and infrared remote sensors from satellites. This is summary of the Web-based data as augmented by surface-based PM10 monitoring data by state agencies This preliminary and incomplete but timely summary is intended for air quality managers and researchers interested in pursuing further detailed analysis of this unusual event.
Location of fires (red dots) on May 15, 1998, based on Defense Meteorological Satellite Program (DMSP) satellite dataDefense Meteorological Satellite Program (DMSP) NOAA’s Operational Significant Event Imagery (OSEI) Forest Fires over Central America Throughout the spring of 1998, thousands of fires in Central America have been burning with twice the intensity of normal springtime fires.
Smoke from the Central American Fires Based on SeaWiFS and other satellite imagery, thick smoke has been lingering over southern Mexico, Guatemala and Honduras and adjacent oceans throughout the spring season.SeaWiFS
Smoke passes over Eastern North America TOMS Aerosol Index GOES 8 Visible Imagery May 12May 14May 15May 16
Preliminary Surface Haze-Ozone Map Comparison Surface haze maps show the north and eastward transport of smoke aerosol Regionally, the smoke does not appear to add ozone to the existing values Rather, ozone in the smoky airmass tends to be lower than the surrounding areas
US Visibility Trend Maps, Click on the images to view larger versions In the Eastern US, throughout the period, the 75th percentile BEXT exceeded 0.15 or had an average visibility of less than 10 miles. Most notable are the hazy regions on both sides of the Appalachian Mountains where the BEXT exceeds 0.2 1/km. Since the early 1980s the BEXT decreased 10-15% with the largest decreases in the Southern and Central regions.
Light Extinction Trends of the 75th and 90th Percentiles Over the Eastern US, the 75 th percentile BEXT decreased about ~8 percent over the 15 years. The largest decreases occurred in the Southeast where the BEXT decreased 12% compared to 8% in the Northeast.