Although the nations air has grown significantly cleaner in recent decades, about 40 percent of Americans 127 million people live in counties where pollution levels still regularly exceed national air quality standards established by the Environmental Protection Agency.
Most of the areas with the heaviest pollution are in California, but other parts of the country are anything but immune. On the drive down I-95 between Baltimore and Washington D.C., for example, sweltering summer heat and relentless traffic often leave plumes of polluted air stewing over the highway making the area one of the top 20 smoggiest metro areas in the country.
Come July, all that health-sapping pollution will have company: a 117-foot P-3B NASA research aircraft flying spirals over six ground stations in Maryland. The aircraft is part of a month-long field campaign designed to improve satellite measurements of air pollution.
The name of the experiment "Deriving Information on Surface conditions from Column and Vertically Resolved Observations Relevant to Air Quality," or DISCOVER-AQ for short is a mouthful, but its purpose is simple.
Were trying to fill the knowledge gap that severely limits our ability to monitor air pollution with satellites, said James Crawford, the campaigns principal investigator and a scientist based at NASAs Langley Research Center in Hampton, Va.
The fundamental challenge for satellites measuring air quality is to distinguish between pollution near the surface and pollution higher in the atmosphere. Measurements from aircraft, in combination with ground-based measurements, offer a key perspective that makes such distinctions easier to make.
Twelve to fourteen flights are planned throughout July using two primary planes. The P-3B, a four-engine turboprop that returned recently from a deployment to the Arctic, will carry a suite of nine instruments, while a smaller two-engine UC-12 will carry two instruments.
Both aircraft will measure the colorless gas ozone and a mixture of soot and other substances known as particulate matter. Other instruments on the P-3B will measure pollutants that lead to the formation of ozone such as nitrogen dioxide and formaldehyde. A third aircraft, a Cessna operated by the University of Maryland, will also participate in the campaign.
While the UC-12 will cruise at a high altitude of about 26,000 feet; the P-3B will fly corkscrew patterns over six ground stations in Maryland that will bring the plane from its highest altitude of about 15,500 feet to as low as 1,000 feet from the surface.
Sampling will focus on an area extending from Beltsville, Md., in the southwest to the northeastern corner of Maryland in a pattern that follows major traffic corridors, overflies ground measurement sites operated by the Maryland Department of the Environment, and observes conditions over the northern Chesapeake Bay.
The two instruments aboard the UC-12 will look down at the surface, much like a satellite instrument might, and measure particles and trace gases. The P-3B, in contrast, will sample the air it flies through, allowing it to take samples from a variety of altitudes.
The July flights are the first leg of a broader five-year campaign that will bring the aircraft to Houston and other polluted regions during upcoming years.
Measuring health sapping particles from above
Overall, the World Health Organization estimates that air pollution causes some two million premature deaths globally per year. Pollutants can spark a whole range of diseases including asthma, cardiovascular disease, and bronchitis.
Since many countries, including the United States, have large gaps in ground-based networks of air pollution monitors, experts look toward satellites to provide a global perspective. Satellites have attempted to collect information about the main air pollutants that affect human health for more than a decade, yet they have struggled to achieve accurate measurements of the pollutants in the air near the surface the air people actually breathe.
The problem: Most satellite instruments can't distinguish pollution close to the ground from that high in the atmosphere. In addition, clouds can block the view. And bright land surfaces, such as snow, desert sand, and those found in certain urban areas can mar measurements.
Were better with some pollutants than others, but broadly speaking we have difficulty distinguishing between pollutants high in a given column of air, which we can see quite well with satellites, and pollutants at the surface, said Kenneth Pickering, DISCOVER-AQs project scientist.
As a result, questions remain about the vertical distribution of pollutants. How far up in the atmosphere are morning and evening spikes in pollution associated with rush hour noticeable? How does ozone, which peaks near the surface in afternoon, behave at other altitudes throughout the day? When is the best time of the day for satellites to measure various pollutants?
The problem is particularly pronounced for pollutants that are abundant at the surface and higher in the atmosphere. For example, a code red air-quality day during the summer might produce very high concentrations of ozone in the bottom few kilometers of the atmosphere, yet generate a change of a mere 1 or 2 percent to a total column of ozone.
Studies suggest that discrepancies of as much as 30 to 50 percent exist between estimates of ground nitrogen dioxide inferred from the Ozone Monitoring Instrument (OMI), an instrument on NASAs Aura satellite launched in 2004, and measurements from ground-based instruments.
A three-dimensional picture
DISCOVER-AQ will address such problems by helping researchers develop a three dimensional view of how air pollutants are distributed and move between different levels of the atmosphere throughout the day.
A phalanx of ground-based instruments will offer a critical view of the same patches of air the aircraft are monitoring from above. While NASA sponsors certain ground instruments, other institutions including the Environmental Protection Agency, the Maryland Department of the Environment, Howard University, and Pennsylvania State University manage the instruments at the ground stations.
One of the stations at Edgewood in Maryland is particularly well-suited for monitoring how sea breezes that blow in from the Chesapeake Bay and trap pollutants over land contribute to some of the most severe ozone problems in Maryland, noted Anne Thompson, a professor of meteorology at Pennsylvania State University.
Its rare for researchers to have an opportunity to use such an array of instruments at once. Its not just one instrument thats most important its really the combination of all of them that makes this campaign valuable, said Jennifer Hains, a research statistician with the Maryland Department of the Environment.
Scientists will use information collected during the DISCOVER-AQ campaign to improve measurements from existing satellites and to help establish parameters for future NASA satellite missions that will monitor air quality.
Achieving better measurements of the column at a variety of altitudes is critical to connecting whats happening at the surface to what were seeing from above with satellites, said Scott Janz, a scientist based at Goddard Space Flight Center in Greenbelt, Md.
Future satellites could play a key role in helping communities meet national air-quality standards. Though ozone and PM2.5 have declined in recent decades across the nation, many areas, including the entire Baltimore/Washington region, still frequently experience days in which air pollution levels exceed standards established by the Environmental Protection Agency.
Over the last five years, for example, Maryland has exceeded ozone standards on average 36 days per year and exceeded PM2.5 standards on average 10 days per year, according to the Maryland Department of the Environment. Last year, ozone proved particularly potent and Maryland exceeded ozone standards on 43 ozone days.
Explore further: Paving the way for space-based air pollution sensors