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– No matter where on earth you live, there’s likely to be an eye in the sky hovering overhead, and that’s a good thing, at least when it comes to satellite monitoring of air quality, said scientists from the National Aeronautics and Space Administration (NASA).

In a special symposium held at the American Thoracic Society’s international conference, NASA health and air quality specialists described the use of space-based systems and earth science applications to improve understanding of respiratory health risks worldwide, and to help enrich pulmonary research with galaxies of data.

“Every day we download over 25 terabytes of data,” said John Haynes, MS, program manager for Health and Air Quality Applications in the Earth Action Program of the NASA Earth Science Division in Washington.

Neil Osterweil/MDedge News
John Haynes

“Many of the observation data sets are critical for healthy air quality applications: observation of land surface temperature, sea surface temperature, precipitation, fires and thermal anomalies, aerosols, just to name a few, and the really awesome news is this offering from our constellation of satellites is free and open access, available to everyone across the globe,” he said.

The mission of NASA’s Earth Action Program is “to enable people and organizations to apply insights from Earth science to benefit the economy, health, quality of life, and environment.”

Program staff work with both industry and nonprofit environmental advocacy and health groups to help inform their decisions and actions with Earth science information.

NASA supports the use of Earth observations to help monitor and manage infectious diseases and environmental health, toxins and pathogens that affect health, air quality standards, and to assess the effects of climate change on air quality and public health.

Mr. Haynes noted that worldwide, six major cities have incorporated NASA data on fine particulate matter smaller than 2.5 microns (PM2.5) into their climate action plans. These cities include Accra, Ghana; Addis Ababa, Ethiopia; Buenos Aires, Argentina; Guadalajara, Mexico; Lima, Peru; and Johannesburg, South Africa.
 

Monitoring pollution with TEMPO

There are more than 30 Earth-monitoring systems currently in orbit or soon to be launched, including NASA’s Tropospheric Emissions: Monitoring of Pollution (TEMPO), launched in April 2023, with first operations in August 2023. The instrument is in a geostationary orbit about 22,236 miles above the equator at longitudes that allow it to survey virtually all of North America — from coast to coast, and from southern Mexico, Cuba, Puerto Rico, and the Bahamas to Northern Canada.

TEMPO is part of a geostationary air quality satellite “constellation” or group that provides daylight observation over the entire Northern Hemisphere, explained Aaron Naeger, PhD, MS, mission applications lead for TEMPO at the NASA Marshall Space Flight Center in Huntsville, Alabama.

Until TEMPO, space-based instruments had relatively low spatial resolution and could only capture one image each day. In contrast, TEMPO can scan east-west each daylight hour across its entire coverage area (known as the Field of Regard), and even more frequently during early morning and late afternoon. This allows researchers to measure volumes of pollution, sources, and how these pollution levels vary over time. The system measures ozone levels, nitrogen dioxide (NO2,) formaldehyde, and aerosols.

More than 100 federal, state, local and tribal air quality agencies use the data captured by TEMPO to inform public health efforts.

Dr. Naeger gave examples of how the system can help identify public health hazards, including scans that showed high NO2 levels from cities, traffic corridors, power plants, oil and gas fields, and fires.

Similarly, the system detected unhealthy ozone and PM2.5 levels during prescribed burns in April 2024, as well as notable differences between weekdays and weekends in NO2 concentrations across California and the Front Range in Colorado. These showed higher levels along traffic corridors during weekdays related to increased traffic volumes and tailpipe emissions.
 

 

 

Fire and heat

Other NASA health and air quality initiatives include the FireAQ project, based at the University of Iowa in Iowa City, which provides free online weekly briefings on fire-related air quality concerns using data from TEMPO and other NASA satellite systems. The FireAQ project was described by Jun Wang, PhD, from the University of Iowa in Iowa City.

NASA also fosters collaborations to reduce health disparities in air quality and respiratory health in urban heat islands and other areas affected by extreme temperatures due to climate change, as discussed by Christopher K. Uejio, PhD, from Florida State University in Tallahassee.

Air pollution expert George D. Thurston, ScD, professor of medicine and population health at the NYU Grossman School of Medicine, who attended the session, said that the PM2.5 standard includes nontoxic particulate matter, such as soil, and misses sub-micron sized particles, and asked Mr. Haynes whether smaller particles were being measured in the studies he described.

Mr. Haynes replied that the systems do not directly measure PM2.5 but instead rely on aerosol optical depth, a measure of the extent to which atmospheric particles absorb or scatter sunlight.

Dr. Thurston, who in 1987 was coauthor of groundbreaking study showing the link between PM2.5 levels and mortality, is now an advocate for a tougher standard of measuring ambient ultrafine particles with an aerodynamic diameter less than .1 microns in size (PM1).

NASA health and climate data are available at https://www.earthdata.nasa.gov/.

Mr. Haynes and Dr. Naeger are NASA employees. Dr. Thurston had no relevant disclosures.

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– No matter where on earth you live, there’s likely to be an eye in the sky hovering overhead, and that’s a good thing, at least when it comes to satellite monitoring of air quality, said scientists from the National Aeronautics and Space Administration (NASA).

In a special symposium held at the American Thoracic Society’s international conference, NASA health and air quality specialists described the use of space-based systems and earth science applications to improve understanding of respiratory health risks worldwide, and to help enrich pulmonary research with galaxies of data.

“Every day we download over 25 terabytes of data,” said John Haynes, MS, program manager for Health and Air Quality Applications in the Earth Action Program of the NASA Earth Science Division in Washington.

Neil Osterweil/MDedge News
John Haynes

“Many of the observation data sets are critical for healthy air quality applications: observation of land surface temperature, sea surface temperature, precipitation, fires and thermal anomalies, aerosols, just to name a few, and the really awesome news is this offering from our constellation of satellites is free and open access, available to everyone across the globe,” he said.

The mission of NASA’s Earth Action Program is “to enable people and organizations to apply insights from Earth science to benefit the economy, health, quality of life, and environment.”

Program staff work with both industry and nonprofit environmental advocacy and health groups to help inform their decisions and actions with Earth science information.

NASA supports the use of Earth observations to help monitor and manage infectious diseases and environmental health, toxins and pathogens that affect health, air quality standards, and to assess the effects of climate change on air quality and public health.

Mr. Haynes noted that worldwide, six major cities have incorporated NASA data on fine particulate matter smaller than 2.5 microns (PM2.5) into their climate action plans. These cities include Accra, Ghana; Addis Ababa, Ethiopia; Buenos Aires, Argentina; Guadalajara, Mexico; Lima, Peru; and Johannesburg, South Africa.
 

Monitoring pollution with TEMPO

There are more than 30 Earth-monitoring systems currently in orbit or soon to be launched, including NASA’s Tropospheric Emissions: Monitoring of Pollution (TEMPO), launched in April 2023, with first operations in August 2023. The instrument is in a geostationary orbit about 22,236 miles above the equator at longitudes that allow it to survey virtually all of North America — from coast to coast, and from southern Mexico, Cuba, Puerto Rico, and the Bahamas to Northern Canada.

TEMPO is part of a geostationary air quality satellite “constellation” or group that provides daylight observation over the entire Northern Hemisphere, explained Aaron Naeger, PhD, MS, mission applications lead for TEMPO at the NASA Marshall Space Flight Center in Huntsville, Alabama.

Until TEMPO, space-based instruments had relatively low spatial resolution and could only capture one image each day. In contrast, TEMPO can scan east-west each daylight hour across its entire coverage area (known as the Field of Regard), and even more frequently during early morning and late afternoon. This allows researchers to measure volumes of pollution, sources, and how these pollution levels vary over time. The system measures ozone levels, nitrogen dioxide (NO2,) formaldehyde, and aerosols.

More than 100 federal, state, local and tribal air quality agencies use the data captured by TEMPO to inform public health efforts.

Dr. Naeger gave examples of how the system can help identify public health hazards, including scans that showed high NO2 levels from cities, traffic corridors, power plants, oil and gas fields, and fires.

Similarly, the system detected unhealthy ozone and PM2.5 levels during prescribed burns in April 2024, as well as notable differences between weekdays and weekends in NO2 concentrations across California and the Front Range in Colorado. These showed higher levels along traffic corridors during weekdays related to increased traffic volumes and tailpipe emissions.
 

 

 

Fire and heat

Other NASA health and air quality initiatives include the FireAQ project, based at the University of Iowa in Iowa City, which provides free online weekly briefings on fire-related air quality concerns using data from TEMPO and other NASA satellite systems. The FireAQ project was described by Jun Wang, PhD, from the University of Iowa in Iowa City.

NASA also fosters collaborations to reduce health disparities in air quality and respiratory health in urban heat islands and other areas affected by extreme temperatures due to climate change, as discussed by Christopher K. Uejio, PhD, from Florida State University in Tallahassee.

Air pollution expert George D. Thurston, ScD, professor of medicine and population health at the NYU Grossman School of Medicine, who attended the session, said that the PM2.5 standard includes nontoxic particulate matter, such as soil, and misses sub-micron sized particles, and asked Mr. Haynes whether smaller particles were being measured in the studies he described.

Mr. Haynes replied that the systems do not directly measure PM2.5 but instead rely on aerosol optical depth, a measure of the extent to which atmospheric particles absorb or scatter sunlight.

Dr. Thurston, who in 1987 was coauthor of groundbreaking study showing the link between PM2.5 levels and mortality, is now an advocate for a tougher standard of measuring ambient ultrafine particles with an aerodynamic diameter less than .1 microns in size (PM1).

NASA health and climate data are available at https://www.earthdata.nasa.gov/.

Mr. Haynes and Dr. Naeger are NASA employees. Dr. Thurston had no relevant disclosures.

– No matter where on earth you live, there’s likely to be an eye in the sky hovering overhead, and that’s a good thing, at least when it comes to satellite monitoring of air quality, said scientists from the National Aeronautics and Space Administration (NASA).

In a special symposium held at the American Thoracic Society’s international conference, NASA health and air quality specialists described the use of space-based systems and earth science applications to improve understanding of respiratory health risks worldwide, and to help enrich pulmonary research with galaxies of data.

“Every day we download over 25 terabytes of data,” said John Haynes, MS, program manager for Health and Air Quality Applications in the Earth Action Program of the NASA Earth Science Division in Washington.

Neil Osterweil/MDedge News
John Haynes

“Many of the observation data sets are critical for healthy air quality applications: observation of land surface temperature, sea surface temperature, precipitation, fires and thermal anomalies, aerosols, just to name a few, and the really awesome news is this offering from our constellation of satellites is free and open access, available to everyone across the globe,” he said.

The mission of NASA’s Earth Action Program is “to enable people and organizations to apply insights from Earth science to benefit the economy, health, quality of life, and environment.”

Program staff work with both industry and nonprofit environmental advocacy and health groups to help inform their decisions and actions with Earth science information.

NASA supports the use of Earth observations to help monitor and manage infectious diseases and environmental health, toxins and pathogens that affect health, air quality standards, and to assess the effects of climate change on air quality and public health.

Mr. Haynes noted that worldwide, six major cities have incorporated NASA data on fine particulate matter smaller than 2.5 microns (PM2.5) into their climate action plans. These cities include Accra, Ghana; Addis Ababa, Ethiopia; Buenos Aires, Argentina; Guadalajara, Mexico; Lima, Peru; and Johannesburg, South Africa.
 

Monitoring pollution with TEMPO

There are more than 30 Earth-monitoring systems currently in orbit or soon to be launched, including NASA’s Tropospheric Emissions: Monitoring of Pollution (TEMPO), launched in April 2023, with first operations in August 2023. The instrument is in a geostationary orbit about 22,236 miles above the equator at longitudes that allow it to survey virtually all of North America — from coast to coast, and from southern Mexico, Cuba, Puerto Rico, and the Bahamas to Northern Canada.

TEMPO is part of a geostationary air quality satellite “constellation” or group that provides daylight observation over the entire Northern Hemisphere, explained Aaron Naeger, PhD, MS, mission applications lead for TEMPO at the NASA Marshall Space Flight Center in Huntsville, Alabama.

Until TEMPO, space-based instruments had relatively low spatial resolution and could only capture one image each day. In contrast, TEMPO can scan east-west each daylight hour across its entire coverage area (known as the Field of Regard), and even more frequently during early morning and late afternoon. This allows researchers to measure volumes of pollution, sources, and how these pollution levels vary over time. The system measures ozone levels, nitrogen dioxide (NO2,) formaldehyde, and aerosols.

More than 100 federal, state, local and tribal air quality agencies use the data captured by TEMPO to inform public health efforts.

Dr. Naeger gave examples of how the system can help identify public health hazards, including scans that showed high NO2 levels from cities, traffic corridors, power plants, oil and gas fields, and fires.

Similarly, the system detected unhealthy ozone and PM2.5 levels during prescribed burns in April 2024, as well as notable differences between weekdays and weekends in NO2 concentrations across California and the Front Range in Colorado. These showed higher levels along traffic corridors during weekdays related to increased traffic volumes and tailpipe emissions.
 

 

 

Fire and heat

Other NASA health and air quality initiatives include the FireAQ project, based at the University of Iowa in Iowa City, which provides free online weekly briefings on fire-related air quality concerns using data from TEMPO and other NASA satellite systems. The FireAQ project was described by Jun Wang, PhD, from the University of Iowa in Iowa City.

NASA also fosters collaborations to reduce health disparities in air quality and respiratory health in urban heat islands and other areas affected by extreme temperatures due to climate change, as discussed by Christopher K. Uejio, PhD, from Florida State University in Tallahassee.

Air pollution expert George D. Thurston, ScD, professor of medicine and population health at the NYU Grossman School of Medicine, who attended the session, said that the PM2.5 standard includes nontoxic particulate matter, such as soil, and misses sub-micron sized particles, and asked Mr. Haynes whether smaller particles were being measured in the studies he described.

Mr. Haynes replied that the systems do not directly measure PM2.5 but instead rely on aerosol optical depth, a measure of the extent to which atmospheric particles absorb or scatter sunlight.

Dr. Thurston, who in 1987 was coauthor of groundbreaking study showing the link between PM2.5 levels and mortality, is now an advocate for a tougher standard of measuring ambient ultrafine particles with an aerodynamic diameter less than .1 microns in size (PM1).

NASA health and climate data are available at https://www.earthdata.nasa.gov/.

Mr. Haynes and Dr. Naeger are NASA employees. Dr. Thurston had no relevant disclosures.

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