麻豆淫院

Canada is facing another dangerous wildfire season, with burning forests sending smoke plumes across the provinces and into the U.S. again. The is reminiscent of the , which in North America to hazardous smoke levels.

For most of the past decade, forecasters have been able to use satellites to , but the view was only two-dimensional: The satellites couldn't determine how close the smoke was to Earth's surface.

The altitude of the smoke matters.

If a plume is high in the atmosphere, it won't affect the air people breathe鈥攊t simply floats by, far overhead.

But when smoke plumes are close to the surface, people are breathing in . Those particles, known as PM2.5, can get deep into the lungs and exacerbate asthma and other respiratory and cardiac problems.

The Environmental Protection Agency uses a network of ground-based air quality monitors to issue air quality alerts, but the monitors are , meaning forecasts have been broad estimates in much of the country.

Now, a new satellite-based method and colleagues at universities and federal agencies have been working on for the past two years is able to give scientists and air quality managers a 3D picture of the smoke plumes, providing detailed data of the risks down to the neighborhood level for urban and rural areas alike.

Building a nationwide smoke monitoring system

The new method uses data from a satellite that NASA launched in 2023 called the .

TEMPO makes it possible to determine a smoke plume's height by providing data on how much the oxygen molecules absorb sunlight at the 688 nanometer wavelength. Smoke plumes that are high in the atmosphere reflect more solar radiation at this wavelength back to space, while those lower in the atmosphere, where there is more oxygen to absorb the light, reflect less.

Understanding the physics allowed scientists to develop algorithms that use TEMPO's data to infer the smoke plume's altitude and map its 3D movement in nearly real time.

By combining TEMPO's data with measurements of particles in the atmosphere, taken by the , forecasters can better assess the health risk from smoke plumes in almost real time, provided clouds aren't in the way.

That's a big jump from relying on , which may be hundreds of miles apart. Iowa, for example, had air quality monitors reporting data on a recent day for a state that covers 56,273 square miles. Most of those monitors were clustered around its largest cities.

NOAA's currently provides a near-real-time stream of wildfire smoke images from its GOES-R satellites, and the agency plans to incorporate TEMPO's height data. A prototype of this system from my team's NASA-supported research project on fire and air quality, called FireAQ, shows how users can zoom in to the neighborhood level to , however the prototype is currently only updated once a day, so the data is delayed, and it isn't able to provide smoke height data where clouds are also overhead.

Wildfire health risks are rising

Fire risk is increasing across North America as global temperatures rise and .

While air quality in most of the U.S. improved between 2000 and 2020, thanks to stricter emissions regulations on vehicles and power plants, in parts of the western U.S. Research has found that wildfire smoke has effectively of air quality progress there.

Our mark a new era in air quality forecasting, offering more accurate and timely information to better protect public health in the face of these escalating wildfire threats.

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