Fires

Fires can be set naturally, such as by lightning, or by humans, whether intentionally or accidentally. Fire is often thought of as a menace and detriment to life, but in some ecosystems it is necessary to maintain the equilibrium, for example, some plants only release seeds under high temperatures that can only be achieved by fire, fires can also clear undergrowth and brush to help restore forests to good health, humans use fire in slash and burn agriculture, to clear away last year’s crop stubble and provide nutrients for the soil and to clear areas for pasture. The fire layer is useful for studying the spatial and temporal distribution of fire, to locate persistent hot spots such as volcanoes and gas flares, to locate the source of air pollution from smoke that may have adverse human health impacts.

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• Learn more: NASA Wildfire Toolkit and Wildfires Data Pathfinder

MODIS and VIIRS active fire/hotspot locations are made available through the Land, Atmosphere Near real-time Capability for EOS (LANCE) Fire Information for Resource Management System (FIRMS).

Fire Information for Resource Management System (FIRMS)

Aerosol Index

Aerosols absorb and scatter incoming sunlight, which reduces visibility and increases the optical depth. Aerosols have an effect on human health, weather and the climate. Sources of aerosols include pollution from factories, smoke from fires, dust from dust storms, sea salts, and volcanic ash and smog. Aerosols compromise human health when inhaled by people with asthma or other respiratory illnesses. Aerosols also have an affect on the weather and climate by cooling or warming the earth, helping or preventing clouds from forming.

Satellite-derived Aerosol Index products are useful for identifying and tracking the long-range transport of volcanic ash from volcanic eruptions, smoke from wildfires or biomass burning events and dust from desert dust storms, even tracking over clouds and areas of snow and ice.

Product: Instrument (Platform) and Download Link	Description	Browse imagery in Worldview
OMI (Aura) OMAERUV	The Ozone Monitoring Instrument (OMI) Aerosol Index (AI) indicates the presence of ultraviolet (UV)-absorbing particles in the air (aerosols) such as desert dust and soot particles in the atmosphere. The sensor resolution is 25 km, imagery resolution is 2 km, and the temporal resolution is daily. L2 Near UV Aerosol Optical Depth and Single Scattering Albedo Swath 13x24 km.	Aerosol Index UV Aerosol Index
OMPS (Suomi NPP) NMMIEAI-L2-NRT	The Ozone Mapping and Profiler Suite (OMPS) Aerosol Index (AI) indicates the presence of UV-absorbing particles in the air (aerosols) such as desert dust and soot particles in the atmosphere. The unitless range of the AI is from 0.00 to >=5.00, where 5.0 indicates heavy concentrations of aerosols that could reduce visibility or impact human health and this satisfies the needs of most users. However, the AI signal for pyrocumulonimbus (pyroCb) events, which are both dense and high in the atmosphere, can be much larger than 5.0. To provide better near real-time imagery for these high AI events, the pyroCb product has an upper AI limit of 50.0. The sensor resolution is 50 km, imagery resolution is 2 km, and the temporal resolution is daily. OMPS-NPP L2 NM Aerosol Index swath orbital NRT	Aerosol Index Aerosol Index (Pyrocumulonimbus)

Aerosol Optical Depth

Aerosol Optical Depth (AOD) (or Aerosol Optical Thickness) indicates the level at which particles in the air (aerosols) prevent light from traveling through the atmosphere. Aerosols scatter and absorb incoming sunlight, which reduces visibility. From an observer on the ground, an AOD of less than 0.1 is “clean” - characteristic of clear blue sky, bright sun and maximum visibility. As AOD increases to 0.5, 1.0, and greater than 3.0, aerosols become so dense that sun is obscured. Sources of aerosols include pollution from factories, smoke from fires, dust from dust storms, sea salt, and volcanic ash and smog. Aerosols compromise human health when inhaled by people, particularly those with asthma or other respiratory illnesses. Aerosols also have an effect on the weather and climate by cooling or warming the earth, helping or preventing clouds from forming. Since aerosols are difficult to identify when they occur over different types of land surfaces and ocean surfaces, Worldview provides several different types of imagery layers to assist in the identification.

Product: Instrument (Platform) and Download Link	Description	Browse imagery in Worldview
MODIS (Terra) MOD04_L2 MODIS (Aqua) MYD04_L2	Moderate Resolution Imaging Spectroradiometer (MODIS (Terra)) L2 Aerosol, 5-Min Swath 10km doi:10.5067/MODIS/MOD04_L2.NRT.061 MODIS (Aqua) L2 Aerosol, 5-Min Swath 10km doi:10.5067/MODIS/MYD04_L2.NRT.061	Aerosol Optical Depth (AOD) AOD 3km (Land and Ocean) Deep Blue Aerosol Angstrom Exponent (Land) Dark Target Aerosol Angstrom Exponent (Ocean) Deep Blue AOD (Land) Merged DT/DB Aerosol Optical Depth (Land and Ocean)
MODIS (Terra/Aqua) MCDAODHD MODIS (Aqua) MYDAODHD MODIS (Terra) MODAODHD	L3 Value-added Aerosol Optical Depth MODIS (combined) doi:10.5067/MODIS/MCDAODHD.NRT.061 MODIS (Aqua) doi:10.5067/MODIS/MYDAODHD_NRT.061 MODIS (Terra) doi:10.5067/MODIS/MODAODHD.NRT.061	Value Added AOD
MODIS (Terra/Aqua) MCD19A2N	L2G Multi-Angle Implementation of Atmospheric Correction (MAIAC) Land Aerosol Optical Depth MODIS/Terra+Aqua Land Aerosol Optical Depth Daily L2G Global 1km SIN Grid doi:10.5067/MODIS/MCD19A2N.NRT.061	MAIAC Aerosol Optical Depth
VIIRS (Suomi NPP) AERDB_L2_VIIRS_SNPP_NRT	VIIRS/Suomi NPP Deep Blue Aerosol L2 6-Min Swath 6 km doi:10.5067/VIIRS/AERDB_L2_VIIRS_SNPP_NRT.011	Deep Blue Aerosol Optical Thickness Deep Blue Aerosol Angstrom Exponent

Carbon Monoxide

Carbon Monoxide (CO) is a poisonous, odorless and colorless gas. CO is produced by incomplete combustion of fossil fuels and biomass burning. It is one of the longest-lived, naturally occurring atmospheric carbon compounds. CO is a trace gas produced by methane oxidation, fossil fuel consumption (emitted from factories and cars) and biomass burning (from forest fires and agricultural burning). These measurements are useful for analyzing the distribution, transport, sources and sinks of CO in the troposphere and can be used to observe how it interacts with land and ocean biospheres. CO hinders the atmosphere’s natural ability to rid itself of harmful pollutants.

Product: Instrument (Platform) and Download Link	Description	Browse imagery in Worldview
AIRS (Aqua) AIRS2RET_NRT.007	The Atmospheric Infrared Sounder (AIRS) Carbon Monoxide (CO) Total Column (Day/Night) layer indicates the amount of Carbon Monoxide (CO) in the total vertical column profile of the atmosphere (from Earth’s surface to top-of-atmosphere) and is measured in parts per billion by volume (ppbv).The imagery resolution is 2 km and sensor resolution is 45 km. L2 standard retrieval product using AIRS IR only	CO Total Column (Day|Night)
MLS (Aura) ML2CO_NRT.005	The Microwave Limb Sounder (MLS) Carbon Monoxide (CO) Mixing Ratio layer at 215 hPa (hectopascals) indicates carbon monoxide levels at the vertical atmospheric pressure level of 215hPa, and is measured in parts per billion by volume (ppbv). L2 Carbon Monoxide (CO) MLS/Aura NRT L2 CO Mixing Ratio	CO (215 hPa, Day/Night)
MOPITT (Terra) MOP02R_NRT	The Measurements of Pollution in the Troposphere (MOPITT) Carbon Monoxide (Level 2, Daily, Day/Night, Total Column) layer shows the amount of carbon monoxide (CO) present in the total vertical column of the lower atmosphere (troposphere) and is measured in mole per square centimeter (mol/cm2) for the Day and Night overpasses, in near real-time (NRT). MOPITT NRT measurements use thermal-infrared radiation at 4.7 µm to produce CO total column abundance. MOPITT NRT Level 2 CO vertical profiles derived from Thermal Infrared Radiances	CO (Level 2, Daily, Day/Night, Total Column)

Corrected Reflectance Imagery

MODIS and VIIRS Corrected Reflectance imagery are available only as near real-time imagery. The imagery can be visualized in Worldview and Global Imagery Browse Services (GIBS).

Information on MODIS Corrected Reflectance Imagery layers including:

• Corrected Reflectance True Color (Bands 1-4-3),
• Corrected Reflectance (Bands 3-6-7)
• Corrected Reflectance (Bands 7-2-1)

Information on VIIRS Corrected Reflectance Imagery layers including:

• Corrected Reflectance True Color (Bands I1-M4-M3),
• Corrected Reflectance (Bands M3-I3-M11)
• Corrected Reflectance (Bands M11-I2-I1)

Browse Corrected Reflectance imagery in Worldview

For more on the difference between Corrected Reflectance and Surface Reflectance Imagery

Fire

The VIIRS and MODIS Fire and Thermal Anomalies layer shows active fire detections and thermal anomalies, such as volcanoes, and gas flares. Fires can be set naturally, such as by lightning, or by humans, whether intentionally or accidentally. Fire is often thought of as a menace and detriment to life, but in some ecosystems it is necessary to maintain the equilibrium, for example, some plants only release seeds under high temperatures that can only be achieved by fire, fires can also clear undergrowth and brush to help restore forests to good health, humans use fire in slash and burn agriculture, to clear away last year’s crop stubble and provide nutrients for the soil and to clear areas for pasture. The fire layer is useful for studying the spatial and temporal distribution of fire, to locate persistent hot spots such as volcanoes and gas flares, to locate the source of air pollution from smoke that may have adverse human health impacts.

Product: Instrument (Platform) and Download Link	Description	Browse imagery in Worldview
MODIS (Aqua) MYD14 MODIS (Terra) MOD14	The MODIS Fire and Thermal Anomalies product is available from the Terra (MOD14) and Aqua (MYD14) satellites as well as a combined Terra and Aqua (MCD14) satellite product. The thermal anomalies are represented as red points (approximate center of a 1 km pixel) in Worldview/GIBS. doi:10.5067/MODIS/MYD14.NRT.061 (Aqua) doi:10.5067/MODIS/MOD14.NRT.061 (Terra)	MODIS Fires and Thermal Anomalies (Day/Night)
VIIRS (Suomi NPP) VNP14IMG_NRT VIIRS (NOAA-20) VJ114IMG_NRT	The VIIRS 375m I-band fire detections complements the MODIS fire detections; they both show good agreement in hotspot detection but the improved spatial resolution of the 375m data provides a greater response over fires of relatively small areas and provides improved mapping of large fire perimeters. The 375m data also has improved nighttime performance. Consequently, these data are well suited for use in support of fire management (e.g., near real-time alert systems), as well as other science applications requiring improved fire mapping fidelity.The thermal anomalies are represented as red points (approximate center of a 375 m pixel). VIIRS/Suomi NPP Active Fires 6-Min L2 Swath 375m NRT VIIRS/JPSS1 Active Fires 6-Min L2 Swath 375m NRT	VIIRS Thermal Anomalies (Day/Night)

Land Surface Reflectance

Product: Instrument, Platform and Download Link	Description	Browse imagery in Worldview
MODIS (Aqua) MYD09 MODIS (Terra) MOD09	doi:10.5067/MODIS/MYD09.NRT.061 (Aqua) and doi:10.5067/MODIS/MOD09.NRT.061 (Terra) More information on MODIS Land Surface Reflectance Products including: MODIS (Aqua/Terra) Land Surface Reflectance True Color (Bands 1-4-3) MODIS (Aqua/Terra) Land Surface Reflectance True Color (Bands 7-2-1) MODIS (Aqua/Terra) Land Surface Reflectance True Color (Bands 1-2-1)	True Color Bands 1-2-1 Bands 7-2-1
VIIRS (Suomi NPP) VNP09_NRT	VIIRS Land Surface Reflectance The VIIRS Surface Reflectance provides continuity with the EOS-MODIS Land Surface Reflectance product.The Suomi NPP/VIIRS surface reflectance products are estimates of surface reflectance in each of the VIIRS reflective bands I1-I3, M1-M5, M7, M8, M10, and M11. Surface reflectance for each moderate-resolution (750m) or imagery-resolution (375m) pixel is retrieved separately for the Level-2 products and is obtained by adjusting top-of-atmosphere reflectance to compensate for atmospheric effects. Corrections are made for the effects of molecular gases, including ozone and water vapor, and for the effects of atmospheric aerosols. The inputs to the surface reflectance algorithm include top-of-atmosphere reflectance for the VIIRS visible bands (VNP02MOD, VNP02IMG), the VIIRS cloud mask and aerosol product (NPP-CMIP_L2), aerosol optical thickness (NPP_VAOTIP_L2, NPP_VAMIP_L2), and atmospheric data obtained from a reanalysis (surface pressure, atmospheric precipitable water, and ozone concentration). All surface reflectance products are produced for daytime conditions only.	Coming soon

Land Surface Temperature

Land Surface Temperature layer shows the temperature of the land surface in Kelvin (K). This measurement differs from air temperature measurements as it provides the temperature of whatever is on the surface of the earth for example, bare sand in the desert, ice and snow covered area, a leaf covered tree canopy and even the temperature of man-made buildings and roads. Land Surface Temperature is useful for monitoring changes in weather and climate patterns and used in agriculture to allow farmers to evaluate water requirements for wheat, or determine frost damage in orange groves.

Product: Instrument, Platform and Download Link	Description	Browse imagery in Worldview
MODIS (Terra) MOD11_L2 MODIS (Aqua) MYD11_L2	MODIS Land Surface Temperature and Emissivity The MODIS Land Surface Temperature and Emissivity (LST&E) product is available from both Terra and Aqua satellites. The sensor and imagery resolution is 1 km, and the temporal resolution is daily. doi:10.5067/MODIS/MOD11_L2.NRT.061 and doi:10.5067/MODIS/MYD11_L2.NRT.061	Land Surface Temp (Day/Night)
VIIRS (Suomi NPP) VNP21_NRT	VIIRS Land Surface Temperature and Emissivity VIIRS/Suomi NPP Land Surface Temperature and Emissivity 6-Min L2 Swath 750m NRT products doi:10.5067/VIIRS/VNP21_NRT.001	Coming soon.

Sulfur Dioxide

Sulfur Dioxide (SO₂), is a colorless gas with a pungent, suffocating odor that is water soluble to produce the acid, H₂SO₃. SO₂ is one of the US Environmental Protection Agency's (EPA) six major regulated criteria pollutants (Tropospheric Ozone, Nitrogen dioxide, Sulfur dioxide, Lead, PM2.5 and PM10 particulates). It irritates the eyes, nose, and lungs. High concentrations of SO₂ can result in temporary breathing impairment. It is produced by combustion of coal, fuel oil, and gasoline, since these fuels contain sulfur in the combustion, and in the oxidation of naturally occurring sulfur gases. It is a precursor to sulfuric acid (H₂SO₄), which is a major constituent of acid rain. SO₂ is injected into the stratosphere by volcanic eruptions. SO₂ also is a major precursor to PM2.5 (Particulate Matter up to 2.5 micrometers in size), which is a significant health concern, and a main contributor to poor visibility. These data are used by the Volcanic Ash Advisory Centers in advisories to airlines for operational decisions.

Product: Instrument, Platform and Download Link	Description	Browse imagery in Worldview
AIRS (Aqua) AIRIBRAD_NRT.005	The AIRS Prata SO2 Index Day/Night layer indicates Sulfur Dioxide column amounts in the atmosphere, measured in Dobson Units (DU); it is science parameter is a derived parameter from the Level 1B Near-Real Time Infrared (IR) geolocated and calibrated radiances, (AIRIBRAD_NRT). The imagery resolution is 2 km and sensor resolution is 45 km. The temporal resolution is daily. L1B IR geolocated radiances	Sulfur Dioxide (Day/Night Prata Algorithm)
MLS (Aura) ML2SO2_NRT.005	The MLS Sulfur Dioxide (SO2) Mixing Ratio layer at 147hPa (hectopascals) indicates sulfur dioxide levels at the vertical atmospheric pressure level of 147hPa, and is measured in parts per billion by volume (ppbv). The sensor resolution is 5 km, imagery resolution is 2 km and the temporal resolution is twice daily (day and night). MLS/Aura NRT L2 SO2 Mixing Ratio	Sulfur Dioxide (147 hPa, Day/Night)
OMI (Aura) OMSO2NRTb	The OMI Sulfur Dioxide (SO2) Lower Troposphere layer indicates the column density of sulfur dioxide in the lower troposphere (corresponding to 2.5 km center of mass altitude (CMA)) and is measured in Dobson Units (DU). Sulfur Dioxide and Aerosol Index products are used to monitor volcanic clouds and detect pre-eruptive volcanic degassing globally. L2 Sulfur Dioxide (SO2) Total Column Swath 13x24 km SO2 Planetary Boundary Layer Measures the tropospheric boundary-layer component of the total SO2 column measured in Dobson Units (DU). SO2 Lower Troposphere Indicates the column density of SO2 in the lower troposphere (corresponding to 2.5 km center of mass altitude (CMA)). SO2 Middle Troposphere Indicates the column density of sulfur dioxide in the middle troposphere (corresponding to 7.5 km center of mass altitude (CMA)). SO2 Upper Troposphere and Stratosphere layer Indicates the column density of sulfur dioxide in the upper troposphere and stratosphere (corresponding to 17 km center of mass altitude (CMA)) and is measured in Dobson Units (DU).	SO2 Planetary Boundary layer Lower Troposphere Middle Troposphere Upper Troposphere and Stratosphere
OMPS (Suomi NPP) NMSO2-PCA-L2-NRT	OMPS NRT products complement the sulfur dioxide NRT data already available from OMI OMPS/Suomi NPP PCA SO2 Total Column 1-Orbit L2 Swath 50x50km NRT	SO2 Planetary Boundary layer Lower Troposphere Middle Troposphere Upper Troposphere and Stratosphere

Image

Visualize the Marshall Fire, Colorado in Worldview

On December 30, 2021, high winds roared out of the west and down the front slope of the Rocky Mountains in Colorado. Northwest of Denver, peak gusts reached 115 miles (185 kilometers) per hour—the equivalent of a category 3 hurricane. Those winds whipped up intense grass and brush fires in south Boulder and blew them east toward the towns of Superior and Louisville, igniting a firestorm. The Marshall Fire is now the most destructive in the state’s history. Read more about the Marshall Fire at NASA's Earth Observatory.