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Landsat-based thermal change of Nisyros Island (volcanic). Thermal Remote Sensing. Distinguishing materials on the ground using differences in emissivity and temperature. Thermal = Emitted Infrared. IR = 0.76 um to 1000 um Reflective IR = 0.7 – 3.0 um
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Thermal Remote Sensing Distinguishing materials on the ground using differences in emissivity and temperature
Thermal = Emitted Infrared • IR = 0.76 um to 1000 um • Reflective IR = 0.7 – 3.0 um • Thermal IR for remote sensing = 7 – 18 um • Sometimes called far IR (vs. near and mid IR) • Experiences almost no atmospheric scattering • But…lots of absorption by atmospheric gases (e.g., CO2) • Must use atmospheric windows for rem. sens.
The Infrared portion of the electromagnetic spectrum Emitted Thermal
Thermal Properties of Objects • All objects with temperature > 0o K emit thermal radiation • Amount depends on temperature (Stefan-Boltzman Law) • M = εσT4 • Peak wavelength emitted also depends on temperature (Wien’s Displacement Law) • Peak λ(µm) = 3000/T(oK)
Emissivity • Emissivity is the ratio of the energy emitted byan object to that of a Black Body at the same temperature • A black body has ε = 1 • A white body has ε = 0 • Water has ε close to 1 • Most vegetation has ε close to 1 • Many minerals have ε << 1 • Depends on wavelength • Can find tables of emissivities in reference books and textbooks
Kinetic Temperature vs. Radiant Temperature • Kinetic temperature is caused by the vibration of molecules • sometimes called “true temperature” • measured using conventional temperature scales (e.g. oF, oC, oK) • Radiant temperature is the emitted energy of an object • sometimes called “apparent temperature” • what we measure with thermal remote sensing • depends on kinetic temperature and emissivity
Thermal Remote Sensing • Incoming radiation from the sun is absorbed (converted to kinetic energy) and object emits EMR • Objects vary in the amount of sun they “see” (different slopes, etc.) and in their emissivity • Thermal remote sensing is sensitive to differences in emissivity.
Interpreting Thermal Images • Thermal images are often single-band and so displayed as monochrome images. • Bright areas = relatively warmer places • Dark areas = relatively cooler places • Can be the opposite for thermal weather images! • Must know if the image is a negative or a positive! • Should know the time of day the image was acquired – day vs. night alters the interpretation
Atlanta -- Daytime Atlanta -- Nighttime
North Thermal Infrared Multispectral Scanner (TIMS) image of Death Valley Daytime Positive – Bright = warm, Dark = cool
Multi-band thermal • Thermal imagery can also be multi-band (different parts of the thermal IR spectrum) • When displayed in color, colors primarily represent differences in emissivity.
North TIMS image of Death Valley made by combining thermal bands from different wavelengths after “decorrelation stretching”
Interpretation (cont.) • It is difficult to accurately calculate the kinetic temperature of objects from their radiant temperature • Must know the emissivity of the target(s) • Often have to estimate or assume emissivity values
Complicating Factors • Topography (effects amount of incoming radiation from sun) • Fine scale differences in emissivities of materials in scene • Cloud cover history • Precipitation history – differences in soil moisture • Vegetation canopy geometry • Geothermal areas • Many others
Thermal Sensors • Thermal Infrared Multispectral Scanner (TIMS) (Airborne – 18 m spatial res.) • Landsat 3 MSS (237 m spatial resolution) • Landsat TM (Band 6) (120 m spatial) • Landsat 8 (Bands 10 & 11) (100 m spatial) • Landsat ETM+ (Band 6) (60 m spatial) • ASTER (5 thermal bands at 90 m spatial) • MODIS (many thermal bands at 1 km spatial resolution) • Many others…
Applications • Agricultural water stress (energy balance) • Heat loss from urban areas • Identifying and mapping materials based on their emissivities (e.g. minerals) • Earthquake and volcanic activity prediction • Mapping moisture amounts • Ocean current mapping • Plumes of warm water from power plants, etc. • Atmospheric studies, weather forecasting, etc.
Evapotranspiration (ET) estimation using thermal RS • If you know how much energy is being used to evaporate water, you can estimate how much water is evaporating! E = H + L + r + G Where E = irradiance, H = sensible heat, L = latent heat, r = reflected energy, and G = ground storage of energy.
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Airborne thermal image of warm creek flowing into ocean near Anchorage, AK
ASTER images of San Francisco. Bottom right is thermal image used for water temperature
Summary – Thermal Remote Sensing • Typically used to map surface materials that differ in thermal properties (like emissivity) • Usually NOT used to map absolute kinetic temperature • Many applications but not especially good for distinguishing among vegetation types because all veg has about the same emissivity • Gives us another tool to help distinguish materials that may be spectrally similar in the reflected wavelengths!