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The Dependence of Emissivity on Sand Moisture Content. By: Emily Teske Meteorology Department of Marine and Environmental Systems Florida Institute of Technology. Objective. Measure the Emissivity of Wet, Damp, and Dry sand Compare these measured emissivities to previous studies
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The Dependence of Emissivity on Sand Moisture Content By: Emily Teske Meteorology Department of Marine and Environmental Systems Florida Institute of Technology
Objective • Measure the Emissivity of Wet, Damp, and Dry sand • Compare these measured emissivities to previous studies • Dry = 0.90 and Wet = 0.94-0.96
Emissivity • Measure of how efficiently an object radiates energy compared to a blackbody (=1) at the same temperature and a given wavelength • Emissivity = 1 means that object radiates all energy absorbed • The smaller the emissivity value the more energy absorbed
Motivation • No known published values for damp sand • Emissivity important for the surface energy budget (skin temperature) • Important for remote-sensing • Biological impact (flora and fauna of the dune environment)
Sampling Methods • Use two-meter dipstick and handheld IR thermometer to measure the temperature of the sand. • Temperature of wet, damp, and dry sand was taken Image From: http://www.az-instrument.com.tw/en/productsinfo/135.html
IR Thermometer gives temperature at the surface. Temp Probes Measure temperature 1cm below the surface.
What the IR Measures • IR thermometer measures the irradiance (I) of the surface for a given wavelength window • Uses the Stefan-Boltzmann Equation to output a temperature • Where ε is the pre-set emissivity of the IR thermometer (=1) • The temperature may be wrong depending on what the actual emissivity of the surface is
How to get Emissivity • Use the temperature probes to get a temperature not dependent on a known emissivity • Use the irradiance (I) from the IR thermometer and temperature (T) from temperature probes to calculate an actual emissivity (ε) Irradiance Measured by IR Temp measured By Probes
Data Analysis • Temperature correction was needed since two-meter dipstick temperature probes were slightly under the surface (~ 1 cm) • Additional Correction was needed for cloud cover • The adjusted temperatures were then used to calculate emissivity
Before sunrise Peak solar Our Measurements From: Tang et al 1999
Temperature Correction • A temperature soil profile model was used to adjust temperatures • The ΔT equation below was used • ΔT is the difference between the surface temperature and the temperature at depth , z, below the surface • A is the diurnal amplitude (°C) of the temperature • A=30 for dry sand, 15 for damp sand, and 10 for wet sand
4.45 °C • The measured temperature was 49.9°C and emissivity 0.963. • The adjusted temperature is 54.3°C lowering emissivity to 0.910
Cloud Correction • assumed that the full A (amplitude) of the temperature correction would be too large in the presence of clouds • A ratio of the actual-theoretical solar radiation was taken • This ratio was then multiplied by the ΔT value obtained from plot
ΔT = 5.25°C New ΔT = 4.6°C Avg = 825 Wm-2 Avg = 688 Wm-2
Cloud Correction Example • ΔT without cloud correction = 5.25°C • Actual-theoretical ratio found to be 0.83 • New ΔT = 4.36° • The adjusted temperature would then be 57.4°C rather than 58.25°C (ε= 0.914,0.890)
Wet Damp Dry Wet Damp Dry
Conclusion • Measured emissivity values were slightly higher than published values • Temperature corrections improved emissivity estimates • The damp sand emissivity fell between that of wet and dry sand as expected • Other factors to be considered: sand moisture content, sand grain size/type, color
Questions? Next: Jeremy Fimat