the spectral and chemical measurement of light-absorbing

The spectral and chemical measurement of light - absorbing impurities on snow near South Pole, Antarctica Kimberly A. Casey 1,2 , Susan D. Kaspari 3 , S. McKenzie Skiles 4 , Karl Kreutz 5,6 , Michael J. Handley 5 1 Land Remote Sensing Program, USGS, 2 Cryospheric Sciences Lab, NASA GSFC, [email protected] , 3 Department of Geological Sciences, Central Washington University, 4 Department of Geography, University of Utah, 5 School of Earth and Climate Sciences, University of Maine, 6 Climate Change Institute, University of Maine Abstract Remote sensing of light-absorbing impurities such as black carbon (BC) and dust on snow is a key remaining challenge in cryospheric surface characterization. Snow purity and reflectivity affects local, regional and global radiative energy balance and is an important component of the climate system. We present a quantitative data set of in situ snow reflectance, measured and modeled albedo, and BC and trace element concentrations from clean to heavily fossil fuel emission contaminated snow near South Pole, Antarctica. Fig 1. Map of study sites Methods Over 1130 snow reflectance spectra (350-2500 nm) and 28 surface snow samples were collected at 7 distinct sites in the austral summer season of 2014-2015. Snow samples were analyzed for BC concentration via a single particle soot photometer (SP2), for trace element concentration via an inductively coupled plasma mass spectrometer (ICPMS), and imaged via an optical microscope. Fig 2. Spectral measurements, snow sampling for ICPMS, SP2 analytical chemistry, imaging Results Snow impurity concentrations ranged from 0.14 – 7000 ppb BC, 9.5 – 1200 ppb sulfur, 0.19 – 660 ppb iron, 0.043 – 6.2 ppb chromium, 0.13–120 ppb copper, 0.63 – 6.3 ppb zinc, 0.45 – 82 ppt arsenic, 0.0028 – 6.1 ppb cadmium, 0.062–22 ppb barium, and 0.0044 – 6.2 ppb lead. Broadband visible to shortwave infrared albedo ranged from 0.85 in pristine snow to 0.62 in contaminated snow. Light- absorbing impurity radiative forcing, the enhanced surface absorption due to BC and trace elements, spanned from < 1 W m -2 for clean snow to ~70 W m -2 for snow with high BC and trace element content. Recommendations Resolving light-absorbing impurities and concentrations on snow and ice remains challenging with most current satellite spectrometers. We recommend next generation sustainable land imaging sensors contain high spectral resolution in order to accurately measure and differentiate cryospheric impurities and snow grain size. Such sensor spectral improvements would also strengthen our ability to assess radiative impacts. We recommend snow albedo models improve representation of impurities from current broad mineral class estimations to more precise molecular and elemental based spectral absorption features. Fig 3. Snow spectral reflectance and modeled snow albedo Further details including snow trace element chemistry results are presented in: Casey, K. A., S. D. Kaspari, S. M. Skiles, K. Kreutz, M. J. Handley, 2017, The spectral and chemical measurement of pollutants on snow near South Pole, Antarctica, Journal of Geophysical Research Atmospheres, 122, doi:10.1002/2016JD026418. Contact email: [email protected] or [email protected] Landsat 8 bands View of runway and South Pole Station Site 1, clean air sector Site 5, aircraft runway SOUTH POLE, ANTARCTICA

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Page 1: The spectral and chemical measurement of light-absorbing

The spectral and chemical measurement of light-absorbing impurities on snow near South Pole, Antarctica

Kimberly A. Casey1,2, Susan D. Kaspari3, S. McKenzie Skiles4, Karl Kreutz5,6, Michael J. Handley51Land Remote Sensing Program, USGS, 2Cryospheric Sciences Lab, NASA GSFC, [email protected], 3Department of Geological Sciences, Central Washington University, 4Department of Geography, University of Utah, 5School of Earth and Climate Sciences, University of Maine, 6Climate Change Institute, University of Maine

AbstractRemote sensing of light-absorbing impurities such as black carbon(BC) and dust on snow is a key remaining challenge in cryosphericsurface characterization. Snow purity and reflectivity affects local,regional and global radiative energy balance and is an importantcomponent of the climate system. We present a quantitative dataset of in situ snow reflectance, measured and modeled albedo, andBC and trace element concentrations from clean to heavily fossilfuel emission contaminated snow near South Pole, Antarctica.

Fig 1. Map of study sites

MethodsOver 1130 snow reflectance spectra (350-2500 nm) and 28surface snow samples were collected at 7 distinct sites in theaustral summer season of 2014-2015. Snow samples wereanalyzed for BC concentration via a single particle sootphotometer (SP2), for trace element concentration via aninductively coupled plasma mass spectrometer (ICPMS), andimaged via an optical microscope.

Fig 2. Spectral measurements,snow sampling for ICPMS, SP2 analytical chemistry, imaging

ResultsSnow impurity concentrations ranged from 0.14 – 7000 ppb BC, 9.5– 1200 ppb sulfur, 0.19 – 660 ppb iron, 0.043 – 6.2 ppb chromium,0.13–120 ppb copper, 0.63 – 6.3 ppb zinc, 0.45 – 82 ppt arsenic,0.0028 – 6.1 ppb cadmium, 0.062–22 ppb barium, and 0.0044 – 6.2ppb lead. Broadband visible to shortwave infrared albedo rangedfrom 0.85 in pristine snow to 0.62 in contaminated snow. Light-absorbing impurity radiative forcing, the enhanced surfaceabsorption due to BC and trace elements, spanned from < 1 W m-2

for clean snow to ~70 W m-2 for snow with high BC and traceelement content.

RecommendationsResolving light-absorbing impurities and concentrations on snow andice remains challenging with most current satellite spectrometers. Werecommend next generation sustainable land imaging sensors containhigh spectral resolution in order to accurately measure anddifferentiate cryospheric impurities and snow grain size. Such sensorspectral improvements would also strengthen our ability to assessradiative impacts.

We recommend snow albedo models improve representation ofimpurities from current broad mineral class estimations to moreprecise molecular and elemental based spectral absorption features.

Fig 3. Snow spectral reflectance and modeled snow albedo

Further details including snow trace element chemistry results are presented in:

Casey, K. A., S. D. Kaspari, S. M. Skiles, K. Kreutz, M. J. Handley, 2017, The spectral and chemical measurement of pollutants on snow near South Pole, Antarctica, Journal of Geophysical Research Atmospheres, 122, doi:10.1002/2016JD026418.

Contact email: [email protected] or [email protected]

Landsat 8 bands

View of runway and South Pole Station

Site 1, clean air sector

Site 5, aircraft runway

SOUTH POLE, ANTARCTICA

mailto:[email protected]

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