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Collaborative Research on Sunlight and the Arctic Atmosphere-Ice-Ocean System ( AIOS )

Collaborative Research on Sunlight and the Arctic Atmosphere-Ice-Ocean System ( AIOS ). Hajo Eicken Univ. of Alaska Fairbanks. Bonnie Light Univ. of Washington. Kathy Jones CRREL. Rebecca Woodgate Univ. of Washington. Kay Runciman Univ. of Washington. Jeremy Harbeck UAF.

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Collaborative Research on Sunlight and the Arctic Atmosphere-Ice-Ocean System ( AIOS )

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  1. Collaborative Research on Sunlight and the Arctic Atmosphere-Ice-Ocean System (AIOS) Hajo Eicken Univ. of Alaska Fairbanks Bonnie Light Univ. of Washington Kathy Jones CRREL Rebecca Woodgate Univ. of Washington Kay Runciman Univ. of Washington Jeremy Harbeck UAF John Weatherly CRREL Don Perovich CRREL The AIOS sunlight team

  2. Goals • Enhance our understanding of the present role that solar radiation plays in the Arctic AIOS • Improve our ability to predict its future role. • Determine spatially and temporally the partitioning of solar energy Sunlight and the Arctic AIOS Where does all the sunlight go?

  3. Transmitted Where does all the sunshine go? Incident Reflected Atmosphere Reflected Absorbed Ice Transmitted Ocean Incident = reflected + absorbed + transmitted • Only three possible fates for sunlight • reflected back to atmosphere • absorbed in snow and ice • transmitted to ocean • Determine over large scale How hard can it be?

  4. May Temporal and spatial variability June July August September

  5. Pan – Arctic over ocean • All on 25 x 25 km EASE grid • (Equal Area Scalable Earth) • Generate description of solar partitioning • Daily values from 1979 to 2007 of • Incident solar energy • Reflected solar energy • Absorbed in snow and ice, • Transmitted to ocean • Spectral, integrated, PAR Region of Interest EASE grid over the Arctic Basin…from 1979 to 2007…daily

  6. Solar input to open water • Input: • Incident (Fr) from ERA-40 • Ice concentration (C) • Water albedo (a) = 0.07 • Output: • Solar input to the ocean (Fw) • Fw = Fr (1 – a) (1 – C) • Assume ice is opaque, for now Incident solar, ice concentration, and albedo -> heat input

  7. 27 year trend of annual ocean solar heat input Units are percent per year Increasing solar heat input in 85% of area

  8. Solar partitioning by ice • Reflected • Absorbed • Transmitted • Input from: • process studies • field experiments • models • satellites • Snow depth and ice thickness distributions • Timing of onset of melt and freezeup • Seasonal evolution of ice albedo • Pond evolution • Every day, over the entire grid Next step: the ice Dry snow Melting snow Pond evolution Fall freezeup Pond evolution Do the hard part

  9. Scientific community • Archived datasets • Web site • Map based • One click to data • Integrated datasets will benefit • Sea ice mass balance • Oceanography • Atmospheric chemistry • Large-scale modeling • Future field planning • Public • General interest article on ice-albedo feedback • Public lectures • K-5 synthesis puzzles Outreach Synthesize and collaborate

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