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The Arctic Subpolar gyre sTate Estimate (ASTE): Description and assessment of a data-constrained, dynamically consistent ocean-sea ice estimate for 2002-2017
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  • An T Nguyen,
  • Helen Pillar,
  • Victor Ocaña,
  • Arash Bigdeli,
  • Timothy A Smith,
  • Patrick Heimbach,
  • Victor Ocaña,
  • Arash Bigdeli
An T Nguyen
University of Texas-Austin, University of Texas-Austin, University of Texas-Austin, University of Texas-Austin

Corresponding Author:[email protected]

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Helen Pillar
The University of Texas at Austin, The University of Texas at Austin, The University of Texas at Austin, The University of Texas at Austin
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Victor Ocaña
University of Texas at Austin, University of Texas at Austin, University of Texas at Austin
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Arash Bigdeli
University of Texas-Austin, University of Texas-Austin, University of Texas-Austin
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Timothy A Smith
University of Texas at Austin, University of Texas at Austin, University of Texas at Austin, University of Texas at Austin
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Patrick Heimbach
university of Texas at Austin, university of Texas at Austin, university of Texas at Austin, university of Texas at Austin
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Victor Ocaña
University of Texas at Austin
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Arash Bigdeli
University of Texas-Austin
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Abstract

A description and assessment of the first release of the Arctic Subpolar gyre sTate Estimate (ASTE_R1), a data-constrained ocean-sea ice model-data synthesis is presented. ASTE_R1 has a nominal resolution of 1/3o and spans the period 2002-2017. The fit of the model to an extensive (O(10^9)) set of satellite and in situ observations was achieved through adjoint-based nonlinear least-squares optimization. The improvement of the solution compared to an unconstrained simulation is reflected in misfit reductions of 77% for Argo, 50% for satellite sea surface height, 58% for the Fram Strait mooring, 65% for Ice Tethered Profilers, and 83% for sea ice extent. Exact dynamical and kinematic consistency is a key advantage of ASTE_R1, distinguishing the state estimate from existing ocean reanalyses. Through strict adherence to conservation laws, all sources and sinks within ASTE_R1 can be accounted for, permitting meaningful analysis of closed budgets at the grid-scale, such as contributions of horizontal and vertical convergence to the tendencies of heat and salt. ASTE_R1 thus serves as the biggest effort undertaken to date of producing a specialized Arctic ocean-ice estimate over the 21st century. Transports of volume, heat, and freshwater are consistent with published observation-based estimates across important Arctic Mediterranean gateways. Interannual variability and low frequency trends of freshwater and heat content are well represented in the Barents Sea, western Arctic halocline, and east subpolar North Atlantic. Systematic biases remain in ASTE_R1, including a warm bias in the Atlantic Water layer in the Arctic and deficient freshwater inputs from rivers and Greenland discharge.
May 2021Published in Journal of Advances in Modeling Earth Systems volume 13 issue 5. 10.1029/2020MS002398