articles/ceaice/ceaice.tex

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\title{A Dynamic-Thermodynamic Sea ice Model for Ocean Climate
  Estimation on an Arakawa C-Grid}

\author{Martin Losch, Dimitris Menemenlis, Patrick Heimbach, \\
        Jean-Michel Campin, and Chris Hill}
\begin{document}

\maketitle

\input{ceaice_abstract.tex}

\input{ceaice_intro.tex}

\input{ceaice_model.tex}

\input{ceaice_forward.tex}

\input{ceaice_adjoint.tex}

\input{ceaice_concl.tex}

\appendix
\input{ceaice_appendix.tex}

\paragraph{Acknowledgements}
We thank Jinlun Zhang for providing the original B-grid code and many
helpful discussions. ML thanks Elizabeth Hunke for multiple explanations.

This work is a contribution to Estimating the Circulation and Climate of the
Ocean, Phase II (ECCO2).  The ECCO2 project (http://ecco2.org/) is sponsored
by the NASA Modeling Analysis and Prediction (MAP) program.  D. Menemenlis
carried out this work at the Jet Propulsion Laboratory, California Institute
of Technology under contract with the National Aeronautics and Space
Administration.

\bibliography{bib/journal_abrvs,bib/seaice,bib/genocean,bib/maths,bib/mitgcmuv,bib/fram,bib/mit_biblio}

\end{document}

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A Dynamic-Thermodynamic Sea ice Model for Ocean Climate
  Estimation on an Arakawa C-Grid

Introduction

Ice Model:
 Dynamics formulation.
  B-C, LSR, EVP, no-slip, slip
  parallellization
 Thermodynamics formulation.
  0-layer Hibler salinity + snow
  3-layer Winton

Idealized tests
 Funnel Experiments
 Downstream Island tests
  B-grid LSR no-slip
  C-grid LSR no-slip
  C-grid LSR slip
  C-grid EVP no-slip
  C-grid EVP slip

Arctic Setup
 Configuration
 OBCS from cube
 forcing
 1/2 and full resolution
 with a few JFM figs from C-grid LSR no slip
  ice transport through Canadian Archipelago
  thickness distribution
  ice velocity and transport

Arctic forward sensitivity experiments
 B-grid LSR no-slip
 C-grid LSR no-slip
 C-grid LSR slip
 C-grid EVP no-slip
 C-grid EVP slip
 C-grid LSR no-slip + Winton
  speed-performance-accuracy (small)
  ice transport through Canadian Archipelago differences
  thickness distribution differences
  ice velocity and transport differences

Adjoint sensitivity experiment on 1/2-res setup
 Sensitivity of sea ice volume flow through Fram Strait
*** Sensitivity of sea ice volume flow through Canadian Archipelago

Summary and conluding remarks
1	mlosch	1.21	% $Header: /u/gcmpack/MITgcm_contrib/articles/ceaice/ceaice.tex,v 1.20 2008/03/25 22:04:31 heimbach Exp $
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3	dimitri	1.1	\documentclass[12pt]{article}
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11	dimitri	1.1
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16	mlosch	1.19	\usepackage{url}
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18	dimitri	1.1	% math abbreviations
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45			% commenting scheme
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47	dimitri	1.1
48			\title{A Dynamic-Thermodynamic Sea ice Model for Ocean Climate
49			Estimation on an Arakawa C-Grid}
50
51			\author{Martin Losch, Dimitris Menemenlis, Patrick Heimbach, \\
52			Jean-Michel Campin, and Chris Hill}
53			\begin{document}
54
55			\maketitle
56
57	dimitri	1.17	\input{ceaice_abstract.tex}
58
59			\input{ceaice_intro.tex}
60
61			\input{ceaice_model.tex}
62
63			\input{ceaice_forward.tex}
64	dimitri	1.1
65	dimitri	1.17	\input{ceaice_adjoint.tex}
66	dimitri	1.1
67	dimitri	1.17	\input{ceaice_concl.tex}
68	dimitri	1.1
69	mlosch	1.21	\appendix
70			\input{ceaice_appendix.tex}
71
72	dimitri	1.1	\paragraph{Acknowledgements}
73			We thank Jinlun Zhang for providing the original B-grid code and many
74	mlosch	1.6	helpful discussions. ML thanks Elizabeth Hunke for multiple explanations.
75	dimitri	1.1
76	dimitri	1.18	This work is a contribution to Estimating the Circulation and Climate of the
77			Ocean, Phase II (ECCO2). The ECCO2 project (http://ecco2.org/) is sponsored
78			by the NASA Modeling Analysis and Prediction (MAP) program. D. Menemenlis
79			carried out this work at the Jet Propulsion Laboratory, California Institute
80			of Technology under contract with the National Aeronautics and Space
81			Administration.
82
83	heimbach	1.20	\bibliography{bib/journal_abrvs,bib/seaice,bib/genocean,bib/maths,bib/mitgcmuv,bib/fram,bib/mit_biblio}
84	dimitri	1.1
85			\end{document}
86
87			%%% Local Variables:
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91	mlosch	1.4
92
93			A Dynamic-Thermodynamic Sea ice Model for Ocean Climate
94			Estimation on an Arakawa C-Grid
95
96			Introduction
97
98			Ice Model:
99			Dynamics formulation.
100			B-C, LSR, EVP, no-slip, slip
101			parallellization
102			Thermodynamics formulation.
103			0-layer Hibler salinity + snow
104			3-layer Winton
105
106			Idealized tests
107			Funnel Experiments
108			Downstream Island tests
109			B-grid LSR no-slip
110			C-grid LSR no-slip
111			C-grid LSR slip
112			C-grid EVP no-slip
113			C-grid EVP slip
114
115			Arctic Setup
116			Configuration
117			OBCS from cube
118			forcing
119			1/2 and full resolution
120			with a few JFM figs from C-grid LSR no slip
121			ice transport through Canadian Archipelago
122			thickness distribution
123			ice velocity and transport
124
125			Arctic forward sensitivity experiments
126			B-grid LSR no-slip
127			C-grid LSR no-slip
128			C-grid LSR slip
129			C-grid EVP no-slip
130			C-grid EVP slip
131			C-grid LSR no-slip + Winton
132			speed-performance-accuracy (small)
133			ice transport through Canadian Archipelago differences
134			thickness distribution differences
135			ice velocity and transport differences
136
137			Adjoint sensitivity experiment on 1/2-res setup
138			Sensitivity of sea ice volume flow through Fram Strait
139			*** Sensitivity of sea ice volume flow through Canadian Archipelago
140
141			Summary and conluding remarks