ceaice_split_version/ceaice_part2/ceaice_part2.tex

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\begin{document}
\begin{frontmatter}
  \title{A Dynamic-Thermodynamic Sea Ice Model on an Arakawa C-Grid
for Coupled Ocean/Sea Ice Estimation. Part 2: Adjoint Sensitivities.}

  \author[MIT]{Patick Heimbach\thanksref{corrau}},
  \author[JPL]{Dimitris Menemenlis}, 
  \author[AWI]{Martin Losch},
  \author[MIT]{Jean-Michel Campin} and
  \author[MIT]{Chris Hill}
  \address[MIT]{Massachusetts Institute of Technology, EAPS, 77 Massachusetts
    Avenue, Cambridge, MA 02139, USA}
  \address[JPL]{Jet Propulsion Laboratory, 4800 Oak Grove Drive, Pasadena, CA 91109, USA}
  \address[AWI]{Alfred-Wegener-Institut f\"ur Polar- und Meeresforschung,
    Postfach 120161, 27515 Bremerhaven, Germany} 
  \thanks[corrau]{corresponding author, email:
    heimbach@mit.edu, \\\mbox{ph: +1-617-642-3481}, 
    \mbox{fax: +1-617-253-4464}}
  \begin{keyword}
    NUMERICAL SEA-ICE MODELING, ADJOINT MODELING, CANADIAN ARCTIC ARCHIPELAGO, \ldots
  \end{keyword}

\input{ceaice_abstract_part2.tex}
\end{frontmatter}

\linenumbers

\input{ceaice_intro_part2.tex}

\input{ceaice_adjoint.tex}

\input{ceaice_concl.tex}

\appendix
\input{ceaice_appendix_part2.tex}

~

\textbf{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 the ECCO Phase II (ECCO2) project sponsored
by the NASA Modeling Analysis and Prediction (MAP) program,
as well as the ECCO-GODAE project funded under the 
National Oceanographic Partnership Program (NOPP).
D.M. carried out this work at JPL/CalTech under contract with NASA.

\bibliography{../bib_ceaice/journal_abrvs,../bib_ceaice/seaice,../bib_ceaice/genocean,../bib_ceaice/maths,../bib_ceaice/mitgcmuv,../bib_ceaice/fram,../bib_ceaice/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	1.4	% $Header: /u/gcmpack/MITgcm_contrib/articles/ceaice_split_version/ceaice_part2/ceaice_part2.tex,v 1.3 2008/12/04 01:48:49 heimbach Exp $
2	heimbach	1.1	% $Name: $
3	heimbach	1.2	%\documentclass[12pt]{article}
4			\documentclass{elsart3p}
5			\usepackage[round,comma]{natbib}
6			\bibliographystyle{elsart-harv}
7	heimbach	1.1
8			\usepackage[]{graphicx}
9			%\usepackage[draft]{graphicx}
10			\usepackage{subfigure}
11	heimbach	1.2	%\usepackage[round,comma]{natbib}
12			%\bibliographystyle{../bib_ceaice/agu04}
13	heimbach	1.1
14			\usepackage{amsmath,amssymb}
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19
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46
47			% commenting scheme
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49
50	heimbach	1.2	\begin{document}
51			\begin{frontmatter}
52			\title{A Dynamic-Thermodynamic Sea Ice Model on an Arakawa C-Grid
53	heimbach	1.1	for Coupled Ocean/Sea Ice Estimation. Part 2: Adjoint Sensitivities.}
54
55	heimbach	1.2	\author[MIT]{Patick Heimbach\thanksref{corrau}},
56			\author[JPL]{Dimitris Menemenlis},
57			\author[AWI]{Martin Losch},
58			\author[MIT]{Jean-Michel Campin} and
59			\author[MIT]{Chris Hill}
60	heimbach	1.3	\address[MIT]{Massachusetts Institute of Technology, EAPS, 77 Massachusetts
61			Avenue, Cambridge, MA 02139, USA}
62			\address[JPL]{Jet Propulsion Laboratory, 4800 Oak Grove Drive, Pasadena, CA 91109, USA}
63	heimbach	1.2	\address[AWI]{Alfred-Wegener-Institut f\"ur Polar- und Meeresforschung,
64			Postfach 120161, 27515 Bremerhaven, Germany}
65			\thanks[corrau]{corresponding author, email:
66			heimbach@mit.edu, \\\mbox{ph: +1-617-642-3481},
67			\mbox{fax: +1-617-253-4464}}
68			\begin{keyword}
69			NUMERICAL SEA-ICE MODELING, ADJOINT MODELING, CANADIAN ARCTIC ARCHIPELAGO, \ldots
70			\end{keyword}
71	heimbach	1.1
72	heimbach	1.2	\input{ceaice_abstract_part2.tex}
73			\end{frontmatter}
74	heimbach	1.1
75			\linenumbers
76
77			\input{ceaice_intro_part2.tex}
78
79			\input{ceaice_adjoint.tex}
80
81			\input{ceaice_concl.tex}
82
83			\appendix
84	heimbach	1.5	\input{ceaice_appendix_part2.tex}
85	heimbach	1.1
86	heimbach	1.5	~
87	heimbach	1.1
88	heimbach	1.5	\textbf{Acknowledgements}
89	heimbach	1.1	We thank Jinlun Zhang for providing the original B-grid code and many
90			helpful discussions. ML thanks Elizabeth Hunke for multiple explanations.
91	heimbach	1.5	%
92			This work is a contribution to the ECCO Phase II (ECCO2) project sponsored
93			by the NASA Modeling Analysis and Prediction (MAP) program,
94			as well as the ECCO-GODAE project funded under the
95			National Oceanographic Partnership Program (NOPP).
96			D.M. carried out this work at JPL/CalTech under contract with NASA.
97	heimbach	1.1
98			\bibliography{../bib_ceaice/journal_abrvs,../bib_ceaice/seaice,../bib_ceaice/genocean,../bib_ceaice/maths,../bib_ceaice/mitgcmuv,../bib_ceaice/fram,../bib_ceaice/mit_biblio}
99
100			\end{document}
101
102			%%% Local Variables:
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105			%%% End:
106
107
108			A Dynamic-Thermodynamic Sea ice Model for Ocean Climate
109			Estimation on an Arakawa C-Grid
110
111			Introduction
112
113			Ice Model:
114			Dynamics formulation.
115			B-C, LSR, EVP, no-slip, slip
116			parallellization
117			Thermodynamics formulation.
118			0-layer Hibler salinity + snow
119			3-layer Winton
120
121			Idealized tests
122			Funnel Experiments
123			Downstream Island tests
124			B-grid LSR no-slip
125			C-grid LSR no-slip
126			C-grid LSR slip
127			C-grid EVP no-slip
128			C-grid EVP slip
129
130			Arctic Setup
131			Configuration
132			OBCS from cube
133			forcing
134			1/2 and full resolution
135			with a few JFM figs from C-grid LSR no slip
136			ice transport through Canadian Archipelago
137			thickness distribution
138			ice velocity and transport
139
140			Arctic forward sensitivity experiments
141			B-grid LSR no-slip
142			C-grid LSR no-slip
143			C-grid LSR slip
144			C-grid EVP no-slip
145			C-grid EVP slip
146			C-grid LSR no-slip + Winton
147			speed-performance-accuracy (small)
148			ice transport through Canadian Archipelago differences
149			thickness distribution differences
150			ice velocity and transport differences
151
152			Adjoint sensitivity experiment on 1/2-res setup
153			Sensitivity of sea ice volume flow through Fram Strait
154			*** Sensitivity of sea ice volume flow through Canadian Archipelago
155
156			Summary and conluding remarks