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}

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

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

\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	% $Header: /u/gcmpack/MITgcm_contrib/articles/ceaice/ceaice.tex,v 1.16 2008/02/26 19:14:36 mlosch Exp $
2	% $Name: $
3	\documentclass[12pt]{article}
4
5	\usepackage[]{graphicx}
6	\usepackage{subfigure}
7
8	\usepackage[round,comma]{natbib}
9	\bibliographystyle{bib/agu04}
10
11	\usepackage{amsmath,amssymb}
12	\newcommand\bmmax{10} \newcommand\hmmax{10}
13	\usepackage{bm}
14
15	% math abbreviations
16	\newcommand{\vek}[1]{\ensuremath{\mathbf{#1}}}
17	\newcommand{\mat}[1]{\ensuremath{\mathbf{#1}}}
18	\newcommand{\vtau}{\bm{{\tau}}}
19
20	\newcommand{\degree}{\ensuremath{^\circ}}
21	\newcommand{\degC}{\,\ensuremath{\degree}C}
22	\newcommand{\degE}{\ensuremath{\degree}\,E}
23	\newcommand{\degS}{\ensuremath{\degree}\,S}
24	\newcommand{\degN}{\ensuremath{\degree}\,N}
25	\newcommand{\degW}{\ensuremath{\degree}\,W}
26
27	% cross reference scheme
28	\newcommand{\reffig}[1]{Figure~\ref{fig:#1}}
29	\newcommand{\reftab}[1]{Table~\ref{tab:#1}}
30	\newcommand{\refapp}[1]{Appendix~\ref{app:#1}}
31	\newcommand{\refsec}[1]{Section~\ref{sec:#1}}
32	\newcommand{\refeq}[1]{\,(\ref{eq:#1})}
33	\newcommand{\refeqs}[2]{\,(\ref{eq:#1})--(\ref{eq:#2})}
34
35	\newlength{\stdfigwidth}\setlength{\stdfigwidth}{20pc}
36	%\newlength{\stdfigwidth}\setlength{\stdfigwidth}{\columnwidth}
37	\newlength{\mediumfigwidth}\setlength{\mediumfigwidth}{39pc}
38	%\newlength{\widefigwidth}\setlength{\widefigwidth}{39pc}
39	\newlength{\widefigwidth}\setlength{\widefigwidth}{\textwidth}
40	\newcommand{\fpath}{figs}
41
42	% commenting scheme
43	\newcommand{\ml}[1]{\textsf{\slshape #1}}
44
45	\title{A Dynamic-Thermodynamic Sea ice Model for Ocean Climate
46	Estimation on an Arakawa C-Grid}
47
48	\author{Martin Losch, Dimitris Menemenlis, Patrick Heimbach, \\
49	Jean-Michel Campin, and Chris Hill}
50	\begin{document}
51
52	\maketitle
53
54	\input{ceaice_abstract.tex}
55
56	\input{ceaice_intro.tex}
57
58	\input{ceaice_model.tex}
59
60	\input{ceaice_forward.tex}
61
62	\input{ceaice_adjoint.tex}
63
64	\input{ceaice_concl.tex}
65
66	\paragraph{Acknowledgements}
67	We thank Jinlun Zhang for providing the original B-grid code and many
68	helpful discussions. ML thanks Elizabeth Hunke for multiple explanations.
69
70	\bibliography{bib/journal_abrvs,bib/seaice,bib/genocean,bib/maths,bib/mitgcmuv,bib/fram}
71
72	\end{document}
73
74	%%% Local Variables:
75	%%% mode: latex
76	%%% TeX-master: t
77	%%% End:
78
79
80	A Dynamic-Thermodynamic Sea ice Model for Ocean Climate
81	Estimation on an Arakawa C-Grid
82
83	Introduction
84
85	Ice Model:
86	Dynamics formulation.
87	B-C, LSR, EVP, no-slip, slip
88	parallellization
89	Thermodynamics formulation.
90	0-layer Hibler salinity + snow
91	3-layer Winton
92
93	Idealized tests
94	Funnel Experiments
95	Downstream Island tests
96	B-grid LSR no-slip
97	C-grid LSR no-slip
98	C-grid LSR slip
99	C-grid EVP no-slip
100	C-grid EVP slip
101
102	Arctic Setup
103	Configuration
104	OBCS from cube
105	forcing
106	1/2 and full resolution
107	with a few JFM figs from C-grid LSR no slip
108	ice transport through Canadian Archipelago
109	thickness distribution
110	ice velocity and transport
111
112	Arctic forward sensitivity experiments
113	B-grid LSR no-slip
114	C-grid LSR no-slip
115	C-grid LSR slip
116	C-grid EVP no-slip
117	C-grid EVP slip
118	C-grid LSR no-slip + Winton
119	speed-performance-accuracy (small)
120	ice transport through Canadian Archipelago differences
121	thickness distribution differences
122	ice velocity and transport differences
123
124	Adjoint sensitivity experiment on 1/2-res setup
125	Sensitivity of sea ice volume flow through Fram Strait
126	*** Sensitivity of sea ice volume flow through Canadian Archipelago
127
128	Summary and conluding remarks