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- 2008-05-28T13:53:22+02:00 (16 years ago)
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- trunk/DOC
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trunk/DOC/NEMO_book.tex
r997 r998 136 136 137 137 %--------------------------------------------namlist--------------------------------------------------------- 138 %\newcommand{\namdisplay} [1] { \vspace{-25pt}139 % \begin{alltt} \textcolor{blue}{{\scriptsize \verbatiminput{./Namelist/#1}}} \end{alltt}140 % \vspace{-20pt} }141 138 \newcommand{\namdisplay} [1] { 142 \begin{alltt} {{\tiny \verbatiminput{./ Namelist/#1}}} \end{alltt}139 \begin{alltt} {{\tiny \verbatiminput{./TexFiles/Namelist/#1}}} \end{alltt} 143 140 \vspace{-10pt} } 144 141 %-------------------------------------------------------------------------------------------------------------- … … 168 165 169 166 \title{ 170 \includegraphics[width=0.2\textwidth]{./ Figures/logo_CNRS.pdf}167 \includegraphics[width=0.2\textwidth]{./TexFiles/Figures/logo_CNRS.pdf} 171 168 \quad 172 \includegraphics[width=0.2\textwidth]{./ Figures/logo_MERCATOR.pdf}169 \includegraphics[width=0.2\textwidth]{./TexFiles/Figures/logo_MERCATOR.pdf} 173 170 \quad 174 \includegraphics[width=0.1\textwidth]{./ Figures/logo_UKMO.pdf}171 \includegraphics[width=0.1\textwidth]{./TexFiles/Figures/logo_UKMO.pdf} 175 172 \quad 176 \includegraphics[width=0.2\textwidth]{./ Figures/logo_NERC.pdf} \\173 \includegraphics[width=0.2\textwidth]{./TexFiles/Figures/logo_NERC.pdf} \\ 177 174 \vspace{3.0cm} 178 \includegraphics[width=0.3\textwidth]{./ Figures/NEMO_logo_Black.pdf} \\175 \includegraphics[width=0.3\textwidth]{./TexFiles/Figures/NEMO_logo_Black.pdf} \\ 179 176 \vspace{1.0cm} 180 177 \rule{345pt}{1.5pt} \\ … … 194 191 195 192 196 %%\includegraphics[width=0.2\textwidth]{./ Figures/logo_NERC.pdf} \\193 %%\includegraphics[width=0.2\textwidth]{./TexFiles/Figures/logo_NERC.pdf} \\ 197 194 198 195 %% \hbox{\mbox{% 199 196 %% \hspace{4pt}% 200 %% \fbox{\includegraphics[width=3em]{./ Figures/logo_CNRS.pdf}}%197 %% \fbox{\includegraphics[width=3em]{./TexFiles/Figures/logo_CNRS.pdf}}% 201 198 %% \hspace{4pt} 202 199 %% } }% … … 215 212 % ================================================================ 216 213 217 %\includeonly{./ Chapters/Chap_MISC}218 %\includeonly{./ Chapters/Annex_E}219 %\includeonly{./ Chapters/Chap_LBC,./Chapters/Chap_MISC}220 %\includeonly{./ Chapters/Chap_Model_Basics_zstar}221 %\includeonly{./ Chapters/Annex_A,./Chapters/Annex_B,./Chapters/Annex_C,./Chapters/Annex_D}214 %\includeonly{./TexFiles/Chapters/Chap_MISC} 215 %\includeonly{./TexFiles/Chapters/Annex_E} 216 %\includeonly{./TexFiles/Chapters/Chap_LBC,./TexFiles/Chapters/Chap_MISC} 217 %\includeonly{./TexFiles/Chapters/Chap_Model_Basics_zstar} 218 %\includeonly{./TexFiles/Chapters/Annex_A,./TexFiles/Chapters/Annex_B,./TexFiles/Chapters/Annex_C,./TexFiles/Chapters/Annex_D} 222 219 223 220 % ================================================================ … … 239 236 % ================================================================ 240 237 241 \include{./ Chapters/Abstracts_Foreword}238 \include{./TexFiles/Chapters/Abstracts_Foreword} 242 239 243 240 % ================================================================ … … 245 242 % ================================================================ 246 243 247 \include{./ Chapters/Introduction}244 \include{./TexFiles/Chapters/Introduction} 248 245 249 246 % ================================================================ … … 251 248 % ================================================================ 252 249 253 \include{./ Chapters/Chap_Model_Basics}254 255 %\include{./ Chapters/Chap_Model_Basics_zstar} % attent to describe z*-s*256 257 \include{./ Chapters/Chap_DOM}258 259 \include{./ Chapters/Chap_TRA}260 261 \include{./ Chapters/Chap_DYN}262 263 \include{./ Chapters/Chap_SBC}264 265 \include{./ Chapters/Chap_LBC}266 267 \include{./ Chapters/Chap_LDF}268 269 \include{./ Chapters/Chap_ZDF}270 271 \include{./ Chapters/Chap_MISC}250 \include{./TexFiles/Chapters/Chap_Model_Basics} 251 252 %\include{./TexFiles/Chapters/Chap_Model_Basics_zstar} % attent to describe z*-s* 253 254 \include{./TexFiles/Chapters/Chap_DOM} 255 256 \include{./TexFiles/Chapters/Chap_TRA} 257 258 \include{./TexFiles/Chapters/Chap_DYN} 259 260 \include{./TexFiles/Chapters/Chap_SBC} 261 262 \include{./TexFiles/Chapters/Chap_LBC} 263 264 \include{./TexFiles/Chapters/Chap_LDF} 265 266 \include{./TexFiles/Chapters/Chap_ZDF} 267 268 \include{./TexFiles/Chapters/Chap_MISC} 272 269 273 270 % ================================================================ … … 277 274 \appendix 278 275 279 %\include{./Chapters/Chap_Conservation} 280 \include{./Chapters/Annex_A} 281 \include{./Chapters/Annex_B} 282 \include{./Chapters/Annex_C} 283 %\include{./Chapters/Annex_D} 284 %\include{./Chapters/Annex_E} 285 286 %%%%\include{./Chapters/0_page_de_garde_old} 276 %\include{./TexFiles/Chapters/Chap_Conservation} 277 \include{./TexFiles/Chapters/Annex_A} 278 \include{./TexFiles/Chapters/Annex_B} 279 \include{./TexFiles/Chapters/Annex_C} 280 %\include{./TexFiles/Chapters/Annex_D} 281 %\include{./TexFiles/Chapters/Annex_E} 282 287 283 % ================================================================ 288 284 % INDEX … … 297 293 298 294 %%\bibliographystyle{plainnat} 299 \bibliographystyle{./ ametsoc} % AMS biblio style (JPO)300 \bibliography{./ Biblio/Biblio}295 \bibliographystyle{./TexFiles/ametsoc} % AMS biblio style (JPO) 296 \bibliography{./TexFiles/Biblio/Biblio} 301 297 302 298 % ================================================================ -
trunk/DOC/TexFiles/Chapters/Chap_DOM.tex
r996 r998 45 45 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 46 46 \begin{figure}[!tb] \label{Fig_cell} \begin{center} 47 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_cell.pdf}47 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_cell.pdf} 48 48 \caption{Arrangement of variables. $T$ indicates scalar points where temperature, 49 49 salinity, density, pressure and horizontal divergence are defined. ($u$,$v$,$w$) … … 220 220 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 221 221 \begin{figure}[!tb] \label{Fig_index_hor} \begin{center} 222 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_index_hor.pdf}222 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_index_hor.pdf} 223 223 \caption{Horizontal integer indexing used in the \textsc{Fortran} code. The dashed 224 224 area indicates the cell in which variables contained in arrays have the same … … 269 269 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 270 270 \begin{figure}[!pt] \label{Fig_index_vert} \begin{center} 271 \includegraphics[width=.90\textwidth]{./ Figures/Fig_index_vert.pdf}271 \includegraphics[width=.90\textwidth]{./TexFiles/Figures/Fig_index_vert.pdf} 272 272 \caption{Vertical integer indexing used in the \textsc{Fortran } code. Note that 273 273 the $k$-axis is orientated downward. The dashed area indicates the cell in … … 374 374 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 375 375 \begin{figure}[!t] \label{Fig_zgr_e3} \begin{center} 376 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_zgr_e3.pdf}376 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_zgr_e3.pdf} 377 377 \caption{Comparison of (a) traditional definitions of grid-point position and grid-size 378 378 in the vertical, and (b) analytically derived grid-point position and scale factors. For … … 479 479 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 480 480 \begin{figure}[!tb] \label{Fig_z_zps_s_sps} \begin{center} 481 \includegraphics[width=1.0\textwidth]{./ Figures/Fig_z_zps_s_sps.pdf}481 \includegraphics[width=1.0\textwidth]{./TexFiles/Figures/Fig_z_zps_s_sps.pdf} 482 482 \caption{The ocean bottom as seen by the model: 483 483 (a) $z$-coordinate with full step, … … 583 583 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 584 584 \begin{figure}[!tb] \label{Fig_zgr} \begin{center} 585 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_zgr.pdf}585 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_zgr.pdf} 586 586 \caption{Default vertical mesh for ORCA2: 30 ocean levels (L30). Vertical level 587 587 functions for (a) T-point depth and (b) the associated scale factor as computed … … 767 767 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 768 768 \begin{figure}[!tb] \label{Fig_sco_function} \begin{center} 769 \includegraphics[width=1.0\textwidth]{./ Figures/Fig_sco_function.pdf}769 \includegraphics[width=1.0\textwidth]{./TexFiles/Figures/Fig_sco_function.pdf} 770 770 \caption{Examples of the stretching function applied to a sea mont; from left to right: surface, surface and bottom, and bottom intensified resolutions} 771 771 \end{center} \end{figure} -
trunk/DOC/TexFiles/Chapters/Chap_DYN.tex
r996 r998 190 190 \begin{figure}[!ht] \label{Fig_DYN_een_triad} 191 191 \begin{center} 192 \includegraphics[width=0.70\textwidth]{./ Figures/Fig_DYN_een_triad.pdf}192 \includegraphics[width=0.70\textwidth]{./TexFiles/Figures/Fig_DYN_een_triad.pdf} 193 193 \caption{Triads used in the energy and enstrophy conserving scheme (een) for 194 194 $u$-component (upper panel) and $v$-component (lower panel).} … … 710 710 \begin{figure}[!t] \label{Fig_DYN_dynspg_ts} 711 711 \begin{center} 712 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_DYN_dynspg_ts.pdf}712 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_DYN_dynspg_ts.pdf} 713 713 \caption{Schematic of the split-explicit time stepping scheme for the external 714 714 and internal modes. Time increases to the right. -
trunk/DOC/TexFiles/Chapters/Chap_LBC.tex
r996 r998 48 48 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 49 49 \begin{figure}[!t] \label{Fig_LBC_uv} \begin{center} 50 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_LBC_uv.pdf}50 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_LBC_uv.pdf} 51 51 \caption {Lateral boundary (thick line) at T-level. The velocity normal to the 52 52 boundary is set to zero.} … … 71 71 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 72 72 \begin{figure}[!p] \label{Fig_LBC_shlat} \begin{center} 73 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_LBC_shlat.pdf}73 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_LBC_shlat.pdf} 74 74 \caption {lateral boundary condition (a) free-slip ($shlat=0$) ; (b) no-slip ($shlat=2$) 75 75 ; (c) "partial" free-slip ($0<shlat<2$) and (d) "strong" no-slip ($2<shlat$). … … 187 187 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 188 188 \begin{figure}[!t] \label{Fig_LBC_jperio} \begin{center} 189 \includegraphics[width=1.0\textwidth]{./ Figures/Fig_LBC_jperio.pdf}189 \includegraphics[width=1.0\textwidth]{./TexFiles/Figures/Fig_LBC_jperio.pdf} 190 190 \caption {setting of (a) east-west cyclic (b) symmetric across the equator boundary conditions.} 191 191 \end{center} \end{figure} … … 202 202 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 203 203 \begin{figure}[!t] \label{Fig_North_Fold_T} \begin{center} 204 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_North_Fold_T.pdf}204 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_North_Fold_T.pdf} 205 205 \caption {North fold boundary with a $T$-point pivot and cyclic east-west boundary condition ($jperio=4$), as used in ORCA 2, 1/4, and 1/12. Pink shaded area corresponds to the inner domain mask (see text). } 206 206 \end{center} \end{figure} … … 263 263 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 264 264 \begin{figure}[!t] \label{Fig_mpp} \begin{center} 265 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_mpp.pdf}265 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_mpp.pdf} 266 266 \caption {Positioning of a sub-domain when massively parallel processing is used. } 267 267 \end{center} \end{figure} … … 339 339 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 340 340 \begin{figure}[!ht] \label{Fig_mppini2} \begin{center} 341 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_mppini2.pdf}341 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_mppini2.pdf} 342 342 \caption {Example of Atlantic domain defined for the CLIPPER projet. Initial grid is 343 343 composed of 773 x 1236 horizontal points. (a) the domain is split onto 9 \time 20 … … 472 472 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 473 473 \begin{figure}[!t] \label{Fig_obc_north} \begin{center} 474 \includegraphics[width=0.70\textwidth]{./ Figures/Fig_obc_north.pdf}474 \includegraphics[width=0.70\textwidth]{./TexFiles/Figures/Fig_obc_north.pdf} 475 475 \caption {Localization of the North open boundary points.} 476 476 \end{center} -
trunk/DOC/TexFiles/Chapters/Chap_LDF.tex
r996 r998 232 232 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 233 233 \begin{figure}[!ht] \label{Fig_LDF_ZDF1} \begin{center} 234 \includegraphics[width=0.70\textwidth]{./ Figures/Fig_LDF_ZDF1.pdf}234 \includegraphics[width=0.70\textwidth]{./TexFiles/Figures/Fig_LDF_ZDF1.pdf} 235 235 \caption {averaging procedure for isopycnal slope computation.} 236 236 \end{center} \end{figure} … … 249 249 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 250 250 \begin{figure}[!ht] \label{Fig_eiv_slp} \begin{center} 251 \includegraphics[width=0.70\textwidth]{./ Figures/Fig_eiv_slp.pdf}251 \includegraphics[width=0.70\textwidth]{./TexFiles/Figures/Fig_eiv_slp.pdf} 252 252 \caption {Vertical profile of the slope used for lateral mixing in the mixed layer : \textit{(a)} in the real ocean the slope is the iso-neutral slope in the ocean interior and their have to adjust to the surface boundary (i.e. tend to zero at the surface as there is no mixing across the air-sea interface: wall boundary condition). Nevertheless, the profile between surface zero value and interior iso-neutral one is unknown, and especially the value at the based of the mixed layer ; \textit{(b)} profile of slope using a linear tapering of the slope near the surface and imposing a maximum slope of 1/100 ; \textit{(c)} profile of slope actuelly used in \NEMO: linear decrease of the slope from zero at the surface to its ocean interior value computed just below the mixed layer. Note the huge change in the slope at the based of the mixed layer between \textit{(b)} and \textit{(c)}. 253 253 .} -
trunk/DOC/TexFiles/Chapters/Chap_MISC.tex
r996 r998 35 35 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 36 36 \begin{figure}[!tbp] \label{Fig_MISC_strait_hand} \begin{center} 37 \includegraphics[width=0.80\textwidth]{./ Figures/Fig_Gibraltar.pdf}38 \includegraphics[width=0.80\textwidth]{./ Figures/Fig_Gibraltar2.pdf}37 \includegraphics[width=0.80\textwidth]{./TexFiles/Figures/Fig_Gibraltar.pdf} 38 \includegraphics[width=0.80\textwidth]{./TexFiles/Figures/Fig_Gibraltar2.pdf} 39 39 \caption {Example of the Gibraltar strait defined in a 1\r{} x 1\r{} mesh. 40 40 \textit{Top}: using partially open cells. The meridional scale factor at $v$-point … … 107 107 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 108 108 \begin{figure}[!ht] \label{Fig_LBC_zoom} \begin{center} 109 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_LBC_zoom.pdf}109 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_LBC_zoom.pdf} 110 110 \caption {Position of a model domain compared to the data input domain when the zoom functionality is used.} 111 111 \end{center} \end{figure} -
trunk/DOC/TexFiles/Chapters/Chap_Model_Basics.tex
r996 r998 80 80 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 81 81 \begin{figure}[!ht] \label{Fig_ocean_bc} \begin{center} 82 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_I_ocean_bc.pdf}82 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_I_ocean_bc.pdf} 83 83 \caption{The ocean is bounded by two surfaces, $z=-H(i,j)$ and $z=\eta(i,j,k,t)$, where $H$ is the depth of the sea floor and $\eta$ the height of the sea surface. Both $H$ and $\eta $ are referenced to $z=0$.} 84 84 \end{center} \end{figure} … … 294 294 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 295 295 \begin{figure}[!tb] \label{Fig_referential} \begin{center} 296 \includegraphics[width=0.60\textwidth]{./ Figures/Fig_I_earth_referential.pdf}296 \includegraphics[width=0.60\textwidth]{./TexFiles/Figures/Fig_I_earth_referential.pdf} 297 297 \caption{the geographical coordinate system $(\lambda,\varphi,z)$ and the curvilinear coordinate system (\textbf{i},\textbf{j},\textbf{k}). } 298 298 \end{center} \end{figure} … … 616 616 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 617 617 \begin{figure}[!b] \label{Fig_z_zstar} \begin{center} 618 \includegraphics[width=1.0\textwidth]{./ Figures/Fig_z_zstar.pdf}618 \includegraphics[width=1.0\textwidth]{./TexFiles/Figures/Fig_z_zstar.pdf} 619 619 \caption{(a) $z$-coordinate in linear free-surface case ; (b) $z-$coordinate in non-linear free surface case (c) re-scaled height coordinate (become popular as the \textit{z*-}coordinate \citep{Adcroft_Campin_OM04} ).} 620 620 \end{center} \end{figure} -
trunk/DOC/TexFiles/Chapters/Chap_TRA.tex
r996 r998 103 103 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 104 104 \begin{figure}[!t] \label{Fig_adv_scheme} \begin{center} 105 \includegraphics[width=0.9\textwidth]{./ Figures/Fig_adv_scheme.pdf}105 \includegraphics[width=0.9\textwidth]{./TexFiles/Figures/Fig_adv_scheme.pdf} 106 106 \caption{Schematic representation of some ways used to evaluate the tracer value 107 107 at $u$-point and the amount of tracer exchanged between two neighbouring grid … … 836 836 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 837 837 \begin{figure}[!t] \label{Fig_geothermal} \begin{center} 838 \includegraphics[width=1.0\textwidth]{./ Figures/Fig_TRA_geoth.pdf}838 \includegraphics[width=1.0\textwidth]{./TexFiles/Figures/Fig_TRA_geoth.pdf} 839 839 \caption{Geothermal Heat flux (in $mW.m^{-2}$) as inferred from the age 840 840 of the sea floor and the formulae of \citet{Stein1992}.} … … 933 933 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 934 934 \begin{figure}[!t] \label{Fig_bbl} \begin{center} 935 \includegraphics[width=1.0\textwidth]{./ Figures/Fig_BBL_adv.pdf}935 \includegraphics[width=1.0\textwidth]{./TexFiles/Figures/Fig_BBL_adv.pdf} 936 936 \caption{Advective Bottom Boundary Layer.} 937 937 \end{center} \end{figure} … … 1235 1235 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 1236 1236 \begin{figure}[!p] \label{Fig_Partial_step_scheme} \begin{center} 1237 \includegraphics[width=0.9\textwidth]{./ Figures/Partial_step_scheme.pdf}1237 \includegraphics[width=0.9\textwidth]{./TexFiles/Figures/Partial_step_scheme.pdf} 1238 1238 \caption{ Discretisation of the horizontal difference and average of tracers in the $z$-partial step coordinate (\np{ln\_zps}=.true.) in the case $( e3w_k^{i+1} - e3w_k^i )>0$. A linear interpolation is used to estimate $\widetilde{T}_k^{i+1}$, the tracer value at the depth of the shallower tracer point of the two adjacent bottom $T$-points. The horizontal difference is then given by: $\delta _{i+1/2} T_k= \widetilde{T}_k^{\,i+1} -T_k^{\,i}$ and the average by: $\overline{T}_k^{\,i+1/2}= ( \widetilde{T}_k^{\,i+1/2} - T_k^{\,i} ) / 2$. } 1239 1239 \end{center} \end{figure} -
trunk/DOC/TexFiles/Chapters/Chap_ZDF.tex
r996 r998 190 190 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 191 191 \begin{figure}[!t] \label{Fig_mixing_length} \begin{center} 192 \includegraphics[width=1.00\textwidth]{./ Figures/Fig_mixing_length.pdf}192 \includegraphics[width=1.00\textwidth]{./TexFiles/Figures/Fig_mixing_length.pdf} 193 193 \caption {Illustration of the mixing length computation. } 194 194 \end{center} … … 281 281 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 282 282 \begin{figure}[!htb] \label{Fig_npc} \begin{center} 283 \includegraphics[width=0.90\textwidth]{./ Figures/Fig_npc.pdf}283 \includegraphics[width=0.90\textwidth]{./TexFiles/Figures/Fig_npc.pdf} 284 284 \caption {Example of an unstable density profile treated by the non penetrative 285 285 convective adjustment algorithm. $1^{st}$ step: the initial profile is checked from … … 437 437 %>>>>>>>>>>>>>>>>>>>>>>>>>>>> 438 438 \begin{figure}[!t] \label{Fig_zdfddm} \begin{center} 439 \includegraphics[width=0.99\textwidth]{./ Figures/Fig_zdfddm.pdf}439 \includegraphics[width=0.99\textwidth]{./TexFiles/Figures/Fig_zdfddm.pdf} 440 440 \caption {From \citet{Merryfield1999} : (a) Diapycnal diffusivities $A_f^{vT}$ 441 441 and $A_f^{vS}$ for temperature and salt in regions of salt fingering. Heavy
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