1 |
\newpage |
2 |
\paragraph{MITgcm Kernel Diagnostic Menu:} |
3 |
\addcontentsline{toc}{subsubsection}{Kernel Diagnostic Menu} |
4 |
\label{sec:diagnostics:menu} |
5 |
|
6 |
\begin{table} |
7 |
\begin{tabular}{llll} |
8 |
\hline\hline |
9 |
NAME & UNITS & LEVELS & DESCRIPTION \\ |
10 |
\hline |
11 |
|
12 |
&\\ |
13 |
UVEL & $m/sec$ & Nr |
14 |
&\begin{minipage}[t]{3in} |
15 |
{U-Velocity} |
16 |
\end{minipage}\\ |
17 |
VVEL & $m/sec$ & Nr |
18 |
&\begin{minipage}[t]{3in} |
19 |
{V-Velocity} |
20 |
\end{minipage}\\ |
21 |
UVEL\_k2 & $m/sec$ & 1 |
22 |
&\begin{minipage}[t]{3in} |
23 |
{U-Velocity} |
24 |
\end{minipage}\\ |
25 |
VVEL\_k2 & $m/sec$ & 1 |
26 |
&\begin{minipage}[t]{3in} |
27 |
{V-Velocity} |
28 |
\end{minipage}\\ |
29 |
WVEL & $m/sec$ & Nr |
30 |
&\begin{minipage}[t]{3in} |
31 |
{Vertical-Velocity} |
32 |
\end{minipage}\\ |
33 |
THETASQ & $deg^2$ & Nr |
34 |
&\begin{minipage}[t]{3in} |
35 |
{Square of Potential Temperature} |
36 |
\end{minipage}\\ |
37 |
SALTSQ & $g^2/{kg}^2$ & Nr |
38 |
&\begin{minipage}[t]{3in} |
39 |
{Square of Salt (or Water Vapor Mixing Ratio)} |
40 |
\end{minipage}\\ |
41 |
SALTSQan & $g^2/{kg}^2$ & Nr |
42 |
&\begin{minipage}[t]{3in} |
43 |
{Square of Salt anomaly (=SALT-35)} |
44 |
\end{minipage}\\ |
45 |
UVELSQ & $m^2/sec^2$ & Nr |
46 |
&\begin{minipage}[t]{3in} |
47 |
{Square of U-Velocity} |
48 |
\end{minipage}\\ |
49 |
VVELSQ & $m^2/sec^2$ & Nr |
50 |
&\begin{minipage}[t]{3in} |
51 |
{Square of V-Velocity} |
52 |
\end{minipage}\\ |
53 |
WVELSQ & $m^2/sec^2$ & Nr |
54 |
&\begin{minipage}[t]{3in} |
55 |
{Square of Vertical-Velocity} |
56 |
\end{minipage}\\ |
57 |
UV\_VEL\_C & $m^2/sec^2$ & Nr |
58 |
&\begin{minipage}[t]{3in} |
59 |
{Meridional Transport of Zonal Momentum (cell center)} |
60 |
\end{minipage}\\ |
61 |
UV\_VEL\_Z & $m^2/sec^2$ & Nr |
62 |
&\begin{minipage}[t]{3in} |
63 |
{Meridional Transport of Zonal Momentum (corner)} |
64 |
\end{minipage}\\ |
65 |
WU\_VEL & $m^2/sec^2$ & Nr |
66 |
&\begin{minipage}[t]{3in} |
67 |
{Vertical Transport of Zonal Momentum (cell center)} |
68 |
\end{minipage}\\ |
69 |
WV\_VEL & $m^2/sec^2$ & Nr |
70 |
&\begin{minipage}[t]{3in} |
71 |
{Vertical Transport of Meridional Momentum (cell center)} |
72 |
\end{minipage}\\ |
73 |
UVELMASS & $m/sec$ & Nr |
74 |
&\begin{minipage}[t]{3in} |
75 |
{Zonal Mass-Weighted Component of Velocity} |
76 |
\end{minipage}\\ |
77 |
VVELMASS & $m/sec$ & Nr |
78 |
&\begin{minipage}[t]{3in} |
79 |
{Meridional Mass-Weighted Component of Velocity} |
80 |
\end{minipage}\\ |
81 |
WVELMASS & $m/sec$ & Nr |
82 |
&\begin{minipage}[t]{3in} |
83 |
{Vertical Mass-Weighted Component of Velocity} |
84 |
\end{minipage}\\ |
85 |
UTHMASS & $m-deg/sec$ & Nr |
86 |
&\begin{minipage}[t]{3in} |
87 |
{Zonal Mass-Weight Transp of Pot Temp} |
88 |
\end{minipage}\\ |
89 |
VTHMASS & $m-deg/sec$ & Nr |
90 |
&\begin{minipage}[t]{3in} |
91 |
{Meridional Mass-Weight Transp of Pot Temp} |
92 |
\end{minipage}\\ |
93 |
WTHMASS & $m-deg/sec$ & Nr |
94 |
&\begin{minipage}[t]{3in} |
95 |
{Vertical Mass-Weight Transp of Pot Temp} |
96 |
\end{minipage}\\ |
97 |
ETAN & $(hPa,m)$ & 1 |
98 |
&\begin{minipage}[t]{3in} |
99 |
{Perturbation of Surface (pressure, height)} |
100 |
\end{minipage}\\ |
101 |
ETANSQ & $(hPa^2,m^2)$ & 1 |
102 |
&\begin{minipage}[t]{3in} |
103 |
{Square of Perturbation of Surface (pressure, height)} |
104 |
\end{minipage}\\ |
105 |
DETADT2 & ${r-unit}^2/s^2$ & 1 |
106 |
&\begin{minipage}[t]{3in} |
107 |
{Square of Eta (Surf.P,SSH) Tendency} |
108 |
\end{minipage}\\ |
109 |
THETA & $deg K$ & Nr |
110 |
&\begin{minipage}[t]{3in} |
111 |
{Potential Temperature} |
112 |
\end{minipage}\\ |
113 |
SST & $deg K$ & 1 |
114 |
&\begin{minipage}[t]{3in} |
115 |
{Sea Surface Temperature} |
116 |
\end{minipage}\\ |
117 |
SALT & $g/kg$ & Nr |
118 |
&\begin{minipage}[t]{3in} |
119 |
{Salt (or Water Vapor Mixing Ratio)} |
120 |
\end{minipage}\\ |
121 |
SSS & $g/kg$ & 1 |
122 |
&\begin{minipage}[t]{3in} |
123 |
{Sea Surface Salinity} |
124 |
\end{minipage}\\ |
125 |
SALTanom & $g/kg$ & Nr |
126 |
&\begin{minipage}[t]{3in} |
127 |
{Salt anomaly (=SALT-35)} |
128 |
\end{minipage}\\ |
129 |
\end{tabular} |
130 |
\end{table} |
131 |
\vspace{1.5in} |
132 |
\vfill |
133 |
|
134 |
\newpage |
135 |
\vspace*{\fill} |
136 |
\begin{table} |
137 |
\begin{tabular}{llll} |
138 |
\hline\hline |
139 |
NAME & UNITS & LEVELS & DESCRIPTION \\ |
140 |
\hline |
141 |
|
142 |
&\\ |
143 |
USLTMASS & $m-kg/sec-kg$ & Nr |
144 |
&\begin{minipage}[t]{3in} |
145 |
{Zonal Mass-Weight Transp of Salt (or W.Vap Mix Rat.)} |
146 |
\end{minipage}\\ |
147 |
VSLTMASS & $m-kg/sec-kg$ & Nr |
148 |
&\begin{minipage}[t]{3in} |
149 |
{Meridional Mass-Weight Transp of Salt (or W.Vap Mix Rat.)} |
150 |
\end{minipage}\\ |
151 |
WSLTMASS & $m-kg/sec-kg$ & Nr |
152 |
&\begin{minipage}[t]{3in} |
153 |
{Vertical Mass-Weight Transp of Salt (or W.Vap Mix Rat.)} |
154 |
\end{minipage}\\ |
155 |
UVELTH & $m-deg/sec$ & Nr |
156 |
&\begin{minipage}[t]{3in} |
157 |
{Zonal Transp of Pot Temp} |
158 |
\end{minipage}\\ |
159 |
VVELTH & $m-deg/sec$ & Nr |
160 |
&\begin{minipage}[t]{3in} |
161 |
{Meridional Transp of Pot Temp} |
162 |
\end{minipage}\\ |
163 |
WVELTH & $m-deg/sec$ & Nr |
164 |
&\begin{minipage}[t]{3in} |
165 |
{Vertical Transp of Pot Temp} |
166 |
\end{minipage}\\ |
167 |
UVELSLT & $m-kg/sec-kg$ & Nr |
168 |
&\begin{minipage}[t]{3in} |
169 |
{Zonal Transp of Salt (or W.Vap Mix Rat.)} |
170 |
\end{minipage}\\ |
171 |
VVELSLT & $m-kg/sec-kg$ & Nr |
172 |
&\begin{minipage}[t]{3in} |
173 |
{Meridional Transp of Salt (or W.Vap Mix Rat.)} |
174 |
\end{minipage}\\ |
175 |
WVELSLT & $m-kg/sec-kg$ & Nr |
176 |
&\begin{minipage}[t]{3in} |
177 |
{Vertical Transp of Salt (or W.Vap Mix Rat.)} |
178 |
\end{minipage}\\ |
179 |
RHOAnoma & $kg/m^3 $ & Nr |
180 |
&\begin{minipage}[t]{3in} |
181 |
{Density Anomaly (=Rho-rhoConst)} |
182 |
\end{minipage}\\ |
183 |
RHOANOSQ & $kg^2/m^6$ & Nr |
184 |
&\begin{minipage}[t]{3in} |
185 |
{Square of Density Anomaly (=(Rho-rhoConst))} |
186 |
\end{minipage}\\ |
187 |
URHOMASS & $kg/m^2/s$ & Nr |
188 |
&\begin{minipage}[t]{3in} |
189 |
{Zonal Transport of Density} |
190 |
\end{minipage}\\ |
191 |
VRHOMASS & $kg/m^2/s$ & Nr |
192 |
&\begin{minipage}[t]{3in} |
193 |
{Meridional Transport of Density} |
194 |
\end{minipage}\\ |
195 |
WRHOMASS & $kg/m^2/s$ & Nr |
196 |
&\begin{minipage}[t]{3in} |
197 |
{Vertical Transport of Potential Density} |
198 |
\end{minipage}\\ |
199 |
PHIHYD & $m^2/s^2 $ & Nr |
200 |
&\begin{minipage}[t]{3in} |
201 |
{Hydrostatic (ocean) pressure / (atmos) geo-Potential} |
202 |
\end{minipage}\\ |
203 |
PHIHYDSQ & $m^4/s^4 $ & Nr |
204 |
&\begin{minipage}[t]{3in} |
205 |
{Square of Hyd. (ocean) press / (atmos) geoPotential} |
206 |
\end{minipage}\\ |
207 |
PHIBOT & $m^2/s^2 $ & Nr |
208 |
&\begin{minipage}[t]{3in} |
209 |
{ocean bottom pressure / top. atmos geo-Potential} |
210 |
\end{minipage}\\ |
211 |
PHIBOTSQ & $m^4/s^4 $ & Nr |
212 |
&\begin{minipage}[t]{3in} |
213 |
{Square of ocean bottom pressure / top. geo-Potential} |
214 |
\end{minipage}\\ |
215 |
DRHODR & $kg/m^3/{r-unit}$ & Nr |
216 |
&\begin{minipage}[t]{3in} |
217 |
{Stratification: d.Sigma/dr} |
218 |
\end{minipage}\\ |
219 |
VISCA4 & $m^4/sec$ & 1 |
220 |
&\begin{minipage}[t]{3in} |
221 |
{Biharmonic Viscosity Coefficient} |
222 |
\end{minipage}\\ |
223 |
VISCAH & $m^2/sec$ & 1 |
224 |
&\begin{minipage}[t]{3in} |
225 |
{Harmonic Viscosity Coefficient} |
226 |
\end{minipage}\\ |
227 |
TAUX & $N/m^2 $ & 1 |
228 |
&\begin{minipage}[t]{3in} |
229 |
{zonal surface wind stress, >0 increases uVel} |
230 |
\end{minipage}\\ |
231 |
TAUY & $N/m^2 $ & 1 |
232 |
&\begin{minipage}[t]{3in} |
233 |
{meridional surf. wind stress, >0 increases vVel} |
234 |
\end{minipage}\\ |
235 |
TFLUX & $W/m^2 $ & 1 |
236 |
&\begin{minipage}[t]{3in} |
237 |
{net surface heat flux, >0 increases theta} |
238 |
\end{minipage}\\ |
239 |
TRELAX & $W/m^2 $ & 1 |
240 |
&\begin{minipage}[t]{3in} |
241 |
{surface temperature relaxation, >0 increases theta} |
242 |
\end{minipage}\\ |
243 |
TICE & $W/m^2 $ & 1 |
244 |
&\begin{minipage}[t]{3in} |
245 |
{heat from melt/freeze of sea-ice, >0 increases theta} |
246 |
\end{minipage}\\ |
247 |
SFLUX & $g/m^2/s $ & 1 |
248 |
&\begin{minipage}[t]{3in} |
249 |
{net surface salt flux, >0 increases salt} |
250 |
\end{minipage}\\ |
251 |
SRELAX & $g/m^2/s $ & 1 |
252 |
&\begin{minipage}[t]{3in} |
253 |
{surface salinity relaxation, >0 increases salt} |
254 |
\end{minipage}\\ |
255 |
PRESSURE & $Pa $ & Nr |
256 |
&\begin{minipage}[t]{3in} |
257 |
{Atmospheric Pressure (Pa)} |
258 |
\end{minipage}\\ |
259 |
\end{tabular} |
260 |
\end{table} |
261 |
\vspace{1.5in} |
262 |
\vfill |
263 |
|
264 |
\newpage |
265 |
\vspace*{\fill} |
266 |
\begin{table} |
267 |
\begin{tabular}{llll} |
268 |
\hline\hline |
269 |
NAME & UNITS & LEVELS & DESCRIPTION \\ |
270 |
\hline |
271 |
|
272 |
&\\ |
273 |
ADVr\_TH & $K.Pa.m^2/s $ & Nr |
274 |
&\begin{minipage}[t]{3in} |
275 |
{Vertical Advective Flux of Pot.Temperature} |
276 |
\end{minipage}\\ |
277 |
ADVx\_TH & $K.Pa.m^2/s $ & Nr |
278 |
&\begin{minipage}[t]{3in} |
279 |
{Zonal Advective Flux of Pot.Temperature} |
280 |
\end{minipage}\\ |
281 |
ADVy\_TH & $K.Pa.m^2/s $ & Nr |
282 |
&\begin{minipage}[t]{3in} |
283 |
{Meridional Advective Flux of Pot.Temperature} |
284 |
\end{minipage}\\ |
285 |
DFrE\_TH & $K.Pa.m^2/s $ & Nr |
286 |
&\begin{minipage}[t]{3in} |
287 |
{Vertical Diffusive Flux of Pot.Temperature (Explicit part)} |
288 |
\end{minipage}\\ |
289 |
DIFx\_TH & $K.Pa.m^2/s $ & Nr |
290 |
&\begin{minipage}[t]{3in} |
291 |
{Zonal Diffusive Flux of Pot.Temperature} |
292 |
\end{minipage}\\ |
293 |
DIFy\_TH & $K.Pa.m^2/s $ & Nr |
294 |
&\begin{minipage}[t]{3in} |
295 |
{Meridional Diffusive Flux of Pot.Temperature} |
296 |
\end{minipage}\\ |
297 |
DFrI\_TH & $K.Pa.m^2/s $ & Nr |
298 |
&\begin{minipage}[t]{3in} |
299 |
{Vertical Diffusive Flux of Pot.Temperature (Implicit part)} |
300 |
\end{minipage}\\ |
301 |
ADVr\_SLT & $g/kg.Pa.m^2/s$ & Nr |
302 |
&\begin{minipage}[t]{3in} |
303 |
{Vertical Advective Flux of Water-Vapor} |
304 |
\end{minipage}\\ |
305 |
ADVx\_SLT & $g/kg.Pa.m^2/s$ & Nr |
306 |
&\begin{minipage}[t]{3in} |
307 |
{Zonal Advective Flux of Water-Vapor} |
308 |
\end{minipage}\\ |
309 |
ADVy\_SLT & $g/kg.Pa.m^2/s$ & Nr |
310 |
&\begin{minipage}[t]{3in} |
311 |
{Meridional Advective Flux of Water-Vapor} |
312 |
\end{minipage}\\ |
313 |
DFrE\_SLT & $g/kg.Pa.m^2/s$ & Nr |
314 |
&\begin{minipage}[t]{3in} |
315 |
{Vertical Diffusive Flux of Water-Vapor (Explicit part)} |
316 |
\end{minipage}\\ |
317 |
DIFx\_SLT & $g/kg.Pa.m^2/s$ & Nr |
318 |
&\begin{minipage}[t]{3in} |
319 |
{Zonal Diffusive Flux of Water-Vapor} |
320 |
\end{minipage}\\ |
321 |
DIFy\_SLT & $g/kg.Pa.m^2/s$ & Nr |
322 |
&\begin{minipage}[t]{3in} |
323 |
{Meridional Diffusive Flux of Water-Vapor} |
324 |
\end{minipage}\\ |
325 |
DFrI\_SLT & $g/kg.Pa.m^2/s$ & Nr |
326 |
&\begin{minipage}[t]{3in} |
327 |
{Vertical Diffusive Flux of Water-Vapor (Implicit part)} |
328 |
\end{minipage}\\ |
329 |
\end{tabular} |
330 |
\end{table} |
331 |
\vspace{1.5in} |
332 |
\vfill |
333 |
|
334 |
\newpage |
335 |
\vspace*{\fill} |
336 |
\begin{table} |
337 |
\begin{tabular}{llll} |
338 |
\hline\hline |
339 |
NAME & UNITS & LEVELS & DESCRIPTION \\ |
340 |
\hline |
341 |
|
342 |
&\\ |
343 |
SDIAG1 & & 1 |
344 |
&\begin{minipage}[t]{3in} |
345 |
{User-Defined Surface Diagnostic-1} |
346 |
\end{minipage}\\ |
347 |
SDIAG2 & & 1 |
348 |
&\begin{minipage}[t]{3in} |
349 |
{User-Defined Surface Diagnostic-2} |
350 |
\end{minipage}\\ |
351 |
SDIAG3 & & 1 |
352 |
&\begin{minipage}[t]{3in} |
353 |
{User-Defined Surface Diagnostic-3} |
354 |
\end{minipage}\\ |
355 |
SDIAG4 & & 1 |
356 |
&\begin{minipage}[t]{3in} |
357 |
{User-Defined Surface Diagnostic-4} |
358 |
\end{minipage}\\ |
359 |
SDIAG5 & & 1 |
360 |
&\begin{minipage}[t]{3in} |
361 |
{User-Defined Surface Diagnostic-5} |
362 |
\end{minipage}\\ |
363 |
SDIAG6 & & 1 |
364 |
&\begin{minipage}[t]{3in} |
365 |
{User-Defined Surface Diagnostic-6} |
366 |
\end{minipage}\\ |
367 |
SDIAG7 & & 1 |
368 |
&\begin{minipage}[t]{3in} |
369 |
{User-Defined Surface Diagnostic-7} |
370 |
\end{minipage}\\ |
371 |
SDIAG8 & & 1 |
372 |
&\begin{minipage}[t]{3in} |
373 |
{User-Defined Surface Diagnostic-8} |
374 |
\end{minipage}\\ |
375 |
SDIAG9 & & 1 |
376 |
&\begin{minipage}[t]{3in} |
377 |
{User-Defined Surface Diagnostic-9} |
378 |
\end{minipage}\\ |
379 |
SDIAG10 & & 1 |
380 |
&\begin{minipage}[t]{3in} |
381 |
{User-Defined Surface Diagnostic-1-} |
382 |
\end{minipage}\\ |
383 |
SDIAGC & & 1 |
384 |
&\begin{minipage}[t]{3in} |
385 |
{User-Defined Counted Surface Diagnostic} |
386 |
\end{minipage}\\ |
387 |
SDIAGCC & & 1 |
388 |
&\begin{minipage}[t]{3in} |
389 |
{User-Defined Counted Surface Diagnostic Counter} |
390 |
\end{minipage}\\ |
391 |
UDIAG1 & & Nrphys |
392 |
&\begin{minipage}[t]{3in} |
393 |
{User-Defined Upper-Air Diagnostic-1} |
394 |
\end{minipage}\\ |
395 |
UDIAG2 & & Nrphys |
396 |
&\begin{minipage}[t]{3in} |
397 |
{User-Defined Upper-Air Diagnostic-2} |
398 |
\end{minipage}\\ |
399 |
UDIAG3 & & Nrphys |
400 |
&\begin{minipage}[t]{3in} |
401 |
{User-Defined Multi-Level Diagnostic-3} |
402 |
\end{minipage}\\ |
403 |
UDIAG4 & & Nrphys |
404 |
&\begin{minipage}[t]{3in} |
405 |
{User-Defined Multi-Level Diagnostic-4} |
406 |
\end{minipage}\\ |
407 |
UDIAG5 & & Nrphys |
408 |
&\begin{minipage}[t]{3in} |
409 |
{User-Defined Multi-Level Diagnostic-5} |
410 |
\end{minipage}\\ |
411 |
UDIAG6 & & Nrphys |
412 |
&\begin{minipage}[t]{3in} |
413 |
{User-Defined Multi-Level Diagnostic-6} |
414 |
\end{minipage}\\ |
415 |
UDIAG7 & & Nrphys |
416 |
&\begin{minipage}[t]{3in} |
417 |
{User-Defined Multi-Level Diagnostic-7} |
418 |
\end{minipage}\\ |
419 |
UDIAG8 & & Nrphys |
420 |
&\begin{minipage}[t]{3in} |
421 |
{User-Defined Multi-Level Diagnostic-8} |
422 |
\end{minipage}\\ |
423 |
UDIAG9 & & Nrphys |
424 |
&\begin{minipage}[t]{3in} |
425 |
{User-Defined Multi-Level Diagnostic-9} |
426 |
\end{minipage}\\ |
427 |
UDIAG10 & & Nrphys |
428 |
&\begin{minipage}[t]{3in} |
429 |
{User-Defined Multi-Level Diagnostic-10} |
430 |
\end{minipage}\\ |
431 |
\end{tabular} |
432 |
\end{table} |
433 |
\vspace{1.5in} |
434 |
\vfill |