[MITgcm-support] diagnostics package
Jean-Michel Campin
jmc at ocean.mit.edu
Wed Jun 15 16:49:10 EDT 2005
Hi Matt,
I don't known how this diagnostics was supposed to be filled
(did not find any place where it's done) and therefore why
it is defined (if it is not filled).
There was a real effort to add relevant diagnostics for all the
terms of tracer (T,S) equations but not much has been done
for the momentum equations.
I was in the process of re-arranging the 2 main momentum subroutine
and will include some diagnostics, at the same time or later.
But this might take some time.
Jean-Michel
On Tue, Jun 14, 2005 at 03:02:01PM -0400, Matthew Mazloff wrote:
> Hello,
>
> The vorticity field for my model is not zero, however the output by the
> diagnostics package for VORT was all identically zero.
>
> My model output does not include the file available_diagnostics.log
> (How can I get this output?)
> but according to the available_diagnostics.log provided by Dimitris (see
> below) the parsing array for VORT is
>
> 63 |VORT | 15 |SM ML |(e-4 sec-1) |Relative Vorticity
> (x10^-4 sec^-1)
>
>
>
> This shows it to be 'SM ' but it should be 'SZ ' as it is a
> C-grid corner point. Has this error in the code been fixed or is this
> why I am not receiving vorticity output.
>
> Thanks,
> Matt
>
>
> Dimitris Menemenlis wrote:
>
> >Jeff, first time step you get a file called available_diagnostics.log,
> >attached, which contains the infor you're looking for. D.
> >
> >------------------------------------------------------------------------
> >
> >Total Nb of available Diagnostics: ndiagt= 311
> >------------------------------------------------------------------------
> >Num |<-Name->|Levs|<-parsing code->|<-- Units -->|<- Tile (max=80c)
> >------------------------------------------------------------------------
> > 1 |UFLUX | 1 |UM 002L1 |N/m2 |Zonal Wind Surface
> > Stress (N/m^2)
> > 2 |VFLUX | 1 |VM 001L1 |N/m2 |Meridional Wind
> > Surface Stress (N/m^2)
> > 3 |HFLUX | 1 |SM L1 |watt/m2 |Sensible Heat Flux
> > (pos.upwrd) (W/m^2)
> > 4 |EFLUX | 1 |SM L1 |watt/m2 |Latent Heat Flux
> > (pos.upwrd) (W/m^2)
> > 5 |QICE | 1 |SM L1 |watt/m2 |Heat Conduction
> > through Sea-Ice (W/m^2)
> > 6 |RADLWG | 1 |SM L1 |watt/m2 |Net Upward Longwave
> > Flux at the Ground (W/m^2)
> > 7 |RADSWG | 1 |SM P L1 |watt/m2 |Net Downward
> > Shortwave Flux at the Ground (W/m^2)
> > 8 |RI | 15 |SM LL |non-dimensional |Richardson Number
> > (non-dimensional)
> > 9 |CT | 1 |SM L1 |non-dimensional |Surface Drag Coef for
> > Scalars (non-dimensional)
> > 10 |CU | 1 |SM L1 |non-dimensional |Surface Drag Coef for
> > Winds (non-dimensional)
> > 11 |KM | 15 |SM LL |m2/sec |Eddy Diffusivity
> > Coefficient for Momentum (m^2/s)
> > 12 |KH | 15 |SM LL |m2/sec |Eddy Diffusivity
> > Coefficient for Scalars (m^2/s)
> > 13 |TURBU | 15 |UM 014ML |m/s/day |Zonal Wind Tendency
> > from Turbulence (m/s/day)
> > 14 |TURBV | 15 |VM 013ML |m/s/day |Meridional Wind
> > Tendency from Turbulence (m/s/day)
> > 15 |TURBT | 15 |SM ML |K/day |Temperature Tendency
> > from Turbulence (K/day)
> > 16 |TURBQ | 15 |SM ML |gram/kg/day |Specific Humidity
> > Tendency from Turbulence (g/kg/day)
> > 17 |MOISTT | 15 |SM ML |K/day |Temperature Tendency
> > due to Moist Processes (K/day)
> > 18 |MOISTQ | 15 |SM ML |gram/kg/day |Specific Humidity
> > Tendency due to Moist Processes (g/kg/day)
> > 19 |RADLW | 15 |SM ML |K/day |Temperature Tendency
> > due to Longwave Radiation (K/day)
> > 20 |RADSW | 15 |SM P ML |K/day |Temperature Tendency
> > due to Shortwave Radiation (K/day)
> > 21 |PREACC | 1 |SM P L1 |mm/day |Total Precipitation
> > (mm/day)
> > 22 |PRECON | 1 |SM P L1 |mm/day |Convective
> > Precipitation (mm/day)
> > 23 |TUFLUX | 15 |UM 024LL |N/m2 |Turbulent Flux of
> > Zonal Momentum (N/m^2)
> > 24 |TVFLUX | 15 |VM 023LL |N/m2 |Turbulent Flux of
> > Meridional Momentum (N/m^2)
> > 25 |TTFLUX | 15 |SM LL |watt/m2 |Turbulent Flux of
> > Sensible Heat (W/m^2)
> > 26 |TQFLUX | 15 |SM LL |watt/m2 |Turbulent Flux of
> > Latent Heat (W/m^2)
> > 27 |CN | 1 |SM L1 |non-dimensional |Neutral Drag
> > Coefficient (non-dimensional)
> > 28 |WINDS | 1 |SM L1 |m/sec |Surface Wind Speed
> > (m/s)
> > 29 |DTSRF | 1 |SM L1 |K |Air/Surface Virtual
> > Temperature Difference (deg K)
> > 30 |TGROUND | 1 |SM L1 |K |Ground Temperature
> > (deg K)
> > 31 |TS | 1 |SM L1 |K |Surface Air
> > Temperature (deg K)
> > 32 |DTG | 1 |SM L1 |K |Ground Temperature
> > Adjustment (deg K)
> > 33 |QG | 1 |SM P L1 |gram/kg |Ground Specific
> > Humidity (g/kg)
> > 34 |QS | 1 |SM P L1 |gram/kg |Saturation Surface
> > Specific Humidity (g/kg)
> > 35 |TGRLW | 1 |SM L1 |K |Ground Temperature
> > used by LW Radiation (deg K)
> > 36 |LWGUP | 1 |SM L1 |watt/m2 |Upward Longwave
> > Radiation at the Ground (W/m^2)
> > 37 |OLR | 1 |SM U1 |watt/m2 |Outgoing Longwave
> > Radiation (W/m^2)
> > 38 |OLRCLR | 1 |SM U1 |watt/m2 |Clear Sky Outgoing
> > Longwave Radiation (W/m^2)
> > 39 |LWGCLR | 1 |SM L1 |watt/m2 |Clear Sky Net
> > Longwave Flux at the Ground (W/m^2)
> > 40 |LWCLR | 15 |SM ML |K/day |Clear Sky Longwave
> > Radiation Heating Rates (K/day)
> > 41 |TLW | 15 |SM ML |K |Temperature used by
> > Radiation (deg K)
> > 42 |SHRAD | 15 |SM P ML |gram/kg |Specific Humidity
> > used by Radiation (g/kg)
> > 43 |OZLW | 15 |SM ML |non-dimensional |Ozone mixing ratio
> > used by Longwave Radiation (non-dimensional)
> > 44 |CLDRAS | 15 |SM P ML |0-1 |Convective Cloud
> > Fraction (0-1)
> > 45 |CLDTOT | 15 |SM P ML |0-1 |3-D Total Cloud
> > Fraction (0-1)
> > 46 |LWGDOWN | 1 |SM L1 |watt/m2 |Downward Longwave
> > Radiation at the Ground (W/m^2)
> > 47 |GWDT | 15 |SM ML |K/day |Temperature Tendency
> > due to Gravity Wave Drag (K/day)
> > 48 |RADSWT | 1 |SM P U1 |watt/m2 |Incident Shortwave
> > Radiation at TOA (W/m^2)
> > 49 |TAUCLD | 15 |SM C050ML |non-dimensional |Counted Cloud Optical
> > Depth (non-dimensional) per 100 mb
> > 50 |TAUCLDC | 15 |SM D ML |count |Cloud Optical Depth
> > Counter
> > 51 |CLDLOW | 1 |SM P M1 |0-1 |Low-Level ( 1000-700
> > hPa) Cloud Fraction (0-1)
> > 52 |EVAP | 1 |SM L1 |mm/day |Surface Evaporation
> > (mm/day)
> > 53 |DPDT | 1 |SM L1 |hPa/day |Surface Pressure
> > Tendency (hPa/day)
> > 54 |UAVE | 15 |UU 055MR |m/s |Average Zonal Wind
> > (m/s)
> > 55 |VAVE | 15 |VV 054MR |m/s |Average Meridional
> > Wind (m/s)
> > 56 |TAVE | 15 |SM MR |K |Average Potential
> > Temperature (K)
> > 57 |QAVE | 15 |SM MR |gram/kg |Average Specific
> > Humidity (g/kg)
> > 58 |OMEGA | 15 |SM ML |hPa/day |Vertical Velocity
> > (hPa/day)
> > 59 |DUDT | 15 |UU 060ML |m/s/day |Total Zonal Wind
> > Tendency (m/s/day)
> > 60 |DVDT | 15 |VV 059ML |m/s/day |Total Meridional Wind
> > Tendency (m/s/day)
> > 61 |DTDT | 15 |SM ML |K/day |Total Temperature
> > Tendency (K/day)
> > 62 |DQDT | 15 |SM ML |gram/kg/day |Total Specific
> > Humidity Tendency (g/kg/day)
> > 63 |VORT | 15 |SM ML |(e-4 sec-1) |Relative Vorticity
> > (x10^-4 sec^-1)
> > 64 |PSIGDOT | 15 |SM LL |hPa/day |Pi-Weighted Vertical
> > Sigma Velocity (hPa/day)
> > 65 |DTLS | 15 |SM ML |K/day |Temperature Tendency
> > due to Stratiform Processes (K/day)
> > 66 |DQLS | 15 |SM ML |gram/kg/day |Specific Humidity
> > Tendency from Stratiform Processes (g/kg/day)
> > 67 |USTAR | 1 |SM L1 |m/sec |Friction Velocity
> > (m/s)
> > 68 |Z0 | 1 |SM L1 |m |Surface Roughness Z0
> > (m)
> > 69 |FRQTRB | 14 |SM P MM |0-1 |Frequency of
> > Turbulence (0-1)
> > 70 |PBL | 1 |SM P M1 |hPa |Estimated PBL Depth
> > (hPa)
> > 71 |SWCLR | 15 |SM P ML |K/day |Clear Sky Shortwave
> > Heating Rates (K/day)
> > 72 |OSR | 1 |SM P U1 |watt/m2 |Outgoing Shortwave
> > Radiation (W/m^2)
> > 73 |OSRCLR | 1 |SM P U1 |watt/m2 |Clear Sky Outgoing
> > Shortwave Radiation (W/m^2)
> > 74 |CLDMAS | 15 |SM P LL |g/m2/sec |Cloud Mass Flux
> > (g/m^2/sec)
> > 75 |UWND | 15 |UU 076ML |m/sec |Time-Averaged Zonal
> > Wind (m/s)
> > 76 |VWND | 15 |VV 075ML |m/sec |Time-Averaged
> > Meridional Wind (m/s)
> > 77 |TMPU | 15 |SM ML |K |Time-Averaged
> > Temperature (deg K)
> > 78 |SPHU | 15 |SM P ML |gram/kg |Time-Averaged
> > Specific Humidity (g/kg)
> > 79 |RFT | 15 |SM ML |K/day |Temperature Tendency
> > due to Rayleigh Friction (K/day)
> > 80 |PS | 1 |SM L1 |hPa |Time-Averaged Surface
> > Pressure (hPa)
> > 81 |TKE | 15 |SM P LL |(m/sec)2 |Time-Averaged
> > Turbulent Kinetic Energy (m/s)^2
> > 82 |SWGCLR | 1 |SM P L1 |watt/m2 |Clear Sky Net
> > Downward SW Radiation at the Ground (W/m^2)
> > 83 |PAVE | 1 |SM L1 |hPa/day |Average Surface
> > Pressure (hPa)
> > 84 |SDIAG1 | 1 |SM L1 |user-defined |User-Defined Surface
> > Diagnostic #1
> > 85 |SDIAG2 | 1 |SM L1 |user-defined |User-Defined Surface
> > Diagnostic #2
> > 86 |UDIAG1 | 15 |SM ML |user-defined |User-Defined
> > Upper-Air Diagnostic #1
> > 87 |UDIAG2 | 15 |SM ML |user-defined |User-Defined
> > Upper-Air Diagnostic #2
> > 88 |DIABU | 15 |UU 089ML |m/s/day |Zonal Wind Tendency
> > due to Diabatic Forcing (m/s/day)
> > 89 |DIABV | 15 |VV 088ML |m/s/day |Meridional Wind
> > Tendency due to Diabatic Forcing (m/s/day)
> > 90 |DIABT | 15 |SM ML |K/day |Temperature Tendency
> > due to Diabatic Forcing (K/day)
> > 91 |DIABQ | 15 |SM ML |gram/kg/day |Specific Humidity
> > Tendency due to Diabatic Forcing (g/kg/day)
> > 92 |RFU | 15 |UU 093ML |m/s/day |Zonal Wind Tendency
> > due to Rayleigh Friction (m/s/day)
> > 93 |RFV | 15 |VV 092ML |m/s/day |Meridional Wind
> > Tendency due to Rayleigh Friction (m/s/day)
> > 94 |GWDU | 15 |UM 095ML |m/s/day |Zonal Wind Tendency
> > due to Gravity Wave Drag (m/s/day)
> > 95 |GWDV | 15 |VM 094ML |m/s/day |Meridional Wind
> > Tendency due to Gravity Wave Drag (m/s/day)
> > 96 |GWDUS | 1 |UM 097L1 |N/m2 |Zonal Wind Gravity
> > Wave Surface Stress (N/m^2)
> > 97 |GWDVS | 1 |VM 096L1 |N/m2 |Meridional Wind
> > Gravity Wave Surface Stress (N/m^2)
> > 98 |GWDUT | 1 |UM 099U1 |N/m2 |Zonal Wind Gravity
> > Wave Stress at Model Top (N/m^2)
> > 99 |GWDVT | 1 |VM 098U1 |N/m2 |Meridional Wind
> > Gravity Wave Stress at Model Top (N/m^2)
> >------------------------------------------------------------------------
> >Num |<-Name->|Levs|<-parsing code->|<-- Units -->|<- Tile (max=80c)
> >------------------------------------------------------------------------
> >100 |LZRAD | 15 |SM ML |mg/kg |Estimated Cloud
> >Liquid Water used in Radiation (mg/kg)
> >101 |SLP | 1 |SM L1 |hPa |Time-Averaged
> >Sea-Level Pressure (mb)
> >102 |VAVEUQ | 1 |UM 103M1 |m/s gram/kg |Vertically Averaged
> >UWND*SPHU (m/s g/kg)
> >103 |VAVEVQ | 1 |VM 102M1 |m/s gram/kg |Vertically Averaged
> >VWND*SPHU (m/s g/kg)
> >104 |VAVEUT | 1 |UM 105M1 |m/s K |Vertically Averaged
> >UWND*TMPU (m/s deg K)
> >105 |VAVEVT | 1 |VM 104M1 |m/s K |Vertically Averaged
> >VWND*TMPU (m/s deg K)
> >106 |CLDFRC | 1 |SM P M1 |0-1 |2-D Total Cloud
> >Fraction (0-1)
> >107 |TPW | 1 |SM P M1 |gram/cm2 |Total Precipitable
> >Water (g/cm^2)
> >108 |U2M | 1 |UM 109M1 |m/sec |Zonal Wind
> >Interpolated to 2 Meters (m/s)
> >109 |V2M | 1 |VM 108M1 |m/sec |Meridional Wind
> >Interpolated to 2 Meters (m/s)
> >110 |T2M | 1 |SM M1 |K |Temperature
> >Interpolated to 2 Meters (deg K)
> >111 |Q2M | 1 |SM P M1 |gram/kg |Specific Humidity
> >Interpolated to 2 Meters (g/kg)
> >112 |U10M | 1 |UM 113M1 |m/sec |Zonal Wind
> >Interpolated to 10 Meters (m/s)
> >113 |V10M | 1 |VM 112M1 |m/sec |Meridional Wind
> >Interpolated to 10 Meters (m/s)
> >114 |T10M | 1 |SM M1 |K |Temperature
> >Interpolated to 10 Meters (deg K)
> >115 |Q10M | 1 |SM P M1 |gram/kg |Specific Humidity
> >Interpolated to 10 Meters (g/kg)
> >116 |DTRAIN | 15 |SM P LL |g/m2/sec |Detrainment Cloud
> >Mass Flux (g/m^2/sec)
> >117 |QFILL | 15 |SM ML |gram/kg/day |Filling of Negative
> >Specific Humidity (g/kg/day)
> >118 |VAVEQAVE| 1 |SM M1 |mm/day |Vertically Averaged
> >QAVE (mm/day)
> >119 |VAVEQFIL| 1 |SM P L1 |mm/day |Vertically Averaged
> >QFILL (mm/day)
> >120 | | 0 | | |
> >121 | | 0 | | |
> >122 | | 0 | | |
> >123 | | 0 | | |
> >124 |SDIAG3 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #3
> >125 |SDIAG4 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #4
> >126 |SDIAG5 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #5
> >127 |SDIAG6 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #6
> >128 |SDIAG7 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #7
> >129 |SDIAG8 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #8
> >130 |SDIAG9 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #9
> >131 |SDIAG10 | 1 |SM L1 |user-defined |User-Defined Surface
> >Diagnostic #10
> >132 |UDIAG3 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #3
> >133 |UDIAG4 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #4
> >134 |UDIAG5 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #5
> >135 |UDIAG6 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #6
> >136 |UDIAG7 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #7
> >137 |UDIAG8 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #8
> >138 |UDIAG9 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #9
> >139 |UDIAG10 | 15 |SM ML |user-defined |User-Defined
> >Upper-Air Diagnostic #10
> >140 |CLDMID | 1 |SM P M1 |0-1 |Mid-Level (700-400
> >hPa) Cloud Fraction (0-1)
> >141 |CLDHI | 1 |SM P M1 |0-1 |High-Level (above 400
> >hPa) Cloud Fraction (0-1)
> >142 |TAULOW | 1 |SM PC150M1 |non-dimensional |Low-Level (1000-700
> >hPa) Optical Depth
> >143 |TAUMID | 1 |SM PC151M1 |non-dimensional |Mid-Level (700-400
> >hPa) Optical Depth
> >144 |TAUHI | 1 |SM PC152M1 |non-dimensional |High-Level (above 400
> >hPa) Optical Depth
> >145 |CLDNP | 15 |SM ML |0-1 |Non-Precipitating
> >Cloud Fraction (0-1)
> >146 |CLDPRS | 1 |SM PC147M1 |hPa |Cloud Top Pressure
> >(when cloudy) (hPa)
> >147 |CTPCNT | 1 |SM D M1 |count |Cloud Top Pressure
> >Counter
> >148 |CLDTMP | 1 |SM PC149M1 |K |Cloud Top Temperature
> >(when cloudy) (deg K)
> >149 |CTTCNT | 1 |SM D M1 |count |Cloud Top Temperature
> >Counter
> >150 |TAULOWC | 1 |SM D M1 |count |Low-Level Optical
> >Depth Counter
> >151 |TAUMIDC | 1 |SM D M1 |count |Mid-Level Optical
> >Depth Counter
> >152 |TAUHIC | 1 |SM D M1 |count |High-Level Optical
> >Depth Counter
> >153 |TCANOPY | 1 |SM L1 |K |Skin Temperature of
> >the Canopy/Soil (SST over water) (deg K)
> >154 |TDEEP | 1 |SM L1 |K |Deep Soil Temperature
> >(deg K)
> >155 |QCANOPY | 1 |SM L1 |gram/kg |Specific Humidity of
> >the Canopy (g/kg)
> >156 |SMSHAL | 1 |SM L1 |0-1 |Soil Moisture Field
> >Capacity Fraction in Shallow (5 mm) Layer
> >157 |SMROOT | 1 |SM L1 |0-1 |Soil Moisture Field
> >Capacity Fraction in Root Zone
> >158 |SMDEEP | 1 |SM L1 |0-1 |Soil Moisture Field
> >Capacity Fraction in Recharge Layer
> >159 |CAPACITY| 1 |SM L1 |mm |Canopy Interception
> >Reservoir (mm)
> >160 |SNOW | 1 |SM L1 |mm water equiv |Snow Depth (mm water
> >equivalent)
> >161 |RAINCON | 1 |SM L1 |mm/day |Convective Rainfall
> >(liquid precipitate) (mm/day)
> >162 |RAINLSP | 1 |SM L1 |mm/day |Large-scale Rainfall
> >(liquid precipitate) (mm/day)
> >163 |SNOWFALL| 1 |SM P L1 |mm/day |Total Snowfall (solid
> >precipitate) (mm/day)
> >164 |RUNOFF | 1 |SM L1 |mm/sec |Water from
> >precipitation not infiltrated into soil (mm/s)
> >165 |FWSOIL | 1 |SM L1 |mm/sec |Rainwater
> >Infiltration into top soil layer (mm/s)
> >166 |GDRAIN | 1 |SM L1 |mm/sec |Diffusion of Moisture
> >across bottom of root zone (mm/s)
> >167 |SNOWMELT| 1 |SM L1 |mm/sec |Rate of Snow Melt
> >(mm/s)
> >168 |ERESV | 1 |SM L1 |watt/m2 |Latent Heat Flux from
> >Canopy Interception Reservoir (W/m^2)
> >169 |ESOIL | 1 |SM L1 |watt/m2 |Latent Heat Flux from
> >Bare Soil (W/m^2)
> >170 |EVEG | 1 |SM L1 |watt/m2 |Latent Heat Flux
> >(Transpiration) from Vegetated Surface (W/m^2)
> >171 |ESNOW | 1 |SM L1 |watt/m2 |Latent Heat Flux from
> >Snow Pack (W/m^2)
> >172 |PARDF | 1 |SM P L1 |watt/m2 |Diffuse-beam
> >Photosynthetically Active Radiation (W/m^2)
> >173 |PARDR | 1 |SM P L1 |watt/m2 |Direct-beam
> >Photosynthetically Active Radiation (W/m^2)
> >174 |LAI | 1 |SM L1 |percent |Leaf Area Index (%)
> >175 |GREEN | 1 |SM L1 |percent |Green-ness Index (%)
> >176 |DLWDTC | 1 |SM L1 |watt/m2/K |Derivative of Upward
> >LW Radiation wrt TCANOPY (W/m^2 /deg K)
> >177 |DHDTC | 1 |SM L1 |watt/m2/K |Derivative of
> >Sensible Heat Flux wrt TCANOPY (W/m^2 /deg K)
> >178 |DEDTC | 1 |SM L1 |watt/m2/K |Derivative of Latent
> >Heat Flux wrt TCANOPY (W/m^2 /deg K)
> >179 |VDTMOIST| 1 |SM M1 |K/day |Vertically Averaged
> >MOISTT (K/day)
> >180 |VDTTURB | 1 |SM M1 |K/day |Vertically Averaged
> >TURBT (K/day)
> >181 |VDTLWRAD| 1 |SM M1 |K/day |Vertically Averaged
> >RADLW (K/day)
> >182 |VDTSWRAD| 1 |SM P M1 |K/day |Vertically Averaged
> >RADSW (K/day)
> >183 |VAVETAVE| 1 |SM M1 |K/day |Vertically Averaged
> >TAVE (K/day)
> >184 |PSUBCLD | 1 |SM PC185M1 |hPa |Pressure Thickness of
> >the RAS Subcloud Layer (mb)
> >185 |PSUBCLDC| 1 |SM PD M1 |count |Pressure Thickness of
> >the RAS Subcloud Layer Counter
> >186 |LCL | 1 |SM L1 |hPa |Lifting Condensation
> >Level (mb)
> >187 |SDIAGC | 1 |SM C188L1 |user-defined |User-Defined Counted
> >Surface Diagnostic
> >188 |SDIAGCC | 1 |SM D L1 |count |User-Defined Counted
> >Surface Diagnostic Counter
> >189 | | 0 | 0 | |
> >190 |EVPOT | 1 |SM L1 |watt/m2 |Potential
> >Evapotranspiration (W/m^2)
> >191 |RHCHECK | 1 |SM P L1 |mm/day |Net precip due to
> >supersaturation above critical RH (mm/day)
> >192 |DHDQA | 1 |SM L1 |watt/m2 |Derivative of
> >Sensible Heat wrt Canopy Humidity (W/m^2)
> >193 |DEDQA | 1 |SM L1 |watt/m2 |Derivative of Latent
> >Heat wrt Canopy Humidity (W/m^2)
> >194 |DTC | 1 |SM L1 |K/sec |Total Change in
> >Canopy Temperature (deg/sec)
> >195 |DQC | 1 |SM L1 |sec-1 |Change in Canopy
> >Humidity (kg/kg/sec)
> >196 |TCDTC | 1 |SM L1 |K/sec |Change in Canopy
> >Temperature - Energy Term (deg/sec)
> >197 |RADDTC | 1 |SM L1 |K/sec |Change in Canopy
> >Temperature - Net Radiation Term (deg/sec)
> >198 |SENDDTC | 1 |SM L1 |K/sec |Change in Canopy
> >Temperature - Sensible Heat Term (deg/sec)
> >199 |LATDTC | 1 |SM L1 |K/sec |Change in Canopy
> >Temperature - Latent Heat Term (deg/sec)
> >------------------------------------------------------------------------
> >Num |<-Name->|Levs|<-parsing code->|<-- Units -->|<- Tile (max=80c)
> >------------------------------------------------------------------------
> >200 |TDDTC | 1 |SM L1 |K/sec |Change in Canopy
> >Temperature - Ground Temp Term (deg/sec)
> >201 |QCDTC | 1 |SM L1 |K/sec |Change in Canopy
> >Temperature - Humidity Term (deg/sec)
> >202 |TRBQLIQ | 15 |SM ML |mg/kg |Cloud Liquid Water
> >Generated in Turbulence (mg/kg)
> >203 |TRBFCC | 15 |SM ML |0-1 |Cloud Fraction
> >Generated in Turbulence (fraction)
> >204 |ALBEDO | 1 |SM C210L1 |0-1 |Mean Surface Albedo
> >(SW_Up/SW_Down) 0-1
> >205 |ALBVISDR| 1 |SM L1 |0-1 |Direct Beam VIS
> >Surface Albedo (0-1)
> >206 |ALBVISDF| 1 |SM L1 |0-1 |Diffuse Beam VIS
> >Surface Albedo (0-1)
> >207 |ALBNIRDR| 1 |SM L1 |0-1 |Direct Beam NIR
> >Surface Albedo (0-1)
> >208 |ALBNIRDF| 1 |SM L1 |0-1 |Diffuse Beam NIR
> >Surface Albedo (0-1)
> >209 |TAUAVE | 15 |SM ML |non-dimensional |Averaged Cloud
> >Optical Depth (non-dimensional) per 100 mb
> >210 |ALBEDOC | 1 |SM D L1 |count |Surface Albedo Counter
> >211 |RHCHECKT| 15 |SM ML |K/day |Temperature Change
> >due to humidity above critical RH (K/day)
> >212 |RHCHECKQ| 15 |SM ML |g/kg/day |Spec.Humid. Change
> >due to humidity above critical RH (g/kg/day)
> >213 |CLDLSP | 15 |SM P ML |0-1 |Large-Scale Cloud
> >Fraction (0-1)
> >214 |LZLOW | 1 |SM P L1 |mg/cm2 |Vert integrated
> >low-level (below 700mb) cloud water (mg/cm**2)
> >215 |LZMID | 1 |SM P L1 |mg/cm2 |Vert integrated
> >mid-level (700-400mb) cloud water (mg/cm**2)
> >216 |LZHI | 1 |SM P L1 |mg/cm2 |Vert integrated
> >high-level (above 400mb) cloud water (mg/cm**2)
> >217 |LZTOT | 1 |SM P L1 |mg/cm2 |Vertically integrated
> >total suspended cloud water (mg/cm**2)
> >218 |CAPE | 1 |SM P L1 |mb m2/sec2 |Convective Available
> >Potential Energy
> >219 |HSUBCL | 1 |SM P L1 |m2/sec2 |Moist Static Energy
> >in RAS subcloud layer
> >220 |HSTAR | 15 |SM P ML |m2/sec2 |Saturation Moist
> >Static Energy
> >221 |CONT | 15 |SM ML |K/day |Temperature Tendency
> >due to Convective Precipitation (K/day)
> >222 |CONQ | 15 |SM ML |g/kg/day |Moisture Tendency due
> >to Convective Precipitation (g/kg/day)
> >223 |LST | 15 |SM ML |K/day |Temperature Tendency
> >due to Large Scale Precipitation (K/day)
> >224 |LSQ | 15 |SM ML |g/kg/day |Moisture Tendency due
> >to Large Scale Precipitation (g/kg/day)
> >225 |CONEVPT | 15 |SM ML |K/day |Temperature Tendency
> >due to Conv Rain Re-evaporation (K/day)
> >226 |CONEVPQ | 15 |SM ML |g/kg/day |Moisture Tendency due
> >to Conv Rain Re-evaporation (g/kg/day)
> >227 |LSEVPT | 15 |SM ML |K/day |Temperature Tendency
> >due to Large Scale Rain Re-evap (K/day)
> >228 |LSEVPQ | 15 |SM ML |g/kg/day |Moisture Tendency due
> >to Large Scale Rain Re-evap (g/kg/day)
> >229 |GWCUMID | 1 |UM 230L1 |m/sec |Mid-Lev Mean U-Wind
> >for Gravity Wave Drag w/Clouds (m/sec)
> >230 |GWCVMID | 1 |VM 229L1 |m/sec |Mid-Lev Mean V-Wind
> >for Gravity Wave Drag w/Clouds (m/sec)
> >231 |CLDSTD | 1 |SM L1 |m |Mid-Lev Cloud Perturb
> >Length for Gravity Wave Drag w/Clouds (m)
> >232 |GWCUBAR | 1 |UM 233L1 |m/sec |Mid-Lev Perturb
> >U-Wind for Gravity Wave Drag w/Clouds (m/sec)
> >233 |GWCVBAR | 1 |VM 232L1 |m/sec |Mid-Lev Perturb
> >V-Wind for Gravity Wave Drag w/Clouds (m/sec)
> >234 |GWCUS | 1 |UM 235L1 |N/m2 |Mid-Lev U-Wind Stress
> >for Gravity Wave Drag w/Clouds (N/m^2)
> >235 |GWCVS | 1 |VM 234L1 |N/m2 |Mid-Lev V-Wind Stress
> >for Gravity Wave Drag w/Clouds (N/m^2)
> >236 |GWCU | 15 |UM 237ML |m/sec/day |U-Wind Tendency due
> >to Gravity Wave Drag w/Clouds (m/s/day)
> >237 |GWCV | 15 |VM 236ML |m/sec/day |V-Wind Tendency due
> >to Gravity Wave Drag w/Clouds (m/s/day)
> >238 |ETAN | 1 |SM M1 |m |Perturbation of
> >Surface (pressure, height) (Pa,m)
> >239 |ETANSQ | 1 |SM M1 |m^2 |Square of
> >Perturbation of Sfc (Pa^2,m^2)
> >240 |DETADT2 | 1 |SM M1 |m^2/s^2 |Square of Eta
> >(Surf.P,SSH) Tendency ((r_unit/s)^2)
> >241 |THETA | 15 |SM MR |degC |Potential Temperature
> >(degC,K)
> >242 |SALT | 15 |SM MR |psu |Salt or Water Vapor
> >mixing ratio (g/kg)
> >243 |UVEL | 15 |UU 244MR |m/s |Zonal Component of
> >Velocity (m/s)
> >244 |VVEL | 15 |VV 243MR |m/s |Meridional Component
> >of Velocity (m/s)
> >245 |WVEL | 15 |WM LR |m/s |Vertical Component of
> >Velocity (r_units/s)
> >246 |THETASQ | 15 |SM MR |degC^2 |Square of Potential
> >Temperature (K^2)
> >247 |SALTSQ | 15 |SM MR |(psu)^2 |Square of Salt or
> >Water Vapor mix rat (g^2/kg^2)
> >248 |UVELSQ | 15 |UU 249MR |m^2/s^2 |Square of Zonal Comp
> >of Velocity (m^2/s^2)
> >249 |VVELSQ | 15 |VV 248MR |m^2/s^2 |Square of Meridional
> >Comp of Velocity (m^2/s^2)
> >250 |WVELSQ | 15 |WM LR |m^2/s^2 |Square of Vertical
> >Comp of Velocity (m^2/s^2)
> >251 |UV_VEL_C| 15 |UM 251MR |m^2/s^2 |Product of horizontal
> >Comp of velocity (cell center)
> >252 |UV_VEL_Z| 15 |UZ 252MR |m^2/s^2 |Meridional Transport
> >of Zonal Momentum (m^2/s^2)
> >253 |WU_VEL | 15 |WU LR |m.m/s^2 |Vertical Transport of
> >Zonal Momentum (m^2/s^2)
> >254 |WV_VEL | 15 |WV LR |m.m/s^2 |Vertical Transport of
> >Meridional Momentum (m^2/s^2)
> >255 |UVELMASS| 15 |UU 256MR |m/s |Zonal Mass-Weighted
> >Comp of Velocity (m/s)
> >256 |VVELMASS| 15 |VV 255MR |m/s |Meridional
> >Mass-Weighted Comp of Velocity (m/s)
> >257 |WVELMASS| 15 |WM LR |m/s |Vertical
> >Mass-Weighted Comp of Velocity (m/s)
> >258 |UTHMASS | 15 |UU 259MR |degC.m/s |Zonal Mass-Weight
> >Transp of Pot Temp (K.m/s)
> >259 |VTHMASS | 15 |VV 258MR |degC.m/s |Meridional
> >Mass-Weight Transp of Pot Temp (K.m/s)
> >260 |WTHMASS | 15 |WM LR |degC.m/s |Vertical Mass-Weight
> >Transp of Pot Temp (K.m/s)
> >261 |USLTMASS| 15 |UU 262MR |psu.m/s |Zonal Mass-Weight
> >Transp of Salt (g/kg.m/s)
> >262 |VSLTMASS| 15 |VV 261MR |psu.m/s |Meridional
> >Mass-Weight Transp of Salt (g/kg.m/s)
> >263 |WSLTMASS| 15 |WM LR |psu.m/s |Vertical Mass-Weight
> >Transp of Salt (g/kg.m/s)
> >264 |UVELTH | 15 |UU 265MR |degC.m/s |Zonal Transp of Pot
> >Temp (K.m/s)
> >265 |VVELTH | 15 |VV 264MR |degC.m/s |Meridional Transp of
> >Pot Temp (K.m/s)
> >266 |WVELTH | 15 |WM LR |degC.m/s |Vertical Transp of
> >Pot Temp (K.m/s)
> >267 |UVELSLT | 15 |UU 268MR |psu.m/s |Zonal Transp of Salt
> >(g/kg.m/s)
> >268 |VVELSLT | 15 |VV 267MR |psu.m/s |Meridional Transp of
> >Salt (g/kg.m/s)
> >269 |WVELSLT | 15 |WM LR |psu.m/s |Vertical Transp of
> >Salt (g/kg.m/s)
> >270 |RHOAnoma| 15 |SM MR |kg/m^3 |Density Anomaly
> >(=Rho-rhoConst)
> >271 |RHOANOSQ| 15 |SM MR |kg^2/m^6 |Square of Density
> >Anomaly (=(Rho-rhoConst)^2)
> >272 |URHOMASS| 15 |UU 273MR |kg/m^2/s |Zonal Transport of
> >Density
> >273 |VRHOMASS| 15 |VV 272MR |kg/m^2/s |Meridional Transport
> >of Density
> >274 |WRHOMASS| 15 |WM LR |kg/m^2/s |Vertical Transport of
> >Potential Density
> >275 |PHIHYD | 15 |SM MR |m^2/s^2 |Hydrostatic (ocean)
> >pressure / (atmos) geo-Potential
> >276 |PHIBOT | 1 |SM M1 |m^2/s^2 |ocean bottom pressure
> >/ top. atmos geo-Potential
> >277 |PHIBOTSQ| 1 |SM M1 |m^4/s^4 |Square of ocean
> >bottom pressure / top. geo-Potential
> >278 |DRHODR | 15 |SM LR |kg/m^4 |Stratification:
> >d.Sigma/dr (kg/m3/r_unit)
> >279 |VISCA4 | 15 |SM MR |m^4/s |Biharmonic Viscosity
> >Coefficient in (m4/s)
> >280 |VISCAH | 15 |SM MR |m^2/s |Harmonic Viscosity
> >Coefficient in (m2/s)
> >281 |TAUX | 1 |SU U1 |N/m^2 |zonal surface wind
> >stress, >0 increases uVel
> >282 |TAUY | 1 |SV U1 |N/m^2 |meridional surf. wind
> >stress, >0 increases vVel
> >283 |TFLUX | 1 |SM U1 |W/m^2 |net surface heat
> >flux, >0 increases theta
> >284 |TRELAX | 1 |SM U1 |W/m^2 |surface temperature
> >relaxation, >0 increases theta
> >285 |TICE | 1 |SM U1 |W/m^2 |heat from melt/freeze
> >of sea-ice, >0 increases theta
> >286 |SFLUX | 1 |SM U1 |g/m^2/s |net surface salt
> >flux, >0 increases salt
> >287 |SRELAX | 1 |SM U1 |g/m^2/s |surface salinity
> >relaxation, >0 increases salt
> >288 |ADVr_TH | 15 |WM LR |degC.m^3/s |Vertical Advective
> >Flux of Pot.Temperature
> >289 |ADVx_TH | 15 |UU 290MR |degC.m^3/s |Zonal Advective
> >Flux of Pot.Temperature
> >290 |ADVy_TH | 15 |VV 289MR |degC.m^3/s |Meridional Advective
> >Flux of Pot.Temperature
> >291 |DFrE_TH | 15 |WM LR |degC.m^3/s |Vertical Diffusive
> >Flux of Pot.Temperature (Explicit part)
> >292 |DIFx_TH | 15 |UU 293MR |degC.m^3/s |Zonal Diffusive
> >Flux of Pot.Temperature
> >293 |DIFy_TH | 15 |VV 292MR |degC.m^3/s |Meridional Diffusive
> >Flux of Pot.Temperature
> >294 |DFrI_TH | 15 |WM LR |degC.m^3/s |Vertical Diffusive
> >Flux of Pot.Temperature (Implicit part)
> >295 |ADVr_SLT| 15 |WM LR |psu.m^3/s |Vertical Advective
> >Flux of Salinity
> >296 |ADVx_SLT| 15 |UU 297MR |psu.m^3/s |Zonal Advective
> >Flux of Salinity
> >297 |ADVy_SLT| 15 |VV 296MR |psu.m^3/s |Meridional Advective
> >Flux of Salinity
> >298 |DFrE_SLT| 15 |WM LR |psu.m^3/s |Vertical Diffusive
> >Flux of Salinity (Explicit part)
> >299 |DIFx_SLT| 15 |UU 300MR |psu.m^3/s |Zonal Diffusive
> >Flux of Salinity
> >------------------------------------------------------------------------
> >Num |<-Name->|Levs|<-parsing code->|<-- Units -->|<- Tile (max=80c)
> >------------------------------------------------------------------------
> >300 |DIFy_SLT| 15 |VV 299MR |psu.m^3/s |Meridional Diffusive
> >Flux of Salinity
> >301 |DFrI_SLT| 15 |WM LR |psu.m^3/s |Vertical Diffusive
> >Flux of Salinity (Implicit part)
> >302 |GM_VisbK| 1 |SM P M1 |m^2/s |Mixing coefficient
> >from Visbeck etal parameterization
> >303 |GM_Kux | 15 |UU P 304MR |m^2/s |K_11 element
> >(U.point, X.dir) of GM-Redi tensor
> >304 |GM_Kvy | 15 |VV P 303MR |m^2/s |K_22 element
> >(V.point, Y.dir) of GM-Redi tensor
> >305 |GM_Kuz | 15 |UU 306MR |m^2/s |K_13 element
> >(U.point, Z.dir) of GM-Redi tensor
> >306 |GM_Kvz | 15 |VV 305MR |m^2/s |K_23 element
> >(V.point, Z.dir) of GM-Redi tensor
> >307 |GM_Kwx | 15 |UM 308LR |m^2/s |K_31 element
> >(W.point, X.dir) of GM-Redi tensor
> >308 |GM_Kwy | 15 |VM 307LR |m^2/s |K_32 element
> >(W.point, Y.dir) of GM-Redi tensor
> >309 |GM_Kwz | 15 |WM P LR |m^2/s |K_33 element
> >(W.point, Z.dir) of GM-Redi tensor
> >310 |GM_PsiX | 15 |UU 311LR |m^2/s |GM Bolus transport
> >stream-function : X component
> >311 |GM_PsiY | 15 |VV 310LR |m^2/s |GM Bolus transport
> >stream-function : Y component
> >------------------------------------------------------------------------
> >Num |<-Name->|Levs|<-parsing code->|<-- Units -->|<- Tile (max=80c)
> >------------------------------------------------------------------------
> >
> >
> >------------------------------------------------------------------------
> >
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