Total Nb of available Diagnostics: ndiagt= 311 ------------------------------------------------------------------------------------ Num |<-Name->|Levs| mate |<- code ->|<-- Units -->|<- Tile (max=80c) ------------------------------------------------------------------------------------ 1 |SDIAG1 | 1 | |SM L1|user-defined |User-Defined Surface Diagnostic #1 2 |SDIAG2 | 1 | |SM L1|user-defined |User-Defined Surface Diagnostic #2 3 |SDIAG3 | 1 | |SM L1|user-defined |User-Defined Surface Diagnostic #3 4 |SDIAG4 | 1 | |SM L1|user-defined |User-Defined Surface Diagnostic #4 5 |SDIAG5 | 1 | |SM L1|user-defined |User-Defined Surface Diagnostic #5 6 |SDIAG6 | 1 | |SM L1|user-defined |User-Defined Surface Diagnostic #6 7 |SDIAG7 | 1 | |SU L1|user-defined |User-Defined U.pt Surface Diagnostic #7 8 |SDIAG8 | 1 | |SV L1|user-defined |User-Defined V.pt Surface Diagnostic #8 9 |SDIAG9 | 1 | 10 |UU L1|user-defined |User-Defined U.vector Surface Diag. #9 10 |SDIAG10 | 1 | 9 |VV L1|user-defined |User-Defined V.vector Surface Diag. #10 11 |UDIAG1 | 90 | |SM MR|user-defined |User-Defined Model-Level Diagnostic #1 12 |UDIAG2 | 90 | |SM MR|user-defined |User-Defined Model-Level Diagnostic #2 13 |UDIAG3 | 90 | |SMR MR|user-defined |User-Defined Model-Level Diagnostic #3 14 |UDIAG4 | 90 | |SMR MR|user-defined |User-Defined Model-Level Diagnostic #4 15 |UDIAG5 | 90 | |SU MR|user-defined |User-Defined U.pt Model-Level Diag. #5 16 |UDIAG6 | 90 | |SV MR|user-defined |User-Defined V.pt Model-Level Diag. #6 17 |UDIAG7 | 90 | 18 |UUR MR|user-defined |User-Defined U.vector Model-Lev Diag.#7 18 |UDIAG8 | 90 | 17 |VVR MR|user-defined |User-Defined V.vector Model-Lev Diag.#8 19 |UDIAG9 | 90 | |SM ML|user-defined |User-Defined Phys-Level Diagnostic #9 20 |UDIAG10 | 90 | |SM ML|user-defined |User-Defined Phys-Level Diagnostic #10 21 |SDIAGC | 1 | 22 |SM C L1|user-defined |User-Defined Counted Surface Diagnostic 22 |SDIAGCC | 1 | |SM L1|count |User-Defined Surface Diagnostic Counter 23 |ETAN | 1 | |SM M1|m |Surface Height Anomaly 24 |ETANSQ | 1 | |SM P M1|m^2 |Square of Surface Height Anomaly 25 |DETADT2 | 1 | |SM M1|m^2/s^2 |Square of Surface Height Anomaly Tendency 26 |THETA | 90 | |SMR MR|degC |Potential Temperature 27 |SALT | 90 | |SMR MR|g/kg |Salinity 28 |RELHUM | 90 | |SMR MR|percent |Relative Humidity 29 |SALTanom| 90 | |SMR MR|g/kg |Salt anomaly (=SALT-35; g/kg) 30 |UVEL | 90 | 31 |UUR MR|m/s |Zonal Component of Velocity (m/s) 31 |VVEL | 90 | 30 |VVR MR|m/s |Meridional Component of Velocity (m/s) 32 |WVEL | 90 | |WM LR|m/s |Vertical Component of Velocity (r_units/s) 33 |THETASQ | 90 | |SMRP MR|degC^2 |Square of Potential Temperature 34 |SALTSQ | 90 | |SMRP MR|(g/kg)^2 |Square of Salinity 35 |SALTSQan| 90 | |SMRP MR|(g/kg)^2 |Square of Salt anomaly (=(SALT-35)^2 (g^2/kg^2) 36 |UVELSQ | 90 | 37 |UURP MR|m^2/s^2 |Square of Zonal Comp of Velocity (m^2/s^2) 37 |VVELSQ | 90 | 36 |VVRP MR|m^2/s^2 |Square of Meridional Comp of Velocity (m^2/s^2) 38 |WVELSQ | 90 | |WM P LR|m^2/s^2 |Square of Vertical Comp of Velocity 39 |UE_VEL_C| 90 | 40 |UMR MR|m/s |Eastward Velocity (m/s) (cell center) 40 |VN_VEL_C| 90 | 39 |VMR MR|m/s |Northward Velocity (m/s) (cell center) 41 |UV_VEL_C| 90 | 41 |UMR MR|m^2/s^2 |Product of horizontal Comp of velocity (cell center) 42 |UV_VEL_Z| 90 | 42 |UZR MR|m^2/s^2 |Meridional Transport of Zonal Momentum (m^2/s^2) 43 |WU_VEL | 90 | |WU LR|m.m/s^2 |Vertical Transport of Zonal Momentum 44 |WV_VEL | 90 | |WV LR|m.m/s^2 |Vertical Transport of Meridional Momentum 45 |UVELMASS| 90 | 46 |UUr MR|m/s |Zonal Mass-Weighted Comp of Velocity (m/s) 46 |VVELMASS| 90 | 45 |VVr MR|m/s |Meridional Mass-Weighted Comp of Velocity (m/s) 47 |WVELMASS| 90 | |WM LR|m/s |Vertical Mass-Weighted Comp of Velocity 48 |PhiVEL | 90 | 45 |SMR P MR|m^2/s |Horizontal Velocity Potential (m^2/s) 49 |PsiVEL | 90 | 48 |SZ P MR|m.m^2/s |Horizontal Velocity Stream-Function 50 |UTHMASS | 90 | 51 |UUr MR|degC.m/s |Zonal Mass-Weight Transp of Pot Temp 51 |VTHMASS | 90 | 50 |VVr MR|degC.m/s |Meridional Mass-Weight Transp of Pot Temp 52 |WTHMASS | 90 | |WM LR|degC.m/s |Vertical Mass-Weight Transp of Pot Temp (K.m/s) 53 |USLTMASS| 90 | 54 |UUr MR|g/kg.m/s |Zonal Mass-Weight Transp of Salinity 54 |VSLTMASS| 90 | 53 |VVr MR|g/kg.m/s |Meridional Mass-Weight Transp of Salinity 55 |WSLTMASS| 90 | |WM LR|g/kg.m/s |Vertical Mass-Weight Transp of Salinity 56 |UVELTH | 90 | 57 |UUR MR|degC.m/s |Zonal Transport of Pot Temp 57 |VVELTH | 90 | 56 |VVR MR|degC.m/s |Meridional Transport of Pot Temp 58 |WVELTH | 90 | |WM LR|degC.m/s |Vertical Transport of Pot Temp 59 |UVELSLT | 90 | 60 |UUR MR|g/kg.m/s |Zonal Transport of Salinity 60 |VVELSLT | 90 | 59 |VVR MR|g/kg.m/s |Meridional Transport of Salinity 61 |WVELSLT | 90 | |WM LR|g/kg.m/s |Vertical Transport of Salinity 62 |UVELPHI | 90 | 63 |UUr MR|m^3/s^3 |Zonal Mass-Weight Transp of Pressure Pot.(p/rho) Anomaly 63 |VVELPHI | 90 | 62 |VVr MR|m^3/s^3 |Merid. Mass-Weight Transp of Pressure Pot.(p/rho) Anomaly 64 |RHOAnoma| 90 | |SMR MR|kg/m^3 |Density Anomaly (=Rho-rhoConst) 65 |RHOANOSQ| 90 | |SMRP MR|kg^2/m^6 |Square of Density Anomaly (=(Rho-rhoConst)^2) 66 |URHOMASS| 90 | 67 |UUr MR|kg/m^2/s |Zonal Transport of Density 67 |VRHOMASS| 90 | 66 |VVr MR|kg/m^2/s |Meridional Transport of Density 68 |WRHOMASS| 90 | |WM LR|kg/m^2/s |Vertical Transport of Density 69 |WdRHO_P | 90 | |WM LR|kg/m^2/s |Vertical velocity times delta^k(Rho)_at-const-P 70 |WdRHOdP | 90 | |WM LR|kg/m^2/s |Vertical velocity times delta^k(Rho)_at-const-T,S 71 |PHIHYD | 90 | |SMR MR|m^2/s^2 |Hydrostatic Pressure Pot.(p/rho) Anomaly 72 |PHIHYDSQ| 90 | |SMRP MR|m^4/s^4 |Square of Hyd. Pressure Pot.(p/rho) Anomaly 73 |PHIBOT | 1 | |SM M1|m^2/s^2 |Bottom Pressure Pot.(p/rho) Anomaly 74 |PHIBOTSQ| 1 | |SM P M1|m^4/s^4 |Square of Bottom Pressure Pot.(p/rho) Anomaly 75 |PHI_SURF| 1 | |SM M1|m^2/s^2 |Surface Dynamical Pressure Pot.(p/rho) 76 |PHIHYDcR| 90 | |SMR MR|m^2/s^2 |Hydrostatic Pressure Pot.(p/rho) Anomaly @ const r 77 |MXLDEPTH| 1 | |SM M1|m |Mixed-Layer Depth (>0) 78 |DRHODR | 90 | |SM LR|kg/m^4 |Stratification: d.Sigma/dr (kg/m3/r_unit) 79 |CONVADJ | 90 | |SMR LR|fraction |Convective Adjustment Index [0-1] 80 |oceTAUX | 1 | 81 |UU U1|N/m^2 |zonal surface wind stress, >0 increases uVel 81 |oceTAUY | 1 | 80 |VV U1|N/m^2 |meridional surf. wind stress, >0 increases vVel 82 |atmPload| 1 | |SM U1|Pa |Atmospheric pressure loading anomaly (vs surf_pRef) 83 |sIceLoad| 1 | |SM U1|kg/m^2 |sea-ice loading (in Mass of ice+snow / area unit) 84 |oceFWflx| 1 | |SM U1|kg/m^2/s |net surface Fresh-Water flux into the ocean (+=down), >0 decreases salinity 85 |oceSflux| 1 | |SM U1|g/m^2/s |net surface Salt flux into the ocean (+=down), >0 increases salinity 86 |oceQnet | 1 | |SM U1|W/m^2 |net surface heat flux into the ocean (+=down), >0 increases theta 87 |oceQsw | 1 | |SM U1|W/m^2 |net Short-Wave radiation (+=down), >0 increases theta 88 |oceFreez| 1 | |SM U1|W/m^2 |heating from freezing of sea-water (allowFreezing=T) 89 |TRELAX | 1 | |SM U1|W/m^2 |surface temperature relaxation, >0 increases theta 90 |SRELAX | 1 | |SM U1|g/m^2/s |surface salinity relaxation, >0 increases salt 91 |surForcT| 1 | |SM U1|W/m^2 |model surface forcing for Temperature, >0 increases theta 92 |surForcS| 1 | |SM U1|g/m^2/s |model surface forcing for Salinity, >0 increases salinity 93 |TFLUX | 1 | |SM U1|W/m^2 |total heat flux (match heat-content variations), >0 increases theta 94 |SFLUX | 1 | |SM U1|g/m^2/s |total salt flux (match salt-content variations), >0 increases salt 95 |RCENTER | 90 | |SM MR|m |Cell-Center Height 96 |RSURF | 1 | |SM M1|m |Surface Height 97 |TOTUTEND| 90 | 98 |UUR MR|m/s/day |Tendency of Zonal Component of Velocity 98 |TOTVTEND| 90 | 97 |VVR MR|m/s/day |Tendency of Meridional Component of Velocity 99 |TOTTTEND| 90 | |SMR MR|degC/day |Tendency of Potential Temperature ------------------------------------------------------------------------------------ Num |<-Name->|Levs| mate |<- code ->|<-- Units -->|<- Tile (max=80c) ------------------------------------------------------------------------------------ 100 |TOTSTEND| 90 | |SMR MR|g/kg/day |Tendency of Salinity 101 |MoistCor| 90 | |SM MR|W/m^2 |Heating correction due to moist thermodynamics 102 |gT_Forc | 90 | |SMR MR|degC/s |Potential Temp. forcing tendency 103 |gS_Forc | 90 | |SMR MR|g/kg/s |Salinity forcing tendency 104 |AB_gT | 90 | |SMR MR|degC/s |Potential Temp. tendency from Adams-Bashforth 105 |AB_gS | 90 | |SMR MR|g/kg/s |Salinity tendency from Adams-Bashforth 106 |gTinAB | 90 | |SMR MR|degC/s |Potential Temp. tendency going in Adams-Bashforth 107 |gSinAB | 90 | |SMR MR|g/kg/s |Salinity tendency going in Adams-Bashforth 108 |AB_gU | 90 | 109 |UUR MR|m/s^2 |U momentum tendency from Adams-Bashforth 109 |AB_gV | 90 | 108 |VVR MR|m/s^2 |V momentum tendency from Adams-Bashforth 110 |ADVr_TH | 90 | |WM LR|degC.m^3/s |Vertical Advective Flux of Pot.Temperature 111 |ADVx_TH | 90 | 112 |UU MR|degC.m^3/s |Zonal Advective Flux of Pot.Temperature 112 |ADVy_TH | 90 | 111 |VV MR|degC.m^3/s |Meridional Advective Flux of Pot.Temperature 113 |DFrE_TH | 90 | |WM LR|degC.m^3/s |Vertical Diffusive Flux of Pot.Temperature (Explicit part) 114 |DFxE_TH | 90 | 115 |UU MR|degC.m^3/s |Zonal Diffusive Flux of Pot.Temperature 115 |DFyE_TH | 90 | 114 |VV MR|degC.m^3/s |Meridional Diffusive Flux of Pot.Temperature 116 |DFrI_TH | 90 | |WM LR|degC.m^3/s |Vertical Diffusive Flux of Pot.Temperature (Implicit part) 117 |ADVr_SLT| 90 | |WM LR|g/kg.m^3/s |Vertical Advective Flux of Salinity 118 |ADVx_SLT| 90 | 119 |UU MR|g/kg.m^3/s |Zonal Advective Flux of Salinity 119 |ADVy_SLT| 90 | 118 |VV MR|g/kg.m^3/s |Meridional Advective Flux of Salinity 120 |DFrE_SLT| 90 | |WM LR|g/kg.m^3/s |Vertical Diffusive Flux of Salinity (Explicit part) 121 |DFxE_SLT| 90 | 122 |UU MR|g/kg.m^3/s |Zonal Diffusive Flux of Salinity 122 |DFyE_SLT| 90 | 121 |VV MR|g/kg.m^3/s |Meridional Diffusive Flux of Salinity 123 |DFrI_SLT| 90 | |WM LR|g/kg.m^3/s |Vertical Diffusive Flux of Salinity (Implicit part) 124 |SALTFILL| 90 | |SM MR|g/kg.m^3/s |Filling of Negative Values of Salinity 125 |VISCAHZ | 90 | |SZ MR|m^2/s |Harmonic Visc Coefficient (m2/s) (Zeta Pt) 126 |VISCA4Z | 90 | |SZ MR|m^4/s |Biharmonic Visc Coefficient (m4/s) (Zeta Pt) 127 |VISCAHD | 90 | |SM MR|m^2/s |Harmonic Viscosity Coefficient (m2/s) (Div Pt) 128 |VISCA4D | 90 | |SM MR|m^4/s |Biharmonic Viscosity Coefficient (m4/s) (Div Pt) 129 |VISCAHW | 90 | |WM LR|m^2/s |Harmonic Viscosity Coefficient (m2/s) (W Pt) 130 |VISCA4W | 90 | |WM LR|m^4/s |Biharmonic Viscosity Coefficient (m4/s) (W Pt) 131 |VAHZMAX | 90 | |SZ MR|m^2/s |CFL-MAX Harm Visc Coefficient (m2/s) (Zeta Pt) 132 |VA4ZMAX | 90 | |SZ MR|m^4/s |CFL-MAX Biharm Visc Coefficient (m4/s) (Zeta Pt) 133 |VAHDMAX | 90 | |SM MR|m^2/s |CFL-MAX Harm Visc Coefficient (m2/s) (Div Pt) 134 |VA4DMAX | 90 | |SM MR|m^4/s |CFL-MAX Biharm Visc Coefficient (m4/s) (Div Pt) 135 |VAHZMIN | 90 | |SZ MR|m^2/s |RE-MIN Harm Visc Coefficient (m2/s) (Zeta Pt) 136 |VA4ZMIN | 90 | |SZ MR|m^4/s |RE-MIN Biharm Visc Coefficient (m4/s) (Zeta Pt) 137 |VAHDMIN | 90 | |SM MR|m^2/s |RE-MIN Harm Visc Coefficient (m2/s) (Div Pt) 138 |VA4DMIN | 90 | |SM MR|m^4/s |RE-MIN Biharm Visc Coefficient (m4/s) (Div Pt) 139 |VAHZLTH | 90 | |SZ MR|m^2/s |Leith Harm Visc Coefficient (m2/s) (Zeta Pt) 140 |VA4ZLTH | 90 | |SZ MR|m^4/s |Leith Biharm Visc Coefficient (m4/s) (Zeta Pt) 141 |VAHDLTH | 90 | |SM MR|m^2/s |Leith Harm Visc Coefficient (m2/s) (Div Pt) 142 |VA4DLTH | 90 | |SM MR|m^4/s |Leith Biharm Visc Coefficient (m4/s) (Div Pt) 143 |VAHZLTHD| 90 | |SZ MR|m^2/s |LeithD Harm Visc Coefficient (m2/s) (Zeta Pt) 144 |VA4ZLTHD| 90 | |SZ MR|m^4/s |LeithD Biharm Visc Coefficient (m4/s) (Zeta Pt) 145 |VAHDLTHD| 90 | |SM MR|m^2/s |LeithD Harm Visc Coefficient (m2/s) (Div Pt) 146 |VA4DLTHD| 90 | |SM MR|m^4/s |LeithD Biharm Visc Coefficient (m4/s) (Div Pt) 147 |VAHZSMAG| 90 | |SZ MR|m^2/s |Smagorinsky Harm Visc Coefficient (m2/s) (Zeta Pt) 148 |VA4ZSMAG| 90 | |SZ MR|m^4/s |Smagorinsky Biharm Visc Coeff. (m4/s) (Zeta Pt) 149 |VAHDSMAG| 90 | |SM MR|m^2/s |Smagorinsky Harm Visc Coefficient (m2/s) (Div Pt) 150 |VA4DSMAG| 90 | |SM MR|m^4/s |Smagorinsky Biharm Visc Coeff. (m4/s) (Div Pt) 151 |momKE | 90 | |SMR MR|m^2/s^2 |Kinetic Energy (in momentum Eq.) 152 |momHDiv | 90 | |SMR MR|s^-1 |Horizontal Divergence (in momentum Eq.) 153 |momVort3| 90 | |SZR MR|s^-1 |3rd component (vertical) of Vorticity 154 |Strain | 90 | |SZR MR|s^-1 |Horizontal Strain of Horizontal Velocities 155 |Tension | 90 | |SMR MR|s^-1 |Horizontal Tension of Horizontal Velocities 156 |Stretch | 90 | |SM MR|s^-1 |Vortex stretching from QG Leith dynamic viscosity 157 |USidDrag| 90 | 158 |UUR MR|m/s^2 |U momentum tendency from Side Drag 158 |VSidDrag| 90 | 157 |VVR MR|m/s^2 |V momentum tendency from Side Drag 159 |Um_Diss | 90 | 160 |UUR MR|m/s^2 |U momentum tendency from Dissipation (Explicit part) 160 |Vm_Diss | 90 | 159 |VVR MR|m/s^2 |V momentum tendency from Dissipation (Explicit part) 161 |Um_ImplD| 90 | 162 |UUR MR|m/s^2 |U momentum tendency from Dissipation (Implicit part) 162 |Vm_ImplD| 90 | 161 |VVR MR|m/s^2 |V momentum tendency from Dissipation (Implicit part) 163 |Um_Advec| 90 | 164 |UUR MR|m/s^2 |U momentum tendency from Advection terms 164 |Vm_Advec| 90 | 163 |VVR MR|m/s^2 |V momentum tendency from Advection terms 165 |Um_Cori | 90 | 166 |UUR MR|m/s^2 |U momentum tendency from Coriolis term 166 |Vm_Cori | 90 | 165 |VVR MR|m/s^2 |V momentum tendency from Coriolis term 167 |Um_dPhiX| 90 | 168 |UUR MR|m/s^2 |U momentum tendency from Pressure/Potential grad 168 |Vm_dPhiY| 90 | 167 |VVR MR|m/s^2 |V momentum tendency from Pressure/Potential grad 169 |Um_Ext | 90 | 170 |UUR MR|m/s^2 |U momentum tendency from external forcing 170 |Vm_Ext | 90 | 169 |VVR MR|m/s^2 |V momentum tendency from external forcing 171 |Um_AdvZ3| 90 | 172 |UUR MR|m/s^2 |U momentum tendency from Vorticity Advection 172 |Vm_AdvZ3| 90 | 171 |VVR MR|m/s^2 |V momentum tendency from Vorticity Advection 173 |Um_AdvRe| 90 | 174 |UUR MR|m/s^2 |U momentum tendency from vertical Advection (Explicit part) 174 |Vm_AdvRe| 90 | 173 |VVR MR|m/s^2 |V momentum tendency from vertical Advection (Explicit part) 175 |botTauX | 1 | 176 |UU U1|N/m^2 |zonal bottom stress, >0 increases uVel 176 |botTauY | 1 | 175 |VV U1|N/m^2 |meridional bottom stress, >0 increases vVel 177 |ADVx_Um | 90 | 178 |UM MR|m^4/s^2 |Zonal Advective Flux of U momentum 178 |ADVy_Um | 90 | 177 |VZ MR|m^4/s^2 |Meridional Advective Flux of U momentum 179 |ADVrE_Um| 90 | |WU LR|m^4/s^2 |Vertical Advective Flux of U momentum (Explicit part) 180 |ADVx_Vm | 90 | 181 |UZ MR|m^4/s^2 |Zonal Advective Flux of V momentum 181 |ADVy_Vm | 90 | 180 |VM MR|m^4/s^2 |Meridional Advective Flux of V momentum 182 |ADVrE_Vm| 90 | |WV LR|m^4/s^2 |Vertical Advective Flux of V momentum (Explicit part) 183 |VISCx_Um| 90 | 184 |UM MR|m^4/s^2 |Zonal Viscous Flux of U momentum 184 |VISCy_Um| 90 | 183 |VZ MR|m^4/s^2 |Meridional Viscous Flux of U momentum 185 |VISrE_Um| 90 | |WU LR|m^4/s^2 |Vertical Viscous Flux of U momentum (Explicit part) 186 |VISrI_Um| 90 | |WU LR|m^4/s^2 |Vertical Viscous Flux of U momentum (Implicit part) 187 |VISCx_Vm| 90 | 188 |UZ MR|m^4/s^2 |Zonal Viscous Flux of V momentum 188 |VISCy_Vm| 90 | 187 |VM MR|m^4/s^2 |Meridional Viscous Flux of V momentum 189 |VISrE_Vm| 90 | |WV LR|m^4/s^2 |Vertical Viscous Flux of V momentum (Explicit part) 190 |VISrI_Vm| 90 | |WV LR|m^4/s^2 |Vertical Viscous Flux of V momentum (Implicit part) 191 |EXFhs | 1 | |SM U1|W/m^2 |Sensible heat flux into ocean, >0 increases theta 192 |EXFhl | 1 | |SM U1|W/m^2 |Latent heat flux into ocean, >0 increases theta 193 |EXFlwnet| 1 | |SM U1|W/m^2 |Net upward longwave radiation, >0 decreases theta 194 |EXFswnet| 1 | |SM U1|W/m^2 |Net upward shortwave radiation, >0 decreases theta 195 |EXFlwdn | 1 | |SM U1|W/m^2 |Downward longwave radiation, >0 increases theta 196 |EXFswdn | 1 | |SM U1|W/m^2 |Downward shortwave radiation, >0 increases theta 197 |EXFqnet | 1 | |SM U1|W/m^2 |Net upward heat flux (turb+rad), >0 decreases theta 198 |EXFtaux | 1 | |UM U1|N/m^2 |zonal surface wind stress, >0 increases uVel 199 |EXFtauy | 1 | |VM U1|N/m^2 |meridional surface wind stress, >0 increases vVel ------------------------------------------------------------------------------------ Num |<-Name->|Levs| mate |<- code ->|<-- Units -->|<- Tile (max=80c) ------------------------------------------------------------------------------------ 200 |EXFuwind| 1 | |UM U1|m/s |zonal 10-m wind speed, >0 eastward 201 |EXFvwind| 1 | |VM U1|m/s |meridional 10-m wind speed, >0 northward 202 |EXFurelw| 1 | |UM U1|m/s |zonal relative 10-m wind speed, >0 eastward 203 |EXFvrelw| 1 | |VM U1|m/s |meridional relative 10-m wind speed, >0 northward 204 |EXFwspee| 1 | |SM U1|m/s |10-m wind speed modulus ( >= 0 ) 205 |EXFatemp| 1 | |SM U1|degK |surface (2-m) air temperature 206 |EXFaqh | 1 | |SM U1|kg/kg |surface (2-m) specific humidity 207 |EXFevap | 1 | |SM U1|m/s |evaporation, > 0 increases salinity 208 |EXFpreci| 1 | |SM U1|m/s |precipitation, > 0 decreases salinity 209 |EXFsnow | 1 | |SM U1|m/s |snow precipitation, > 0 decreases salinity 210 |EXFempmr| 1 | |SM U1|m/s |net upward freshwater flux, > 0 increases salinity 211 |EXFpress| 1 | |SM U1|N/m^2 |atmospheric pressure field 212 |EXFroff | 1 | |SM U1|m/s |river runoff, > 0 decreases salinity 213 |EXFroft | 1 | |SM U1|deg C |river runoff temperature 214 |EXFsalfx| 1 | |SM U1|g/m^2/s |upward salt flux, > 0 decreases salinity 215 |KPPviscA| 90 | |SM P LR|m^2/s |KPP vertical eddy viscosity coefficient 216 |KPPdiffS| 90 | |SM P LR|m^2/s |Vertical diffusion coefficient for salt & tracers 217 |KPPdiffT| 90 | |SM P LR|m^2/s |Vertical diffusion coefficient for heat 218 |KPPghatK| 90 | |SM P LR|0-1 |ratio of KPP non-local (salt) flux relative to surface-flux 219 |KPPhbl | 1 | |SM P 1|m |KPP boundary layer depth, bulk Ri criterion 220 |KPPfrac | 1 | |SM P 1| |Short-wave flux fraction penetrating mixing layer 221 |KPPdbsfc| 90 | |SM P UR|m/s^2 |Buoyancy difference with respect to surface 222 |KPPbfsfc| 90 | |SM P UR|m^2/s^3 |Bo+radiation absorbed to d=hbf*hbl + plume 223 |KPPRi | 90 | |SM P UR|non-dimensional |Bulk Richardson number 224 |KPPbo | 1 | |SM P 1|m^2/s^3 |Surface turbulent buoyancy forcing 225 |KPPbosol| 1 | |SM P 1|m^2/s^3 |surface radiative buoyancy forcing 226 |KPPdbloc| 90 | |SM P UR|m/s^2 |Local delta buoyancy across interfaces 227 |KPPshsq | 90 | |SM P UR|m^2/s^2 |Local shear (V(k-1)-V(k))^2 228 |KPPdVsq | 90 | |SM P UR|m^2/s^2 |Shear relative to surface (V(ksrf)-V(k))**2 229 |KPPnuddt| 90 | |SM P UR|m^2/s |Vertical double diffusion coefficient for heat 230 |KPPnudds| 90 | |SM P UR|m^2/s |Vertical double diffusion coefficient for salt 231 |KPPg_TH | 90 | |WM LR|degC.m^3/s |KPP non-local Flux of Pot.Temperature 232 |KPPg_SLT| 90 | |WM LR|g/kg.m^3/s |KPP non-local Flux of Salinity 233 |FrzForcT| 90 | |SM MR|W/m^2 |Frazil temperature forcing, > 0 increases theta 234 |SIarea | 1 | |SM M1|m^2/m^2 |SEAICE fractional ice-covered area [0 to 1] 235 |SIareaPR| 1 | |SM M1|m^2/m^2 |SIarea preceeding ridging process 236 |SIareaPT| 1 | |SM M1|m^2/m^2 |SIarea preceeding thermodynamic growth/melt 237 |SIheff | 1 | |SM M1|m |SEAICE effective ice thickness 238 |SIheffPT| 1 | |SM M1|m |SIheff preceeeding thermodynamic growth/melt 239 |SIhsnow | 1 | |SM M1|m |SEAICE effective snow thickness 240 |SIhsnoPT| 1 | |SM M1|m |SIhsnow preceeeding thermodynamic growth/melt 241 |SIhsalt | 1 | |SM M1|g/m^2 |SEAICE effective salinity 242 |SIenpa | 1 | |SM M1|W/m^2 |SEAICE power input by surface wind stresses 243 |SIenpw | 1 | |SM M1|W/m^2 |SEAICE work done by ocean drag 244 |SIenph | 1 | |SM M1|W/m^2 |SEAICE power due to change in inertia 245 |SIenpg | 1 | |SM M1|W/m^2 |SEAICE work generated by gravity 246 |SIenpi | 1 | |SM M1|W/m^2 |SEAICE work done by internal stress 247 |SIenpot | 1 | |SM M1|W/m^2 |SEAICE work done to change potential energy 248 |SIpRfric| 1 | |SM M1|W/m^2 |SEAICE dissipation in ridging by internal stresses 249 |SIpSfric| 1 | |SM M1|W/m^2 |SEAICE dissipation in shearing by internal stresses 250 |SItices | 1 | 234 |SM C M1|K |Surface Temperature over Sea-Ice (area weighted) 251 |SIuice | 1 | 252 |UU M1|m/s |SEAICE zonal ice velocity, >0 from West to East 252 |SIvice | 1 | 251 |VV M1|m/s |SEAICE merid. ice velocity, >0 from South to North 253 |SItaux | 1 | 254 |UU U1|N/m^2 |SEAICE zonal surface wind stress, >0 increases uIce 254 |SItauy | 1 | 253 |VV U1|N/m^2 |SEAICE merid surface wind stress, >0 increases vIce 255 |SIatmTx | 1 | 256 |UU U1|N/m^2 |Zonal surface wind stress over Ocean+SeaIce 256 |SIatmTy | 1 | 255 |VV U1|N/m^2 |Merid surface wind stress over Ocean+SeaIce 257 |SIqnet | 1 | |SM U1|W/m^2 |Ocean surface heatflux, turb+rad, >0 decreases theta 258 |SIqsw | 1 | |SM U1|W/m^2 |Ocean surface shortwave radiat., >0 decreases theta 259 |SIatmQnt| 1 | |SM U1|W/m^2 |Net atmospheric heat flux, >0 decreases theta 260 |SItflux | 1 | |SM U1|W/m^2 |Same as TFLUX but incl seaice (>0 incr T decr H) 261 |SIaaflux| 1 | |SM U1|W/m^2 |conservative ocn<->seaice adv. heat flux adjust. 262 |SIhl | 1 | |SM U1|W/m^2 |Latent heat flux into ocean, >0 increases theta 263 |SIqneto | 1 | |SM U1|W/m^2 |Open Ocean Part of SIqnet, turb+rad, >0 decr theta 264 |SIqneti | 1 | |SM U1|W/m^2 |Ice Covered Part of SIqnet, turb+rad, >0 decr theta 265 |SIempmr | 1 | |SM U1|kg/m^2/s |Ocean surface freshwater flux, > 0 increases salt 266 |SIatmFW | 1 | |SM U1|kg/m^2/s |Net freshwater flux from atmosphere & land (+=down) 267 |SIsnPrcp| 1 | |SM U1|kg/m^2/s |Snow precip. (+=dw) over Sea-Ice (area weighted) 268 |SIfwSubl| 1 | |SM U1|kg/m^2/s |Potential sublimation freshwater flux, >0 decr. ice 269 |SIacSubl| 1 | |SM U1|kg/m^2/s |Actual sublimation freshwater flux, >0 decr. ice 270 |SIrsSubl| 1 | |SM U1|kg/m^2/s |Residual subl. freshwater flux, >0 taken from ocn 271 |SIactLHF| 1 | |SM U1|W/m^2 |Actual latent heat flux over ice 272 |SImaxLHF| 1 | |SM U1|W/m^2 |Maximum latent heat flux over ice 273 |SIaQbOCN| 1 | |SM M1|m/s |Potential HEFF rate of change by ocean ice flux 274 |SIaQbATC| 1 | |SM M1|m/s |Potential HEFF rate of change by atm flux over ice 275 |SIaQbATO| 1 | |SM M1|m/s |Potential HEFF rate of change by open ocn atm flux 276 |SIdHbOCN| 1 | |SM M1|m/s |HEFF rate of change by ocean ice flux 277 |SIdSbATC| 1 | |SM M1|m/s |HSNOW rate of change by atm flux over sea ice 278 |SIdSbOCN| 1 | |SM M1|m/s |HSNOW rate of change by ocean ice flux 279 |SIdHbATC| 1 | |SM M1|m/s |HEFF rate of change by atm flux over sea ice 280 |SIdHbATO| 1 | |SM M1|m/s |HEFF rate of change by open ocn atm flux 281 |SIdHbFLO| 1 | |SM M1|m/s |HEFF rate of change by flooding snow 282 |SIdAbATO| 1 | |SM M1|m^2/m^2/s |Potential AREA rate of change by open ocn atm flux 283 |SIdAbATC| 1 | |SM M1|m^2/m^2/s |Potential AREA rate of change by atm flux over ice 284 |SIdAbOCN| 1 | |SM M1|m^2/m^2/s |Potential AREA rate of change by ocean ice flux 285 |SIdA | 1 | |SM M1|m^2/m^2/s |AREA rate of change (net) 286 |ADVxHEFF| 1 | 287 |UU M1|m.m^2/s |Zonal Advective Flux of eff ice thickn 287 |ADVyHEFF| 1 | 286 |VV M1|m.m^2/s |Meridional Advective Flux of eff ice thickn 288 |DFxEHEFF| 1 | 289 |UU M1|m.m^2/s |Zonal Diffusive Flux of eff ice thickn 289 |DFyEHEFF| 1 | 288 |VV M1|m.m^2/s |Meridional Diffusive Flux of eff ice thickn 290 |ADVxAREA| 1 | 291 |UU M1|m^2/m^2.m^2/s |Zonal Advective Flux of fract area 291 |ADVyAREA| 1 | 290 |VV M1|m^2/m^2.m^2/s |Meridional Advective Flux of fract area 292 |DFxEAREA| 1 | 293 |UU M1|m^2/m^2.m^2/s |Zonal Diffusive Flux of fract area 293 |DFyEAREA| 1 | 292 |VV M1|m^2/m^2.m^2/s |Meridional Diffusive Flux of fract area 294 |ADVxSNOW| 1 | 295 |UU M1|m.m^2/s |Zonal Advective Flux of eff snow thickn 295 |ADVySNOW| 1 | 294 |VV M1|m.m^2/s |Meridional Advective Flux of eff snow thickn 296 |DFxESNOW| 1 | 297 |UU M1|m.m^2/s |Zonal Diffusive Flux of eff snow thickn 297 |DFyESNOW| 1 | 296 |VV M1|m.m^2/s |Meridional Diffusive Flux of eff snow thickn 298 |ADVxSSLT| 1 | 299 |UU M1|g/kg.m^2/s |Zonal Advective Flux of seaice salinity 299 |ADVySSLT| 1 | 298 |VV M1|g/kg.m^2/s |Meridional Advective Flux of seaice salinity ------------------------------------------------------------------------------------ Num |<-Name->|Levs| mate |<- code ->|<-- Units -->|<- Tile (max=80c) ------------------------------------------------------------------------------------ 300 |DFxESSLT| 1 | 301 |UU M1|g/kg.m^2/s |Zonal Diffusive Flux of seaice salinity 301 |DFyESSLT| 1 | 300 |VV M1|g/kg.m^2/s |Meridional Diffusive Flux of seaice salinity 302 |SIuheff | 1 | 303 |UU M1|m^2/s |Zonal Transport of eff ice thickn (centered) 303 |SIvheff | 1 | 302 |VV M1|m^2/s |Meridional Transport of eff ice thickn (centered) 304 |SIpress | 1 | |SM M1|N/m |SEAICE strength (with upper and lower limit) 305 |SIzeta | 1 | |SM M1|kg/s |SEAICE nonlinear bulk viscosity 306 |SIeta | 1 | |SM M1|kg/s |SEAICE nonlinear shear viscosity 307 |SIsig1 | 1 | |SM M1|no units |SEAICE normalized principle stress, component one 308 |SIsig2 | 1 | |SM M1|no units |SEAICE normalized principle stress, component two 309 |SIshear | 1 | |SM M1|1/s |SEAICE shear deformation rate 310 |SIdelta | 1 | |SM M1|1/s |SEAICE Delta deformation rate 311 |SItensil| 1 | |SM M1|N/m |SEAICE maximal tensile strength ------------------------------------------------------------------------------------ Num |<-Name->|Levs| mate |<- code ->|<-- Units -->|<- Tile (max=80c) ------------------------------------------------------------------------------------