3.1 Model History Files

History files contain model data values written at specified times during a run. The user can specify the frequency at which the data is written. Options are also available to record averaged, instantaneous, maximum, or minimum values on a field-by-field basis. If the user wishes to see a field written at additional time frequencies (e.g. daily, hourly), additional history files must be declared.

History files may be visualized using various commercial or freely available tools. Examples include the "CCSM Component Model Processing Suite (CMPS)", the NCAR Graphics package, FERRET, ncview, MATLAB, AVS, IDL, and Yorick. For a list of software tools for interacting with NetCDF files, view the UNIDATA NetCDF web-site:
http://my.unidata.ucar.edu/content/software/netcdf/software.html.

Aside from the default history file series the user may specify up to five additional history file series for a total of up to six history file series. The frequency at which these history file series are written as well as the contents and averaging options are specified using the same namelist variables described above for modifying the first history file series. tab:mfl lists the fields that can be output on any of the six history files as well as which fields are output by default on the first file series.

3.1.1 Master Field List

Table 3.1 contains a list of fields, referred to as the "Master Field List", that can be written to history files.

The first column lists the names of the output variables.

The second column shows the mathematical symbol associated with the history field, as given in Collins et al. [2004].

The third column provides a brief description of the field.

In the fourth column shows the number of levels for the field. A "1" indicates a single-level field and an "N" indicates a multilevel field (on plev vertical levels).

The fifth column shows the default averaging flag. The flags available are: Instantaneous (I), Average (A), Maximum (X), and Minimum (M).

The sixth column in the table shows the physical units associated with each field.

The last column indicates whether the field will automatically be included on the first history file series. Fields not on by default may be included via the namelist variable FINCL1. Conversely, any default fields may be removed using namelist variable FEXCL1.

The fields are presented in alphabetical order.

Table 3.1: Master Field List

Field Name	Symbol	Field Description	NL	AF	Units	Default
AERASM_v		Total Aerosol Asymmetry Parameter in visible	1	I	None
AERFWD_v		Total Aerosol Forward Scattering in visible	1	I	None
AEROD_v		Total Aerosol Optical Depth in visible	1	I	None
AERSSA_v		Total Aerosol Single Scattering Albedo in visible	1	I	None
ALDIF		albedo: longwave, diffuse	1	A	1
ALDIR		albedo: longwave, direct	1	A	1
ASDIF		albedo: shortwave, diffuse	1	A	1
ASDIR		albedo: shortwave, direct	1	A	1
BGOD_v		Background Aerosol Optical Depth in visible	1	I	None
CAROD_v		Carbon Optical Depth in visible	1	I	None
CGH		Counter-gradient term for heat in PBL	27	A	K/m
CGQ		Counter-gradient term for moisture in PBL	27	A	1/m
CGS		Counter-gradient coeff on surface kinematic fluxes	27	A	s/m2
CLDFRQ		Frequency of occurance of clouds (CLOUD > 0.01)	26	A	fraction
CLDHGH		Vertically-integrated high cloud	1	A	fraction	yes
CLDICE		Grid box averaged ice condensate amount	26	Ak	g/kg	yes
CLDLIQ		Grid box averaged liquid condensate amount	26	A	kg/kg	yes
CLDLOW		Vertically-integrated low cloud	1	A	fraction	yes
CLDMED		Vertically-integrated mid-level cloud	1	A	fraction	yes
CLDST		Stratus cloud fraction	26	A	fraction
CLDTOT		Vertically-integrated total cloud	1	A	fraction	yes
CLOUD		Cloud fraction	26	A	fraction	yes
CME		Rate of cond-evap within the cloud	26	A	kg/kg/s
CMFDQ		Q tendency - Hack convection	26	A	kg/kg/s	yes
CMFDQR		Q tendency - shallow convection rainout	26	A	kg/kg/s	yes
CMFDT		T tendency - Hack convection	26	A	K/s	yes
CMFLQ		Moist convection total water flux	27	A	W/m2
CMFMC		Moist convection mass flux	27	A	kg/m2/s	yes
CMFSL		Moist convection liquid water static energy flux	27	A	W/m2
CNVCLD		Vertically integrated convective cloud amount	1	A	fraction
CONCLD		Convective cloud cover	26	A	fraction	yes
DCCLDICE		CLDICE tendency due to moist processes	26	A	kg/kg/s
DCCLDLIQ		CLDLIQ tendency due to moist processes	26	A	kg/kg/s
DCQ		Q tendency due to moist processes	26	A	kg/kg/s	yes
DISED		Cloud ice tendency from sedimentation	26	A	kg/kg/s
DLSED		Cloud liquid tendency from sedimentation	26	A	kg/kg/s
DQP		Specific humidity tendency due to precipitation	26	A	kg/kg/s
DQSED		Water vapor tendency from cloud sedimentation	26	A	kg/kg/s
DTCOND		T tendency - moist processes	26	A	K/s	yes
DTH		T horizontal diffusive heating	26	A	K/s	yes
DTV		T vertical diffusion	26	A	K/s	yes
DTVKE		dT/dt vertical diffusion KE dissipation	26	A	K/s
DUH		U horizontal diffusive heating	26	A	K/s
DUSTOD_v		Dust Optical Depth in visible	1	I	None
DUV		U vertical diffusion	26	A	m/s2
DVH		V horizontal diffusive heating	26	A	K/s
DVV		V vertical diffusion	26	A	m/s2
EFFCLD		Effective cloud fraction	26	A	fraction
EMIS		cloud emissivity	26	A	1
ENGYCORR		Energy correction for over-all conservation	26	A	W/m2
ETADOT		Vertical (eta) velocity	27	A	1/s
EVAPPCT		Percentage of Zhang-McFarlane precipitation going into evaporation	1	A	percent
EVAPPREC		Rate of evaporation of falling precip	26	A	kg/kg/s
EVAPSNOW		Rate of evaporation of falling snow	26	A	kg/kg/s
FICE		Fractional ice content within cloud	26	A	fraction	yes
FLN200		Net longwave flux at 200 mb	1	A	W/m2
FLN200C		Clearsky net longwave flux at 200 mb	1	A	W/m2
FLNS		Net longwave flux at surface	1	A	W/m2	yes
FLNSC		Clearsky net longwave flux at surface	1	A	W/m2	yes
FLNSICE		FLNS over sea ice	1	A	W/m2
FLNSLND		FLNS over land	1	A	W/m2
FLNSOCN		FLNS over open ocn	1	A	W/m2
FLNSOI		FLNS over open ocn and ice	1	A	W/m2	yes
FLNT		Net longwave flux at top of model	1	A	W/m2	yes
FLNTC		Clearsky net longwave flux at top of model	1	A	W/m2	yes
FLUT		Upwelling longwave flux at top of model	1	A	W/m2	yes
FLUTC		Clearsky upwelling longwave flux at top of model	1	A	W/m2	yes
FRACW		Relative importance of rain accreting liquid	26	A	fraction
frc_day		Portion of time column is lit	1	I	None
FSACI		Relative importance of snow accreting ice	26	A	fraction
FSACW		Relative importance of snow accreting liquid	26	A	fraction
FSAUT		Relative importance of ice autoconversion	26	A	fraction
FSDS		Downwelling solar flux at surface	1	A	W/m2	yes
FSDSC		Clearsky downwelling solar flux at surface	1	A	W/m2	yes
FSN200		Net shortwave flux at 200 mb	1	A	W/m2
FSN200C		Clearsky net shortwave flux at 200 mb	1	A	W/m2
FSNIRTOA		Net near-infrared flux (Nimbus-7 WFOV) at top of atmosphere	1	A	W/m2
FSNRTOAC		Clearsky net near-infrared flux (Nimbus-7 WFOV) at top of atmosphere	1	A	W/m2
FSNRTOAS		Net near-infrared flux (>= 0.7 microns) at top of atmosphere	1	A	W/m2
FSNS		Net solar flux at surface	1	A	W/m2	yes
FSNSC		Clearsky net solar flux at surface	1	A	W/m2	yes
FSNSICE		FSNS over sea ice	1	A	W/m2
FSNSLND		FSNS over land	1	A	W/m2
FSNSOCN		FSNS over open ocn	1	A	W/m2
FSNSOI		FSNS over open ocn and ice	1	A	W/m2	yes
FSNT		Net solar flux at top of model	1	A	W/m2	yes
FSNTC		Clearsky net solar flux at top of model	1	A	W/m2	yes
FSNTOA		Net solar flux at top of atmosphere	1	A	W/m2	yes
FSNTOAC		Clearsky net solar flux at top of atmosphere	1	A	W/m2	yes
FU		Zonal wind forcing term	26	I	m/s
FV		Meridional wind forcing term	26	I	m/s
FWAUT		Relative importance of liquid autoconversion	26	A	fraction
GCLDLWP		Grid-box cloud water path	26	A	gram/m2	yes
HEVAP		Heating from evaporation of falling precip	26	A	W/kg
HKEIHEAT		Heating by ice and evaporation in HK convection	26	A	W/kg
HKFLXPRC		Flux of precipitation from HK convection	27	A	kg/m2/s
HKFLXSNW		Flux of snow from HK convection	27	A	kg/m2/s
HKNTPRPD		Net precipitation production from HK convection	26	A	kg/kg/s
HKNTSNPD		Net snow production from HK convection	26	A	kg/kg/s
HMELT		Heating from snow melt	26	A	W/kg
HPROGCLD		Heating from prognostic clouds	26	A	W/kg
HR		Heating rate needed for d(theta)/dt computation	26	A	K/s
HREPART		Heating from cloud ice/liquid repartitioning	26	A	W/kg
HSED		Heating from cloud sediment evaporation	26	A	W/kg
ICEFRAC		Fraction of sfc area covered by sea-ice	1	A	fraction	yes
ICIMR		Prognostic in-cloud ice mixing ratio	26	A	kg/kg
ICLDIWP		In-cloud ice water path	26	A	gram/m2	yes
ICLDLWP		In-cloud cloud water path (liquid and ice)	26	A	gram/m2	yes
ICWMR		Prognostic in-cloud water mixing ratio	26	A	kg/kg
KVH		Vertical diffusion diffusivities (heat/moisture)	27	A	m2/s
KVM		Vertical diffusion diffusivities (momentum)	27	A	m2/s
LANDFRAC		Fraction of sfc area covered by land	1	A	fraction	yes
LANDMCOS		Land ocean transition mask: ocean (0), continent (1), transition (0-1)	1	I	unitless
LHFLX		Surface latent heat flux	1	A	W/m2	yes
LHFLXICE		LHFLX over sea ice	1	A	W/m2
LHFLXLND		LHFLX over land	1	A	W/m2
LHFLXOCN		LHFLX over open ocn	1	A	W/m2
LHFLXOI		LHFLX over open ocn and ice	1	A	W/m2	yes
LPSTEN		Surface pressure tendency	1	A	Pa/s
LWC		Liquid Water Content	26	A	kg/m3
LWCF		Longwave cloud forcing	1	A	W/m2	yes
LWSH		Liquid water scale height	1	A	m
MBCPHI_V		Mass of BCPHI in and below layer	26	I	Kg/m2
MBCPHO_V		Mass of BCPHO in and below layer	26	I	Kg/m2
MBG_V		Mass of Background Aerosol in and below layer	26	I	Kg/m2
MDUST1_V		Mass of Dust bin 1 in and below layer	26	I	Kg/m2
MDUST2_V		Mass of Dust bin 2 in and below layer	26	I	Kg/m2
MDUST3_V		Mass of Dust bin 3 in and below layer	26	I	Kg/m2
MDUST4_V		Mass of Dust bin 4 in and below layer	26	I	Kg/m2
MOCPHI_V		Mass of OCPHI in and below layer	26	I	Kg/m2
MOCPHO_V		Mass of OCPHO in and below layer	26	I	Kg/m2
MQ		Water vapor mass in layer	26	A	kg/m2
MSO4		Mass concentration of SO4	26	A	gram/cm3
MSSLT_V		Mass of Sea Salt in and below layer	26	I	Kg/m2
MSUL_V		Mass of Sulfate in and below layer	26	I	Kg/m2
MVOLC		Mass of Volcanic Aerosol in layer	26	I	Kg/m2
NSTEP		Model timestep	1	A	timestep
O3VMR		Ozone volume mixing ratio	26	A	m3/m3
OCNFRAC		Fraction of sfc area covered by ocean	1	A	fraction	yes
OMEGA		Vertical velocity (pressure)	26	A	Pa/s	yes
OMEGA500		Vertical velocity at 500 mbar pressure surface	1	A	Pa/s
OMEGA850		Vertical velocity at 850 mbar pressure surface	1	A	Pa/s
OMEGAT		Vertical heat flux	26	A	K Pa/s	yes
OMEGAU		Vertical flux of zonal momentum	26	A	K Pa/s
PBLH		PBL height	1	A	m	yes
PBOT		Lowest model level pressure	1	A	Pa
PCSNOW		Snow fall from prognostic clouds	1	A	m/s
PDELDRY		Dry pressure difference between levels	26	A	Pa	yes
PHIS		Surface geopotential	1	I	m2/s2	yes
PRECC		Convective precipitation rate	1	A	m/s	yes
PRECCFRQ		Convective precipitation frequency (fraction of time where rate is > 0.10mm/hr)	1	Af	raction
PRECCINT		Convective precipitation rate (less than 0.10mm/hr is set to zero - to get intensity divide by PRECCFRQ)	1	A	mm/hr
PRECCav		Average large-scale precipitation	1	A	m/s
PRECL		Large-scale (stable) precipitation rate	1	A	m/s	yes
PRECLFRQ		Large-scale (stable) precipitation frequency (fraction of time where rate is > 0.05mm/hr)	1	A	fraction
PRECLINT		Large-scale (stable) precipitation rate (less than 0.05mm/hr is set to zero - to get intensity divide by PRECLFRQ)	1	A	mm/hr
PRECLav		Average convective precipitation	1	A	m/s
PRECSC		Convective snow rate (water equivalent)	1	A	m/s	yes
PRECSED		Precipitation from cloud sedimentation	1	A	m/s
PRECSH		Shallow Convection precipitation rate	1	A	m/s	yes
PRECSL		Large-scale (stable) snow rate (water equivalent)	1	A	m/s	yes
PRECT		Total (convective and large-scale) precipitation rate	1	A	m/s
PRECTMX		Maximum (convective and large-scale) precipitation rate	1	Xm	/s
PRODPREC		Rate of conversion of condensate to precip	26	A	kg/kg/s
PS		Surface pressure	1	A	Pa	yes
PSDRY		Surface pressure	1	A	Pa	yes
PSL		Sea level pressure	1	A	Pa	yes
PS_match		Surface Pressure from aerosol climatology	1	I	N/m2
Q		Specific humidity	26	A	kg/kg	yes
Q200		Specific Humidity at 700 mbar pressure surface	1	A	kg/kg
Q850		Specific Humidity at 850 mbar pressure surface	1	A	kg/kg
QBOT		Lowest model level water vapor mixing ratio	1	A	kg/kg
QC		Q tendency - shallow convection LW export	26	A	kg/kg/s	yes
QFLX		Surface water flux	1	A	kg/m2/s	yes
QPERT		Perturbation specific humidity (eddies in PBL)	1	A	kg/kg
QRL		Longwave heating rate	26	A	K/s	yes
QRS		Solar heating rate	26	A	K/s	yes
RAINSED		Rain from cloud liquid sedimentation	1	A	m/s
REI		effective ice particle radius	26	A	micron
REL		effective liquid drop radius	26	A	micron
RELHUM		Relative humidity	26	A	percent	yes
SETLWP		Prescribed liquid water path	26	A	gram/m2
SFCLDICE		CLDICE surface flux	1	A	kg/m2/s	yes
SFCLDLIQ		CLDLIQ surface flux	1	A	kg/m2/s	yes
SFQ		Q surface flux	1	A	kg/m2/s	yes
SGH		Standard deviation of orography	1	I	m
SHFLX		Surface sensible heat flux	1	A	W/m2	yes
SHFLXICE		SHFLX over sea ice	1	A	W/m2
SHFLXLND		SHFLX over land	1	A	W/m2
SHFLXOCN		SHFLX over open ocn	1	A	W/m2
SHFLXOI		SHFLX over open ocn and ice	1	A	W/m2	yes
SICTHK		Sea ice thickness	1	A	m
SNOWHICE		Water equivalent snow depth	1	A	m	yes
SNOWHLND		Water equivalent snow depth	1	A	m	yes
SNOWSED		Snow from cloud ice sedimentation	1	A	m/s
SOLIN		Solar insolation	1	A	W/m2	yes
SOLL		Solar downward near infrared direct to surface	1	A	W/m2
SOLLD		Solar downward near infrared diffuse to surface	1	A	W/m2
SOLS		Solar downward visible direct to surface	1	A	W/m2
SOLSD		Solar downward visible diffuse to surface	1	A	W/m2
SRFRAD		Net radiative flux at surface	1	A	W/m2	yes
SSLTOD_v		Sea Salt Optical Depth in visible	1	I	None
SST		sea surface temperature	1	A	K
SULFANT		Anthropogenic sulfate mass mixing ratio	26	A	kg/kg
SULFBIO		Biogenic sulfate mass mixing ratio	26	A	kg/kg
SULFMMR		Sulfate mass mixing ratio	26	A	kg/kg
SULOD_v		Sulfate Optical Depth in visible	1	I	None
SWCF		Shortwave cloud forcing	1	A	W/m2	yes
T		Temperature	26	A	K	yes
T300		Temperature at 300 mbar pressure surface	1	A	K
T850		Temperature at 850 mbar pressure surface	1	A	K
TAUGWX		Zonal gravity wave surface stress	1	A	N/m2
TAUGWY		Meridional gravity wave surface stress	1	A	N/m2
TAUTMSX		Zonal turbulent mountain surface stress	1	A	N/m2
TAUTMSY		Meridional turbulent mountain surface stress	1	A	N/m2
TAUVIS		Total column aerosol extinction, vis band [aerosol optical depth]	1	A	unitless
TAUX		Zonal surface stress	1	A	N/m2	yes
TAUY		Meridional surface stress	1	A	N/m2	yes
TBOT		Lowest model level temperature	1	A	K
TEFIX		Total energy after fixer	1	A	W/m2
TEINP		Total energy of physics input	1	A	W/m2
TEOUT		Total energy of physics output	1	A	W/m2
TGCLDCWP		Total grid-box cloud water path (liquid and ice)	1	A	gram/m2
TGCLDIWP		Total grid-box cloud ice water path	1	A	gram/m2	yes
TGCLDLWP		Total grid-box cloud liquid water path	1	A	gram/m2	yes
TMQ		Total (vertically integrated) precipitatable water	1	A	kg/m2	yes
TPERT		Perturbation temperature (eddies in PBL)	1	A	K
TREFHT		Reference height temperature	1	A	K	yes
TREFHTMN		Minimum reference height temperature over output period	1	MK
TREFHTMX		Maximum reference height temperature over output period	1	XK
TREFMNAV		Average of TREFHT daily minimum	1	A	K
TREFMXAV		Average of TREFHT daily maximum	1	A	K
TS		Surface temperature (radiative)	1	A	K	yes
TS1		TS1 subsoil temperature	1	A	K
TS2		TS2 subsoil temperature	1	A	K
TS3		TS3 subsoil temperature	1	A	K
TS4		TS4 subsoil temperature	1	A	K
TSICE		Ice temperature	1	A	K
TSMN		Minimum surface temperature over output period	1	M	K	yes
TSMX		Maximum surface temperature over output period	1	X	K	yes
TT		Eddy temperature variance	26	A	K2
TTEND		T tendency	26	A	K/s
TTGWORO		T tendency - orographic gravity wave drag	26	A	K/s
U		Zonal wind	26	A	m/s	yes
U200		Zonal wind at 200 mbar pressure surface	1	A	m/s
U850		Zonal wind at 850 mbar pressure surface	1	A	m/s
UBOT		Lowest model level zonal wind	1	A	m/s
US		Zonal wind, staggered	26	A	m/s
USTAR		Surface friction velocity	1	A	m/s
UTEND		U tendency	26	A	m/s2
UTGWORO		U tendency - orographic gravity wave drag	26	A	m/s2
UU		Zonal velocity squared	26	A	m2/s2	yes
V		Meridional wind	26	A	m/s	yes
V200		Meridional wind at 200 mbar pressure surface	1	A	m/s
V850		Meridional wind at 850 mbar pressure surface	1	A	m/s
VBOT		Lowest model level meridional wind	1	A	m/s
VD01		Vertical diffusion of Q	26	A	kg/kg/s	yes
VDCLDICE		Vertical diffusion of CLDICE	26	A	kg/kg/s
VDCLDLIQ		Vertical diffusion of CLDLIQ	26	A	kg/kg/s
VOLCOD_v		Volcanic Aerosol Optical Depth in visible	1	I	None
VQ		Meridional water transport	26	A	m/skg/kg	yes
VS		Meridional wind, staggered	26	A	m/s
VT		Meridional heat transport	26	A	K m/s	yes
VTEND		V tendency	26	A	m/s2
VTGWORO		V tendency - orographic gravity wave drag	26	A	m/s2
VU		Meridional flux of zonal momentum	26	A	m2/s2	yes
VV		Meridional velocity squared	26	A	m2/s2	yes
VZ		Meridional transport of geopotential energy	26	A	m2/s
WLWC		Weighted Liquid Water Content, prognostic (by CLDFRQ)	26	A	kg/m3
WREL		Weighted effective radius (by CLDFRQ)	26	A	um
WSPEED		Horizontal total wind speed	26	X	m/s
Z050		Geopotential Z at 50 mbar pressure surface	1	A	m
Z3		Geopotential Height (above sea level)	26	A	m	yes
Z300		Geopotential Z at 300 mbar pressure surface	1	A	m
Z500		Geopotential Z at 500 mbar pressure surface	1	A	m
Z700		Geopotential Z at 700 mbar pressure surface	1	A	m
ZBOT		Lowest model level height	1	A	m
ZMDLF		Detrained liquid water from ZM convection	26	A	kg/kg/s
ZMDQ		Q tendency - Zhang-McFarlane moist convection	26	A	kg/kg/s
ZMDT		T tendency - Zhang-McFarlane moist convection	26	A	K/s
ZMEIHEAT		Heating by ice and evaporation in ZM convection	26	A	W/kg
ZMFLXPRC		Flux of precipitation from ZM convection	27	A	kg/m2/s
ZMFLXSNW		Flux of snow from ZM convection	27	A	kg/m2/s
ZMNTPRPD		Net precipitation production from ZM convection	26	A	kg/kg/s
ZMNTSNPD		Net snow production from ZM convection	26	A	kg/kg/s
ZZ		Eddy height variance	26	A	m2

3.1.2 History Files 2 through 6

Up to six different types of history files may be written out by the model during a model run. The capability to write additional history files provides the user with the flexibility to vary the frequency at which various history data are written. Additional files may contain the same or different fields as compared with the first history file. These fields may be written on different timesteps, and have different averaging periods. Furthermore, each file may contain a different number of time samples.

3.1.3 Changing the characteristics of history files

There are several ways that namelist options can modify the characteristics of the output fields on history tapes. Output fields can be added or deleted from a file, the averaging flag can be changed and the output frequency can be varied. In addition, the number of time-samples on a file and the precision of the output data (double or single NetCDF) can be changed. To add additional fields to the first history file, the user should use the namelist variable FINCL1. FEXCL1 can be used to delete fields that are on the default list of fields on the first history file series. The averaging flag may also be specified with the FINCL1 option and determines how the data is averaged over the output frequency. Values recorded for fields on a history file can be represented in one of four different ways. Data may be time averaged since the last write to the history file, instantaneous, or appear as a point-by-point maximum or minimum over the time interval. The representation may be specified in the namelist by including a colon followed by the single character flag for each averaging type after the field name. The characters are as follows: 'A' means averaged over the interval, 'I' for instantaneous, 'M' for point-by-point minimum, and 'X' for point-by-point maximum. An example of this specification would be:

FINCL1 = 'T:I'

This specifies that temperature is to be recorded as instantaneous values on the first history file.

Other namelist variables that modify history file behavior are NHTFRQ(6) (frequency of history file writes), MFILT(6) (number of time samples per history file), and NDENS(6) (packing density). Please see Table B.1 for more information.

3.1.4 Naming the History Files

History volumes will be named according to the history filename specifier. The history filename name specifier may be specified using the namelist variable HFILENAME_SPEC (6), but by default the first history file series will contain monthly output and the filenames will be of the form

caseid.cam2.h0.yyyy-mm.nc

where caseid, yyyy, and mm correspond to the case-name, current year, and current month respectively. For example, if caseid="cambld", and current date is September, 1989 the filename becomes

cambld.cam2.h0.1989-09.nc

Non-monthly file-series are named with a full date expression as follows:

caseid.cam2.h#.yyyy-mm-dd-sssss.nc

Here, # is the file series number minus one, dd is the current day, and sssss is the number of seconds into the current day. For example, for the second file-series and a current date of September, 1, 1989, 0Z the filename becomes:

cambld.cam2.h1.1989-09-01-00000.nc