Revelle Leg KIWI07, APFZ Process I, December 1997 - January 1998 Hydrographic data methodology

US JGOFS Antarctic Environments Southern Ocean Process Study (AESOPS)

Revelle Leg KIWI07, APFZ Process I,  December 1997 - January 1998

Documentation for: THE HYDROGRAPHIC BOTTLE DATA 

L.A. Codispoti (lou@ccpo.odu.edu)
Old Dominion University,  November, 1998

General Comments:

This "readme" file pertains to the salinity, dissolved oxygen, and nutrient
data taken from sampling bottles with the hydrographic rosette that was
equipped with 24 ~10-liter "Niskin-like" Bullister Bottles made mostly of PVC
and equipped with orange silicone o-rings during Revelle leg RR07 (1 December
1997 - 3 January 1998).  Dr. Richard T. Barber of  the Duke University Marine
Lab (rbarber@duke.edu) was the chief scientist during this leg.  This cruise
was the first  process study leg on the R/V Roger Revelle during the U.S.
JGOFS program in the Southern Ocean (AESOPS).  The Revelle legs focused on the
Polar Front region and complemented several AESOPS cruises on board the R/V
Nathaniel Palmer which focused on the Ross Sea.  Several casts with a trace
metal clean rosette equipped with 6, 30-l Go-Flo bottles were also taken
during this leg. These data are not reported here because this system was not
designed to produce hydrographic data of "WOCE quality".  These trace metal
rosette data have been submitted to the U.S. JGOFS data base as a separate
file. 

Some questionable data are not included in this report. These data are
available upon request.  

No units are given for salinity in this report because the most recent
definitions of salinity define it as a dimensionless number.  To accommodate
every preference, Winkler oxygen values are reported in ml/l, micromolar and
micromoles per kg.  The latter values can only be calculated with a knowledge
of the oxygen sample temperatures when the samples were drawn.  These "draw
temperatures" are not reported here, but can be obtained by contacting
lou@ccpo.odu.edu.  Nutrient values are reported in micromolar.  For the
laboratory conditions on this leg, the values in micromolar can be converted
to micromoles per kg,  by combining a temperature of 23 deg. C and the
salinity of the sample to compute density and then dividing the value in
micromolar by this number.

Methods:

In general, the methods employed for the bottle salinity, Winkler dissolved
oxygen, and nutrient analyses did not differ significantly from those
described in the JGOFS protocols that were distributed in 1994 (UNESCO, IOC
Manual and Guide #29).  Minor differences included the following:  1) Sea Bird
CTD systems and bottle carousels were employed (SBE-9+ underwater units,
SBE-11 deck units, SBE-32 carousels).  These units represent a newer
generation of equipment than the instruments described in the JGOFS protocols. 
2) The protocols give one a choice of adjusting nutrient methods so that
calibration curves are strictly linear, or opting for more response and taking
into account non-linearities.  We choose the latter method.  3) No corrections
were made for "carryover" between nutrient samples run on the Technicon
Autoanalyzer. Carryover effects in our nutrient analyses are generally less
than ~2% of the concentration difference between adjacent samples, and were
minimized by arranging samples in depth order, etc. in some cases.  4)
Calibration and re-calibration of volumetric ware were not exactly as
described in the JGOFS protocols, but all volumetric flasks, maxipettors, and
dosimats were  calibrated.  5) Duplicate oxygen samples were not routinely
drawn.  6) The JGOFS protocols do not describe an automated technique for
the analysis of ammonium concentrations.  We employed the Berthelot reaction
using a method somewhat similar to the method described by Whitledge et al.
(1981, Whitledge, T.E., Malloy, S.C., Patton, C.J. and Wirick, C.D. Automated
Nutrient Analyses in Seawater. Brookhaven National Laboratory Rept.  BNL
51398, 216pp.). 


Temperature:

The temperature data associated with each bottle depth were taken by the CTD
system during the bottle tripping process.  Consult the companion CTD data
report for this cruise to learn more about the CTD system.

Sampling:

The samples in this report were taken from ~10 liter Bullister bottles. 
Because there is little or no lag time between triggering a bottle and bottle
closure with the new SeaBird rosette systems, our sampling protocols request
that bottles be held at the sampling depth for at least 30 seconds before
tripping.

NOTE THAT THE MID-POINT OF THE SAMPLING BOTTLES WAS ~1 METER ABOVE THE CTD
SENSORS.  THE DATA HAVE NOT BEEN CORRECTED FOR THIS OFFSET. 

Salinity:

Salinities were determined with Guildline Autosal salinometers.  New vials of
standard sea-water were used to standardize before and at the end of every
run.  Agreement between bottle salinities and the recently calibrated sensors
on the Sea Bird CTD systems was usually better than 0.01 before post-cruise
data processing which employs the bottle salinities to correct the CTD
salinities.  More information on the quality of the salinity data are given in
the companion CTD report.

Dissolved oxygen:

The Winkler dissolved oxygen apparatus was built and supplied by the Scripps
Institution of Oceanography's (SIO) Ocean Data Facility (ODF) group.  This
system is computer controlled and detects the end-point photometrically.
Temperatures of the thiosulfate and standard solutions are automatically
monitored by this system.  

Nutrients:

Note that the terminology used to describe nutrients has become somewhat loose
over the years and that silicate = silicic acid, dissolved silicon or reactive
silicate, and phosphate = reactive phosphorus.  Nutrient analyses were
performed on a 5-channel Technicon II AA system that was modified and provided
by Doug Masten (doug@odf.ucsd.edu) of  the ODF group at the Scripps
Institution of Oceanography.

Queries:

Questions about these data may be addressed to:

Dr. L. A. Codispoti
CCPO
Old Dominion University
Norfolk, VA 23529
lou@ccpo.odu.edu