AnSlope Cruise #1 NATHANIEL B. PALMER 0302

McMurdo, Antarctica to Port Lyttelton, New Zealand; 25 February to 9 April 2003

Cruise Report

 

The Top

 

The Bottom

And in-between

 

I Introduction & Overview [A.Gordon, Chief Scientist]

 

[A] AnSlope, the Program: 

 

AnSlope's primary goal is to identify the principal physical processes that govern the transfer of shelf-modified dense water into intermediate and deep layers of the adjacent deep ocean.  At the same time, we seek to understand the compensatory poleward flow of waters from the oceanic regime. We identify the upper continental slope as the critical gateway for the exchange of shelf and deep ocean waters. Four specific objectives: [A] Determine the ASF mean structure and the principal scales of variability (spatial from ~1 km to ~100 km, and temporal from tidal to seasonal), and estimate the role of the Front on cross-slope exchanges and mixing of adjacent water masses; [B] Determine the influence of slope topography (canyons, proximity to a continental boundary, isobath divergence/convergence) on frontal location and outflow of dense Shelf Water; [C] Establish the role of frontal instabilities, benthic boundary layer transports, tides and other oscillatory processes on cross-slope advection and fluxes; and [D] Assess the effect of diapycnal mixing (shear-driven and double-diffusive), lateral mixing identified through intrusions, and nonlinearities in the equation of  state (thermobaricity and cabbeling) on the rate of descent and fate of outflowing, near-freezing Shelf Water.

 

AnSlope core elements are: moorings; CTD-O2/ADCP and CTD-mounted Microstructure Profiling System (CMiPS); CFC, oxy-18, tritium/helium tracers; and basic tidal modeling. The cruise activities of these elements are reported below:  

• CTD/LADCP/Tracer by Bruce Huber;

• Moorings by Alejandro Orsi;

• Microstructure by Laurence Padman. 

 

International Collaboration: The Italian CLIMA [Climate  Long–term  Interaction of the  Mass  balance of  Antarctica ] program in the Ross Sea provides a valuable international enhancement for the AnSlope observational component. Andrea Bergamasco, who joined the NBP0302 science team from the R/V Italica (CLIMA's ship) brought with him the Italica CTD data. These data provide a view of the western Ross Sea stratification conditions for January-February 2003, complementing the February-March 2003 data set of NBP 0302.

 

The German BRIOS-2 coupled ice-ocean GCM program is complementary to the US process-oriented modeling studies, and provides a test-bed for AnSlope-generated parameterizations of cross-front exchange.

 

The AnSlope field phase consists of three cruises within 12 to 14 months, with moorings in place throughout the period:

 

AnSlope 1:  February 25 to April 11 2003:  deploy the mooring array; thermohaline, oxygen and tracer [CFC, oxy-18, tritium/Helium] stratification, circulation and microstructure at beginning of mooring time series. In addition, water samples for nutrient analyses were collected at 60 selected stations to complement the measurements carried out in the Ross Sea in January and February 2003 by the Italian CLIMA project.

 

AnSlope 2: December 3, 2003 to January 16 2004: thermohaline, oxygen and tracer [CFC, oxy-18, tritium/Helium] stratification, circulation and microstructure during mooring time series;

 

AnSlope 3: February 29 to April 11, 2004: thermohaline and oxygen stratification, circulation at time of mooring recovery;

 

[B] AnSlope-1 Personnel:

 

Science Staff

1. Assmann, Karen                   AIW [BRIO-2]

2. MacKay, Chris                     ESR [Microstrucure]

3. Padman, Laurence                ESR [Microstrucure]

4. Zambianchi, Enrico               Universita Parthenope [CLIMA]

5. Bergamasco, Andrea            National Research Council [ISMAR; CLIMA]

6. Boda, Ken                           LDEO [CTD/LADCP]

7. Curchister, Enrique               LDEO [CTD/LADCP]

8. Dachille, Anthony                 LDEO [Tracer Chemistry]

9. Gordon, Arnold                    LDEO[Chief Scientist]

10. Huber, Bruce                      LDEO [CTD/LADCP]

11. Mathieu, Guy                      LDEO [Tracer Chemistry]

12. Mathieu, Sally                     LDEO [Tracer Chemistry]

13. Mele, Philip                        LDEO [CTD/LADCP]

14. Stanton, Basil                     LDEO [CTD/LADCP]

15. Stone, Erin                         LDEO [CTD/LADCP]

16. Brooksforce, Kathryn         OSU [Moorings]

17. Simpkins, John                   OSU [Moorings]

18. Bratcher, Amy                    TAMU [Moorings]

19. Orsi, Alejandro                   TAMU [Moorings]

 

AIW = Alfred Wegener Institute for Polar & Marine Research

CLIMA = Climate  Long–term  Interaction of the  Mass  balance of  Antarctica

ISMAR = Institute for Marine Science

LDEO = Lamont-Doherty Earth Observatory

ESR = Earth & Space Research

OSU = Oregon State University

TAMU = Texas A&M University

 

Raytheon Polar Services Company Staff:

1. Blackman, Sheldon               Electronics Technician

2. Coward, Annie                     Marine Technician

3. Felix, Bruce                          Electronics Technician

4. Gavahan, Kathleen               Information Technology

5. Huckins, Paul                       Information Technology

6. Huggins, Jen             Marine Technician

7. Klostermayer, Bryan USCG observer

8. Liben, Robbie                       Information Technology

9. McGuier, Chris                     Marine Technician

10. Newyear, Karl                   Marine Projects Coordinator

11. Tarrant, Steve                     Marine Technician

12. Tudor,  Laura                     Marine Science Technician

 

[C] What was Done:

 

The Chief Scientist's weekly SitReps with those of the Karl Newyear document the activities during the AnSlope-1 cruise. The sea ice cover was far more extensive than expected. However the mooring and CTD station activities were not hindered. Only the planned XBT survey was not done because of ice conditions.

 

The Track and Station array:

 

Figure I-1 Track, CTD stations [tracer activities noted: red symbol Tritium/Helium & Oxygen -18; + CFC], and moorings (see figure 1c; yellow is Central E-1 and B-1, which were recovered and redeployed as Central E-2 and B-2, shown by the blue symbol; the moorings which were not rotated during the cruise are shown in green). Table II- 1[Huber] lists the CTD stations, 206 in total and Table III-1 [Orsi] lists the mooring positions and composition. 

 

 

I-1a The full Station Array

 

I-1b the primary AnSlope area

 

I-1c Close up of mooring region, SW corner of AnSlope Coverage

 

 

I-1d Multibeam base of Close up of the SW corner of AnSlope Coverage

 

Research "Blocks": AnSlope-1 cruise activities may be segmented into research blocks, A to H (Figure I-2). A 'Station'  consists of CTD/LADCP; microstructure; water samples; a 'Section' is a sequence of stations, generally with spacing of 5 to 15 nm.

 

Figure I-2 Map of Research Blocks

[A] Enroute from McMurdo [stations 1- 18] :  The first station was in Terra Nova Bay, near the CLIMA current meter mooring L 74° 44.57 S; 164° 08.42 E. This was followed with a few stations along the west wall of mega-iceberg C-19 and a section across Drygalski Trough. These stations define the February 2003 characteristics of the dense shelf water within Drygalski, which is the prime source of slope plumes expected in the mooring area. A section [stations at 10 nm] was obtained along the trough axis, passing CLIMA mooring G, 73° 18.00 S; 171° 36.00 E, extending across the slope into the deep ocean, providing our first glimpse of the shelf/slope front and slope plume characteristics.  The front over the continental slope separates the relatively warm deep waters from the cold dense water over slope floor. Above 500 m the front conforms to the shelf-slope exchange processes.

 

[B] Moorings deployment [stations 19- 42]: Deployment of the 12 AnSlope moorings (including the pressure sensor near East-A) with regional CTD / LADCP stations. Tidal currents are a very noticeable part of the flow field, particularly over the shelf. Within the mooring area, over the slope and deeper ocean we find low salinity bottom water spreading westward across the mouth of the Drygalski trough, eventually over-riding saltier slope water derived from Drygalski. While there is general agreement of the stratification observed during AnSlope-1 with that found by Italica [January-February 2003] there is some variability: the Italica data reveals slightly greater extent of the saline slope water.

 

[C] Western boundary [stations 43-71]: Five closely spaced sections [5 nm] were obtained across the outer shelf to deep ocean within the western 'bend' and western boundary formed by the slope isobaths. These sections show the behavior of the shelf-slope front as the continental margins executes its abrupt turn. Above 500 m the modified warm deep water seems to just keep going west, spreading at least to with 15 nm of the shore. Pressed up against the slope and deeper adjacent ocean is strong northward flow of saline bottom water. Water mass characteristics and the bottom tracked LADCP data indicate that there are significant downslope components of salty shelf water from Drygalski, prompting use of the descriptive word 'Plume'. The northern cross slope section [stations 67-72] in this grouping defines the characteristics of the Ross Sea saline bottom water as they exit their formation site.

 

[D] Northern [D1] and Eastern [D2] boundary sections [stations 72-97]: The deep water side of the AnSlope survey region is enclosed by a northern (72-86; nominally along 72°S) and an eastern (87-97; along 175°E) boundary sections. These sections define the open ocean boundary condition for the AnSlope area. The northern section crosses the Iselin Bank near 178°E. The northward protrusion of Iselin Bank forms a major perturbation to the otherwise SE-NW trending Ross Sea slope. The eastern slope of the Bank is characterized by northward flowing water derived from Pennell Trough shelf water. The top of the Bank is covered with outer shelf waters derived from Pennell region. The front for the most part follows the contours of Iselin Bank, but the slope water along the western flank is not as cold as observed to the east, indicating that the Pennell formed bottom water passes into the southeast Pacific Basin rather then curl their way to the western Ross margin.

 

[E] Pennell Trough [stations 98-110]:  Pennell Trough holds the potential source water for local slope plumes, both ice shelf water and high salinity shelf water. The latter being similar to that within Drygalski, but here at its eastern extend it forms a thinner benthic layer. Within Pennell Trough there are two CLIMA moorings:  H-1 75°57.461'S; 177°38.709'W  632-m, and H-2 75°09.936'S; 176°14.603'W   738-m. We took a station at H-2, but ice was too heavy to spare the fuel to reach H-1. At the shelf break, at H-2, we found vigorous mixing of the shelf and modified warm deep waters, with very high offshore speeds, feeding the northward flowing slope waters observed along the eastern slope of Iselin Bank.

 

[F] Continental slope crossings [stations 111-144]: From Pennell Trough to the mooring area we crisscrossed the continental slope and associated front 8 times (including the two crossings at Pennell and the 175W section) with a station spacing of about 5 nm. These sections examine the connectivity between the Pennell Trough frontal and plume characteristics with those at the western mooring area. The southern root of Iselin Bank was transversed near 73.5S, which with the northern boundary section define the extent of the Bank's disturbance to the margin stratification/circulation. There appears to be both low and high salinity benthic water derived from Joides Basin along the downstream slope. 

 

[G] Recovery/redeployment of two moorings [stations 145-186]: Central E-1 and Central B-1 moorings were recovered and re-deployed as Central E-2 and B-2. E-1 and B-1 were not quite in the desired placement, and E-1 was too shallow exposing it to iceberg impact. The three week mooring records provide a tantalizing hint of things to come when we recover the full year's data. Sections were obtained at close spacing (<5nm at the mooring sites) along the three mooring sections to enable current meter referenced geostrophic calculations. The sections along the eastern and western mooring lines were extended off shore to deeper waters. Repeated lowering (yo-yo station) of the CTD for a period of 25 hours were performed at the ADCP mooring site, revealing very vigorous, time varying conditions.

 

[H] Balleny Trough [stations 187-206]: The bottom water formed along the western margin of the Ross Sea exits the region within the passage between the Balleny Islands and Antarctica. We know this mainly from data west of 150°E. There are a few, but not many stations in the Balleny Passage. In order to trace the movement and mixing of the Ross Sea water westward through this passage, and evaluate the impact of possible local sources of dense deep/bottom water, we ended the cruise with a series of CTD stations at WOCE spacing [30 nm] through the Balleny Passage. The time for these stations came from the cancelled XBT survey of the Ross Sea margin.

 

Other Activities:

 

Ice Observations: Fulfilling a request from Steve Ackley, chairman of the SCAR-GloChAnt ASPeCT program, ice observations were also carried out during the cruise, using the Aspect protocols and software developed at CRC and Australian Antarctic Division by Anthony Worby (see Antarctic CRC Research Report 14, 1999). After a few days of training, a routine of hourly observations was established, under the coordination of Enrico Zambianchi, member of the ASPeCT SSG, and Karl Newyear, involving several volunteer watch standers.

 

Multibeam: Kathleen Gavahan reports that though the ice was extensive for most of the cruise we were able to add to the regional coverage.  We have filled a few data "holes" in the northwestern mooring area, where we have spend most of the time on this cruise.  We had pretty good coverage there already from NBP0209.  On our excursion to the Pennell area, we added to the definition of the shelf break. However, because of the ice, the quality of data has been patchy on this cruise. Ping editing volunteers were very active during the cruise. Erin Stone proved to be the most persistent of the ping editors.

 

Multibeam is an indispensable aid in siting moorings and in understanding the sea floor morphology control of the circulation and mixing processes.

 

 

[D] Acknowledgements & comments:

 

It's been a great cruise! The NBP is a fantastic ship, staffed with a fine group of capable and congenial people, across the whole spectrum. We have achieved the objectives of AnSlope cruise 1 under unexpected difficult ice conditions: the moorings have been placed to best achieve the AnSlope objectives; we have a detailed view of the stratification and circulation along the margins of the Ross Sea.  We succeeded because of the expert ship handling, as critical for the mooring operations and for weaving and breaking our way through the endless ice. The solid support provide by the Raytheon team, in keeping the equipment and computer network in tip-top shape allowed us to smoothly carry out the cruise activities. The dedicated of group of scientist insured the collection of quality data and in making maximum use of the available facilities.  All of individuals in the above mentioned groups deserved commendation. My special appreciation goes to Captain Joe Borkowski III who has earned my highest respect.

 

Adding to the science and the company was the natural beauty of the environment. The scenery was spectacular, particularly as the sunrise lit up the snow covered mountains to the west of the mooring area and the icebergs of varied sizes and shapes under flattering lighting conditions. There were many penguin, seal and whale sightings. Food is great, with variety to suit nearly every taste, prepared by a knowledgeable staff. [Though 24 hour availability of better coffee would be good; timely coffee brewed by the Raytheon MT was appreciated (just as I typed out this sentence).]

 

E-mail policy: the free daily 25K compressed limit is reasonable and the extra cost for additional exchange is not prohibitive to further meaningful use of e-mail. The chief scientist, who often is faced with many additional responsibilities at the home institution and SitReps, should be advised to request in the SIP a free limit of 50K compressed per day.


 

II CTD/LADCP/Tracer Chemistry [Bruce A. Huber]:

 

CTD/LADCP/Tracer

 

Profiles of temperature, salinity, and dissolved oxygen were obtained using equipment provided by RPSC.  The basic package consisted of a Sea-bird Electronics SBE911+ CTD system fitted with 2 sets of ducted conductivity-temperature sensors, dual pumps, and a single SBE 43 dissolved oxygen sensor.  The sensor suite was mounted vertically on a flat mounting surface just inboard of the lower frame supports.  The sensor pairs generally agreed to within 0.001 for both T and C throughout the cruise, and can be used interchangeably.   One-second GPS data from the vessel’s Ashtech GPS was merged with the CTD data stream and recorded at every CTD scan.   Data were acquired using  a PC running Windows 98 and Sea-Bird’s Seasave for Windows software.  Raw data was copied over the network to a separate drive immediately after the station.  Preliminary post-processing was carried out using batch files and scripts prepared by RPSC and modified by LDEO to provide a variety of CTD products to the AnSlope science party.  The processed data was copied to a network disk drive and was generally available within 10 minutes after the conclusion of a station.

All profiles were planned to reach within 10 m of the bottom.  Approach to the bottom was guided by a 12 kHz pinger (OSI ) mounted on the frame and an SBE bottom contact switch fitted with a 10 m lanyard and weight.  The pinger generally worked well, but required service twice during the cruise to replace the batteries.  The bottom contact switch gave sporadic results due to large drifts and bottom currents until station 40, when the original ¼” line and set of large shackles as weights were replaced with a much thinner nylon string and single, 5/8” shackle as weight.  From this point on, the bottom contact was for the most part reliable.

Water samples were collected using a 24-position SBE ­­32 Carousel sampler with 10 liter water sample bottles of the SIO Bullister design, modified to include a second, larger-bore valve adjacent to the standard sampling valve on the body of the bottle.  Water was collected for on-board analysis of salinity, dissolved oxygen, and CFCs.   Salinity and oxygen analyses are primarily for standardizing the CTD conductivity and oxygen sensors.  Additional samples were collected for later analysis at LDEO of helium, tritium, oxygen-18.  Samples for later analysis of nutrients in Italy were collected and frozen at -80ºC.

The water sampling system was generally trouble-free, with a few noteworthy exceptions:

-                          the sample valves on most of the bottles are very difficult to operate.  The RPSC marine technicians kept a ready supply of spares to install when a valve became troublesome, but more often than not, this was a temporary fix.  This issue should be investigated further by RPSC to determine if there is a flaw in the design or manufacture of the valve assemblies which promotes sticking.

-                          The latch assembly began to stick on station 100.  The assembly was replaced with a spare, but the spare proved to be worse than the original.  The original was carefully rinsed and replaced, and further sticking was only occasionally a problem.

-                          The casousel pylon electronics assembly failed on station 193.  A spare was installed from the backup CTD package.

Profiles of water velocity were obtained with the LDEO Lowered Acoustic Doppler Profiler system (LADCP).  The LADCP underwater system comprises two RDI Workhorse WH300 ADCPs and an LDEO battery/communications package.  The two ADCP heads (sn 150 and 149) are operated in master-slave configuration, with the down-looking head serving as master (sn  150).  Ping rate was nominally 1.5 seconds, with a bin length of 10 m.  Nominal range for each head was typically 100 m.   The data were processed using the LDEO LADCP software version 7b.  A one-second time series of the preliminary CTD data with integrated GPS navigation was used during the LADCP processing, accessed via the network immediately after each CTD station.  The CTD, GPS and ADCP bottom track data are utilized by the processing software to produce a velocity profile with 20 m vertical resolution, with velocity errors of typically 0.05 m/s .   A separate, more detailed  report on LADCP operations will be available after the cruise.  Of note is the effect of the bottom contact lanyard on quality of the LADCP data – the ¼” lanyard used for the first 39 stations caused data dropouts in the first down-looking bin.  It is important to use a thin line and small weight to avoid contaminating the ADCP data. 

 

Oxygen titration

An SBE 43 dissolved oxygen sensor was connected to the primary CTD sensor
array.  There was no discernable sensor drift over the time of the cruise as determined by inter comparison between station pairs at the same location during the beginning and the end of the cruise.  A preliminary correction was applied based on temperature, yielding close approximation to rosette bottle data. 1,400 oxygen samples were collected for Winkler titration.  An amperometric titrator, designed by Dr. C. Langdon, was used to titrate whole bottle samples.  The first eight stations were titrated using the RPS titrator,
after which it was swapped out for the PO titrator due to slow titration speed and the lack of software to change the speed.  Except for minor problems, the titrations ran smoothly.

 

Salinity determination

Water sample salinity was determined using the RPSC Guildline Autosal 8400B laboratory salinometer(number 59-213) , standardized with batch P141 standard water from OSIL.  Data from the autosal was captured by computer using an interface and software constructed at Scripps Oceanographic Inst.  The salinometer is housed in a temperature-controlled enclosure constructed in the Bio Lab.  The room temperature at the level of the salinometer is reasonably well controlled, but we found early on that there was a nearly 5 degree gradient between the deck and the autosal level.  Samples to be run are stored on the deck, and so were not equilibrating to near the salinometer bath temperature, causing some noisy runs.  We installed a circulating fan in the autosal room, minimizing the floor-to-ceiling temperature gradient. In order to speed sample processing, sample crates were placed in the aft dry lab sink immediately after drawing the samples, and the crates filled with tap water.  Water was changed 2 to 3 times over the next few hours, and the resultant water bath temperature checked with a thermocouple probe provided by RPSC.  This procedure stabilized the sample temperatures to around 20ºC within 6 hours and greatly improved the stability of the runs.  Overall the system works very well.  The combination of SIO interface and software, temperature stability, and excellent maintenance of the autosal yielded very low drift rates, and good repeatability of  replicate samples.   The bulk of the samples were drawn and run by K. Assmann and E. Curchitser.

 

 

 

 

 

 

Station Summary

 

Table II-1 provides summary information for the 206 CTD/LADCP/Tracer stations occupied during NBP03-02.   Bottom depths at the start of the CTD are in meters, as indicated by the multibeam center channel display. These depths are corrected for local sound velocity, profiles for which were determined by K. Gavahan from CTD data collected during the cruise. 

 

 

Latitude S

Longitude

 

 

 

 

 

Water Samples

 

CTD

Deg

Min

Deg

Min

 

Date m/d/y

Time (z)

Depth (m)

Max Pres

Dist off bot.

He

CFC

Ox

Trit

O18

Sal

Nut*

Notes

1

74

59.976

166

01.056

E

02/25/03

21:52

1035

990

10

11

22

23

11

11

22

 

 

2

74

30.096

174

45.468

E

02/26/03

20:07

502

493

10

 

14

12

 

 

12

 

 

3

74

00.084

175

09.906

E

02/27/03

00:17

586

580

8

13

14

14

13

13

14

 

Tr sample only half full

4

73

30.474

175

11.826

E

02/27/03

04:33

404

397

10

 

 

11

 

 

11

 

 

5

72

59.982

175

00.876

E

02/27/03

10:30

354

351

10

 

11

10

 

 

10

 

bottle 2 leaked from bottom endcap-loose o-ring

6

72

54.942

174

25.662

E

02/27/03

13:51

365

365

10

 

10

9

 

 

6

 

 

7

72

49.596

173

52.398

E

02/27/03

17:32

401

392

10

 

12

10

 

 

6

 

ladcp up-head data only

8

72

44.652

173

16.752

E

02/27/03

20:22

504

501

8

 

 

12

 

 

6

 

 

9

72

39.810

172

41.460

E

02/27/03

23:19

529

525

8

12

13

12

12

12

12

 

bottles 1,2 no trip-lanyards tangled

10

72

34.884

172

07.230

E

02/28/03

01:52

553

552

10

 

 

12

 

 

6

 

 

11

72

30.108

171

33.618

E

02/28/03

04:18

361

348

10

 

 

6

6

 

6

 

 

12

72

30.132

172

34.908

E

02/28/03

08:52

543

536

8

 

 

6

 

 

6

 

bottle 9 no trip

13

72

20.352

172

49.590

E

02/28/03

12:39

527

526

7

12

12

12

12

12

12

 

 

14

72

10.038

173

04.590

E

02/28/03

16:03

512

512

10

 

 

12

 

 

6

 

 

15

72

00.042

173

17.946

E

02/28/03

18:41

1053

1061

10

19

20

19

19

19

19

 

bottles 18,19 air vent leak

16

71

50.052

173

32.346

E

02/28/03

21:32

1953

1950

20

 

 

12

 

 

12

 

 

17

71

40.158

173

45.750

E

03/01/03

01:12

1967

1980

10

 

 

12

 

 

12

 

 

18

71

30.000

174

00.072

E

03/01/03

04:37

2132

2137

10

24

25

24

23

23

24

 

no Tr or 18-O sample niskin 23(smpl 103)

19

72

08.022

172

58.062

E

03/02/03

07:50

513

505

 

 

 

 

 

 

 

 

 

20

72

08.880

172

50.028

E

03/02/03

09:26

506

499

5

 

 

 

 

 

 

 

 

21

72

09.942

172

45.150

E

03/02/03

10:59

507

505

10

 

 

 

 

 

 

 

 

22

72

07.914

172

55.656

E

03/03/03

08:48

499

496

12

 

 

 

 

 

 

 

 

23

72

07.602

172

49.872

E

03/03/03

09:58

508

490

10

 

 

 

 

 

 

 

 

24

72

07.872

172

44.952

E

03/03/03

11:14

502

497

10

 

 

 

 

 

 

 

 

25

72

08.370

172

42.012

E

03/03/03

12:21

504

497

10

 

 

 

 

 

 

 

 

26

71

56.250

172

37.308

E

03/04/03

02:49

1674

1716

10

22

23

24

22

22

24

 

 

27

72

02.232

172

43.896

E

03/04/03

06:20

521

518

10

 

 

 

 

 

 

 

 

28

72

03.606

172

43.212

E

03/04/03

07:57

498

496

8

 

 

 

 

 

 

 

 

29

72

02.190

172

28.452

E

03/04/03

09:59

477

465

10

13

15

13

13

13

13

 

 

30

71

57.144

172

27.594

E

03/04/03

12:01

1592

1598

10

 

 

 

 

 

 

 

 

31

71

52.086

172

12.954

E

03/04/03

17:15

1078

790

 

 

16

15

 

 

24

 

drifted into shallower water during cast.

Bottle 18 lanyard caught in top endcap

32

71

50.028

172

37.200

E

03/05/03

19:32

1759

1695

10

 

22

21

 

 

24

2

air vent o-ring unseated bottle 9

33

71

58.938

172

47.496

E

03/05/03

22:44

888

893

6

 

 

 

 

 

 

 

 

34

72

00.852

172

48.612

E

03/06/03

03:11

560

602

10

 

 

 

 

 

 

 

 

35

71

57.990

173

00.054

E

03/06/03

06:33

1118

1125

9

 

21

24

 

20

20

 

18-O without Tr/He

36

72

03.780

172

56.154

E

03/06/03

08:56

532

 

9

 

 

 

 

 

 

 

 

37

71

58.584

172

35.298

E

03/06/03

10:53

990

1199

 

 

 

 

 

 

 

 

biota in sensor plumbing on ut

38

71

58.980

172

36.798

E

03/06/03

12:46

852

895

 

 

 

 

 

 

 

 

 

39

71

59.244

172

38.790

E

03/06/03

14:26

833

824

 

 

 

 

 

 

 

 

 

40

71

59.004

172

36.570

E

03/06/03

16:07

854

872

 

 

 

 

 

 

 

 

bottom contact lanyard and weight replaced prior to cast

41

71

59.082

172

33.600

E

03/06/03

17:30

904

890

 

 

20

19

 

 

20

4

 

42

72

02.508

172

37.506

E

03/06/03

21:56

504

496

8

 

 

 

 

 

 

 

halted on dt at 120m due to ice

43

72

02.754

172

36.828

E

03/06/03

22:47

508

492

8

 

 

 

 

 

 

 

at same site as 42

44

71

55.212

172

36.528

E

03/07/03

01:13

1764

1764

10

 

 

 

 

 

 

 

 

45

71

51.528

172

36.246

E

03/07/03

03:32

1759

1765

10

21

22

21

21

21

21

5

 

46

71

53.490

172

27.252

E

03/07/03

06:14

1613

1609

10

 

 

 

 

 

 

 

 

47

71

55.776

172

18.360

E

03/07/03

08:10

1534

1539

9

 

 

 

 

 

 

 

 

48

71

57.618

172

09.180

E

03/07/03

10:03

953

965

8

 

 

 

 

 

 

 

 

49

71

59.868

171

59.988

E

03/07/03

11:55

426

424

8

 

13

12

 

 

12

4

 

50

71

50.832

171

59.064

E

03/07/03

14:16

639

656

8

 

 

 

 

 

 

 

 

51

71

50.964

171

50.958

E

03/07/03

15:36

493

486

8

 

 

 

 

 

 

 

 

52

71

50.994

171

42.186

E

03/07/03

17:12

423

393

8

 

 

 

 

 

 

 

 

53

71

50.844

172

07.398

E

03/07/03

19:14

753

737

8

 

 

 

 

 

 

 

 

54

71

50.886

172

14.700

E

03/07/03

20:26

1122

1135

8

 

21

20

 

 

20

3

 

55

71

50.940

172

22.476

E

03/07/03

22:35

1636

1653

8

 

 

 

 

 

 

 

 

56

71

50.904

172

29.172

E

03/08/03

00:24

1573

1577

10

 

 

 

 

 

 

 

 

57

71

50.922

172

36.576

E

03/08/03

02:18

1685

1687

8

 

 

 

 

 

 

 

 

58

71

46.692

172

36.510

E

03/08/03

04:13

1668

1696

10

 

22

21

 

 

21

 

ros 11 leaked

59

71

44.220

172

36.342

E

03/08/03

06:50

1679

1673

9

 

 

 

 

 

 

 

 

60

71

42.534

172

37.242

E

03/08/03

08:44

1639

1643

8

 

 

 

 

 

 

 

 

61

71

40.830

172

37.050

E

03/08/03

10:33

1561

1565

10

 

23

22

 

 

22

4

 

62

71

40.722

172

24.768

E

03/08/03

13:22

1708

1716

8

 

 

 

 

 

 

 

 

63

71

40.212

172

12.000

E

03/08/03

15:41

1350

1352

6

 

 

 

 

 

 

 

 

64

71

39.402

172

00.138

E

03/08/03

17:41

625

 

 

 

 

 

 

 

 

 

cast aborted due to false bottom contact alarm

65

71

38.844

171

59.508

E

03/08/03

18:07

622

610

8

 

 

 

 

 

 

 

 

66

71

40.542

171

50.424

E

03/08/03

19:30

451

476

8

 

 

 

 

 

 

 

stopped cast on ut due to ice at 150 and 133 m

67

71

39.942

171

41.886

E

03/08/03

20:41

455

451

5

 

 

 

 

 

 

 

 

68

71

34.506

172

03.888

E

03/08/03

22:42

673

670

8

 

 

 

 

 

 

 

 

69

71

28.860

172

26.802

E

03/09/03

01:02

1853

1889

10

22

23

22

22

22

24

 

 

70

71

23.214

172

50.844

E

03/09/03

04:24

2154

2170

10

 

 

 

 

 

 

 

 

71

71

17.490

173

12.462

E

03/09/03

07:48

2068

2086

10

 

 

 

 

 

 

 

 

72

71

12.096

173

35.244

E

03/09/03

11:16

2230

2243

8

 

24

24

 

 

24

2

 

73

71

18.702

174

29.784

E

03/09/03

16:15

2188

2168

8

 

 

 

 

 

 

 

 

74

71

25.878

175

23.796

E

03/09/03

21:09

2210

2222

8

 

10

11

 

 

12

6

 

75

71

32.598

176

18.276

E

06/24/00

02:22

2034

2043

7

 

 

 

 

 

 

 

 

76

71

39.210

177

11.700

E

03/10/03

07:00

954

954

10

 

21

12

 

 

12

 

 

77

71

46.284

178

05.634

E

03/10/03

11:30

1848

1857

8

 

 

 

 

 

 

 

 

78

71

52.860

179

00.024

E

03/10/03

15:43

2256

2235

8

24

25

24

24

24

24

5

 

79

71

59.460

179

54.660

E

03/10/03

20:32

2223

2244

8

 

 

 

 

 

 

 

 

80

72

06.084

179

12.432

W

03/11/03

01:19

1314

1324

7

 

20

12

 

 

12

5

 

81

72

12.816

178

17.916

W

03/11/03

05:29

742

732

10

 

 

 

 

 

 

 

 

82

72

19.830

177

23.808

W

03/11/03

09:13

574

568

8

14

14

14

14

14

14

4

 

83

72

26.406

176

30.348

W

03/11/03

14:11

708

715

8

 

 

 

 

 

 

 

 

84

72

33.438

175

37.326

W

03/11/03

18:41

1099

1084

8

 

20

20

 

 

24

4

 

85

72

39.036

174

55.782

W

03/11/03

23:35

1845

270

 

 

 

 

 

 

 

 

cast aborted - ctd problems

86

72

39.192

174

57.018

W

03/12/03

00:43

1822

1835

9

 

 

 

 

 

 

 

ctd data spikes

87

72

59.556

174

59.430

W

03/12/03

05:11

2694

2705

7

 

 

 

 

 

 

 

 

88

73

18.984

174

55.158

W

03/12/03

11:29

2972

3008

8

 

24

24

 

 

24

4

 

89

73

38.364

174

56.298

W

03/12/03

17:36

2767

2799

10

 

 

 

 

 

 

 

 

90

73

59.226

174

58.932

W

03/13/03

03:23

2474

2505

8

24

25

24

23

23

24

5

 

91

74

20.370

174

59.742

W

03/13/03

10:28

2513

2541

8

 

 

 

 

 

 

 

ctd data spikes

92

74

37.728

174

44.304

W

03/13/03

17:15

2406

2442

8

 

23

23

 

4

24

4

bottle 6 air vent leak; 18-O in tcline; slip rings replaced prior to station

93

74

59.634

175

21.900

W

03/13/03

23:15

1909

1927

9

 

 

 

 

 

 

 

 

94

75

08.064

175

08.334

W

03/14/03

02:17

1576

1592

9

 

22

12

 

 

12

8

bottle 13 mistrip

95

75

18.324

175

10.734

W

03/14/03

06:08

1105

 

7

 

 

 

 

 

 

 

 

96

75

24.102

175

14.196

W

03/14/03

12:25

758

764

8

 

 

 

 

 

 

 

1st cast failed-data dropouts-repeated after making repairs to end termination splice

97

75

31.344

175

15.558

W

03/14/03

16:55

542

532

10

 

15

14

 

 

14

5

 

98

75

30.042

176

00.432

W

03/14/03

19:43

585

578

8

 

 

 

 

 

 

 

 

99

75

30.216

176

30.618

W

03/14/03

21:26

579

575

8

 

12

12

 

 

12

4

 

100

75

31.086

176

56.790

W

03/14/03

23:57

607

594

8

16

17

16

16

16

16

7

 

101

75

30.366

177

30.546

W

03/15/03

03:16

543

535

6

 

11

12

 

 

12

5

bottles 1,2,12,19 no trip, carousel latch ass'y replaced

102

75

30.336

177

51.924

W

03/15/03

05:23

499

 

7

 

 

 

 

 

 

 

test trip all bottles

103

75

23.772

177

27.798

W

03/15/03

10:08

516

509

7

 

 

 

 

 

 

 

test trip all bottles. Still have mistrips. Replace carousel latch ass'y with cleaned original.

104

75

16.542

176

53.322

W

03/15/03

13:14

564

557

8

 

 

 

 

 

 

 

test trip all bottles

105

75

09.840

176

09.360

W

03/15/03

16:35

883

917

8

18

18

18

18

18

18

5

 

106

75

05.850

176

07.218

W

03/15/03

18:44

1358

1390

9

 

 

 

 

 

 

 

 

107

74

59.724

175

55.122

W

03/15/03

23:13

1842

1858

8

 

 

 

 

 

 

 

 

108

74

54.036

175

42.132

W

03/16/03

02:12

2014

2035

8

 

 

 

 

 

 

 

 

109

74

47.880

175

30.270

W

03/16/03

05:27

2136

2164

9

 

 

 

 

 

 

 

gps froze for 3-5 minutes

110

74

36.096

175

33.174

W

03/16/03

09:27

2273

2295

8

 

 

 

 

 

 

 

all bottles test tripped at bottom

111

74

35.694

175

59.088

W

03/16/03

13:28

1951

1957

8

 

 

 

 

 

 

 

 

112

74

35.928

176

27.348

W

03/16/03

17:18

1307

1215

0

 

21

19

 

 

24

4

ctd frame touched bottom

113

74

35.700

176

57.396

W

03/16/03

20:14

898

912

8

 

 

 

 

 

 

 

 

114

74

35.316

177

25.842

W

03/16/03

23:35

556

226

 

 

 

 

 

 

 

 

cast aborted at 226m loss of signal, cable reterminated prior to cast 115

115

74

36.384

177

28.974

W

03/17/03

08:30

541

531

7

 

15

14

 

 

14

 

 

116

74

36.618

178

00.006

W

03/17/03

11:06

405

397

8

 

 

 

 

 

 

 

 

117

74

23.472

177

43.440

W

03/17/03

17:06

511

505

8

 

 

 

 

 

 

 

 

118

74

13.854

177

19.788

W

03/17/03

21:02

646

640

8

 

15

15

 

 

15

4

 

119

74

03.054

176

59.748

W

03/17/03

23:57

778

771

9

 

 

 

 

 

 

 

 

120

73

52.464

176

40.476

W

03/18/03

02:36

1046

1050

7

 

 

 

 

 

 

 

 

121

73

40.902

176

20.550

W

03/18/03

06:23

2308

2334

8

24

24

24

24

24

24

6

 

122

73

29.904

176

59.514

W

03/18/03

13:04

1143

1147

8

 

 

 

 

 

 

 

 

123

73

30.330

177

56.742

W

03/18/03

17:01

642

634

8

15

16

15

15

15

12

5

 

124

73

30.096

178

59.922

W

03/18/03

20:50

392

382

7

 

 

 

 

 

 

 

 

125

73

30.252

179

59.934

E

03/19/03

00:01

392

382

7

 

 

 

 

 

 

 

 

126

73

30.102

178

58.638

E

03/19/03

04:03

405

396

8

 

13

12

 

 

24

 

 

127

73

30.708

178

04.080

E

03/19/03

07:45

349

339

9

 

 

 

 

 

 

 

 

128

73

29.178

177

15.786

E

03/19/03

13:00

548

537

 

 

14

13

 

 

13

4

heavy ice, numerous bergs

129

73

19.728

177

07.218

E

03/19/03

15:52

490

484

8

 

 

 

 

 

 

 

 

130

73

08.598

177

18.804

E

03/19/03

19:10

620

623

8

16

15

 

 

 

15

5

 

131

73

00.270

177

15.744

E

03/20/03

00:17

993

988

9

 

 

 

 

 

 

 

spikes in ctd data. Rebooted computer prior to next cast.

132

72

49.596

177

39.564

E

03/20/03

04:15

1408

1409

7

 

22

12

 

 

12

6

 

133

72

40.044

177

49.218

E

03/20/03

07:51

1680

1696

9

 

 

 

 

 

 

 

 

134

72

29.988

177

59.376

E

03/20/03

11:03

1912

1930

8

22

22

22

22

22

22

4

bottle 3 no trip

135

72

30.486

177

30.642

E

03/20/03

14:28

1864

1884

8

 

 

 

 

 

 

 

 

136

72

29.916

177

01.086

E

03/20/03

17:47

1832

1855

10

 

23

23

 

 

23

3

 

137

72

29.910

176

31.248

E

03/20/03

21:31

1373

1355

8

 

 

 

 

 

 

 

bottom alarm on 165-500 m

138

72

29.964

176

00.048

E

03/21/03

00:13

708

704

8

 

12

12

 

 

12

5

 

139

72

30.162

175

29.934

E

03/21/03

02:36

536

524

8

 

 

 

 

 

 

 

 

140

72

19.440

174

58.860

E

03/21/03

06:16

528

528

7

 

 

 

 

 

 

 

 

141

72

10.086

174

59.796

E

03/21/03

09:13

1231

1232

6

20

21

20

20

20

20

6

 

142

71

59.910

174

59.934

E

03/21/03

12:42

1753

1764

 

 

 

 

 

 

 

 

 

143

71

49.758

174

57.696

E

03/21/03

16:02

2037

2050

8

 

 

 

 

 

 

 

 

144

71

40.068

175

01.092

E

03/21/03

19:45

2160

2174

10

24

24

24

24

24

24

5

 

145

71

29.970

174

23.940

E

03/22/03

00:21

2225

2205

9

 

12

12

 

 

12

4

 

146

71

35.292

174

16.470

E

03/22/03

03:26

2149

2162

9

 

 

 

 

 

 

 

 

147

71

40.188

174

08.940

E

03/22/03

06:54

2118

2133

8

23

23

24

23

23

24

4

1st cast aborted - ice in sensor plumbing.  Repeated cast.  bottle 24 leaked

148

71

45.558

174

01.758

E

03/22/03

10:27

2030

2051

 

 

 

 

 

 

 

 

 

149

72

11.820

173

24.954

E

03/23/03

09:30

558

552

8

14

14

14

14

14

14

4

 

150

72

08.604

173

34.896

E

03/23/03

11:48

558

561

8

 

 

 

 

 

 

 

 

151

72

04.740

173

34.986

E

03/23/03

13:35

842

879

8

 

 

 

 

 

 

 

CMiPS removed for repair

152

72

01.716

173

37.668

E

03/23/03

14:57

1206

1240

8

 

 

 

 

 

 

 

 

153

71

55.764

173

46.164

E

03/23/03

17:19

1825

1857

8

22

23

22

22

22

22

4

 23, 24 air leak

154

71

50.850

173

46.488

E

03/23/03

20:55

1981

2005

8

 

 

 

 

 

 

 

 ctd data spikes

155

71

58.200

173

12.222

E

03/24/03

02:45

1218

1206

10

 

 

 

 

 

 

 

No CMiPS; stopped at 760 ice; begin yo-yo

156

71

58.104

173

07.314

E

03/24/03

04:49

1196

1157

9

 

 

 

 

 

 

 

No CMiPS

157

71

58.788

173

03.246

E

03/24/03

07:01

1024

1008

8

 

 

 

 

 

 

 

No CMiPS

158

71

59.412

173

01.422

E

03/24/03

08:48

933

912

9

 

 

 

 

 

 

 

No CMiPS

159

71

59.184

173

10.830

E

03/24/03

10:44

1074

1081

8

 

 

 

 

 

 

 

No CMiPS

160

71

58.698

173

12.474

E

03/24/03

12:50

1151

1177

10

 

 

 

 

 

 

 

No CMiPS

161

71

58.068

173

13.878

E

03/24/03

14:46

1255

1300

8

 

 

 

 

 

 

 

No CMiPS

162

71

56.874

173

16.074

E

03/24/03

16:48

1504

1618

8

 

 

 

 

 

 

 

No CMiPS; end yo-yo

163

72

12.240

172

47.730

E

03/25/03

06:00

511

503

10

 

 

 

 

 

 

 

CMiPS reinstalled prior to cast

164

72

07.224

172

52.968

E

03/25/03

07:42

527

504

6

12

13

12

12

12

12

4

 

165

72

03.432

172

56.574

E

03/25/03

09:22

528

524

8

 

 

 

 

 

 

 

 

166

72

00.156

173

02.004

E

03/25/03

10:39

834

814

10

 

28

14

 

 

12

5

 

167

71

56.256

173

05.412

E

03/25/03

12:43

1538

1555

8

 

 

 

 

 

 

 

 

168

71

52.560

173

11.538

E

03/25/03

14:45

1896

1915

10

22

232

22

22

22

24

4

CFC in new ampoules drawn from 23,24

169

72

03.750

173

47.340

E

03/25/03

20:48

1105

1134

8

 

 

 

 

 

 

 

CFC in new ampoules drawn from 1

170

72

01.098

173

24.408

E

03/26/03

00:57

1057

1048

9

 

 

 

 

 

 

 

begin yo-yo

171

71

59.010

172

56.100

E

03/26/03

04:17

944

907

6

 

 

 

 

 

 

 

 

172

71

59.058

172

33.504

E

03/26/03

05:56

915

891

10

 

 

 

 

 

 

 

 

173

71

59.082

172

31.836

E

03/26/03

08:54

930

818

6

 

 

 

 

 

 

 

 

174

71

58.806

172

26.568

E

03/26/03

11:54

1075

920

6

 

 

 

 

 

 

 

 

175

71

58.854

172

28.470

E

03/26/03

14:55

1044

980

8

 

 

 

 

 

 

 

 

176

71

58.794

172

29.634

E

03/26/03

17:54

1031

995

125

 

 

 

 

 

 

 

stopped ~125 m above bottom due to ice.  Numerous ice stops on ut

177

71

59.046

172

30.978

E

03/26/03

21:35

937

1112

 

 

 

 

 

 

 

 

 

178

71

57.558

172

32.982

E

03/27/03

00:02

1461

1600

10

 

 

 

 

 

 

 

 

179

71

59.124

172

31.944

E

03/27/03

02:54

903

1087

40

 

 

 

 

 

 

 

large drift caused difficult bottom approach

180

71

59.490

172

32.364

E

03/27/03

05:54

820

867

6

 

 

 

 

 

 

 

end yo-yo

181

72

07.044

172

45.294

E

03/27/03

08:40

505

493

10

 

 

 

 

 

 

 

 

182

72

02.640

172

42.336

E

03/27/03

10:13

514

499

10

 

13

12

 

 

12

3

 

183

71

59.940

172

41.766

E

03/27/03

11:52

671

642

8

 

 

 

 

 

 

 

 

184

71

57.222

172

37.230

E

03/27/03

13:29

1480

1474

 

 

12

12

 

 

12

6

 

185

71

54.660

172

37.806

E

03/27/03

15:50

1786

1806

10

 

 

 

 

 

 

 

 

186

71

48.996

172

38.484

E

03/27/03

18:22

1679

1670

8

 

12

12

 

 

12

5

 

187

71

35.562

172

39.462

E

03/27/03

22:27

1787

1787

8

 

 

 

 

 

 

 

 

188

71

23.814

172

38.886

E

03/28/03

01:48

2189

2212

8

 

24

12

 

 

12

7

CFC test ampoules drawn from 2,13,24

189

71

12.756

172

29.046

E

03/28/03

05:38

2255

2285

9

 

 

 

 

 

 

 

 

190

70

59.988

172

13.560

E

03/28/03

11:15

2218

2235

8

24

24

24

24

24

24

5

 

191

70

30.906

171

00.978

E

03/28/03

23:20

2467

2494

8

 

24

12

 

 

12

7

CFC test ampoules drawn from 18,23

192

69

59.688

170

01.338

E

03/29/03

08:39

2709

2742

8

24

25

24

24

24

24

4

 

193

69

29.898

169

30.324

E

03/29/03

17:08

2721

2750

10

 

 

 

 

 

 

 

no bottles -  no trip confirms so recovered without bottle trips.  Problem traced to bad carousel electronics ass'y.  Replaced prior to ctd194 at same site.CMiPS removed for safekeeping-  will be replaced after ctd 194

194

69

28.956

169

30.630

E

03/29/03

22:05

2728

2753

8

 

22

12

 

 

12

5

bottles 1,11 air leak; #4 large valve dripped

195

69

00.078

168

59.928

E

03/30/03

05:05

2653

2656

13

19

24

24

19

19

24

6

 

196

68

47.994

167

29.334

E

03/30/03

13:02

2684

2704

10

 

21

24

 

 

24

5

 

197

68

29.958

166

29.268

E

03/30/03

19:56

2647

2664

8

10

24

24

10

10

24

5

 

198

68

14.964

165

29.106

E

03/31/03

03:52

2671

2693

7

 

14

14

 

 

14

6

no bottom contact alarm sounded

199

68

00.030

164

59.502

E

03/31/03

08:52

2656

2678

8

12

20

21

12

12

20

5

air leak bot 7

200

67

44.904

163

59.880

E

03/31/03

14:55

2639

2669

15

 

12

12

 

 

12

5

no pinger

201

67

29.640

163

00.876

E

03/31/03

21:04

2647

2670

8

18

18

12

18

18

12

4

 

202

67

12.090

162

00.000

E

04/01/03

03:35

2658

2681

10

 

16

14

 

 

14

4

 

203

66

59.766

161

00.192

E

04/01/03

09:56

2670

2692

8

18

18

18

18

6

18

6

O18 on 16-19,21,23 only

204

66

53.736

159

59.826

E

04/01/03

15:47

2618

2638

8

 

15

14

 

 

12

 

 

205

66

47.886

159

00.210

E

04/01/03

21:50

2748

2778

8

 

12

12

 

 

12

 

 

206

66

41.418

157

59.388

E

04/02/03

04:26

2729

2758

8

18

19

18

12

 

18

8

23:leak fm bottom O-ring

 

III  Moored Current Meters and T/C/P Recorders Array,    A. H. Orsi

 

The AnSlope Mooring Program is lead by A.H. Orsi and T. Whitworth III, Texas A&M University, and D. Pillsbury, Oregon State University.  An array of moored current meters, temperature, salinity and pressure recorders were deployed over the Antarctic continental slope near the sill of Drygalski Trough, in the western Ross Sea (FigureIII-1).  Measurements from this array will provide information on the flow structure and variability of the Antarctic Slope Front, the water masses carried by its associated current, and the characteristics of the denser bottom water outflow descending from the Trough.

 

Figure III-1

 

Three groups of moorings (for a total of 12) were arranged around specific isobaths across the eastern, central and western projections of the Drygalski Trough (Table III-1; embedded within the text and as a separate file).  Ten moorings on this array are instrumented with a total of thirty Aanderaa RCM8 current meters and twenty one MicroCat C/T/P recorders, distributed at depths between 400m and the bottom.  A separate westernmost mooring was deployed at the 900-m isobath; it is equipped with a near bottom upward looking SonTek Acoustic Doppler Profiler and three MicroCat recorders to provide high-resolution measurements of the benthic layer (750-900m) currents and stratification along the outflow of newly-formed bottom water.

 

TABLE III-1  The Moorings

 

MOORING

LATITUDE

LONGITUDE

DATE

DATE

TYPE OF

 

DEPTH

NAME

dd mm.mmm

dd mm.mmm

INSTALL

RECOVER

INSTRUMENT

SENSORS

Meters

PG-1

72°  07.223' S

173°  34.696' E

02-Mar-03

 

SeaCat

C,T,P

  619 

 

 

 

 

 

Bottom

 

  620 

EAST A-1

72°  07.708' S

173°  35.157' E

01-Mar-03

 

RCM-8

T,P,U,V

  397 

 

 

 

 

 

RCM-8

T,P,U,V

  497 

 

 

 

 

 

RCM-8

T,U,V

  577 

 

 

 

 

 

MicroCat

C,T

  587 

 

 

 

 

 

Bottom

 

  597 

EAST B-1

72°  03.842' S

173°  37.684' E

01-Mar-03

 

RCM-8

T,P,U,V

  397 

 

 

 

 

 

RCM-8

T,P,U,V

  597 

 

 

 

 

 

RCM-8

T,U,V

  977 

 

 

 

 

 

MicroCat

C,T

  987 

 

 

 

 

 

Bottom

 

  997 

CENTRAL A-1

72°  09.701' S

172°  57.221' E

02-Mar-03

 

MicroCat

C,T,P

  290 

 

 

 

 

 

RCM-8

T,P,U,V

  390 

 

 

 

 

 

RCM-8

T,U,V

  500 

 

 

 

 

 

MicroCat

C,T

  510 

 

 

 

 

 

Bottom

 

  520 

CENTRAL B-1

72°  03.849' S

173°  06.176' E

03-Mar-03

23-Mar-03

MicroCat

C,T,P

  304 

 

 

 

 

 

RCM-8

T,P,U,V

  404 

 

 

 

 

 

RCM-8

T,U,V

  524 

 

 

 

 

 

SeaCat

C,T,P

  533 

 

 

 

 

 

Bottom

 

  544 

CENTRAL B-2

72°  05.675' S

172°  56.500' E

25-Mar-03

 

MicroCat

C,T,P

  278 

 

 

 

 

 

RCM-8

T,U,V

  378 

 

 

 

 

 

RCM-8

T,U,V

  498 

 

 

 

 

 

SeaCat

C,T,P

  507 

 

 

 

 

 

Bottom

 

  518 

CENTRAL C-1

72°  01.851' S

173°  05.518' E

03-Mar-03

 

MicroCat

C,T,P

  328 

 

 

 

 

 

RCM-8

T,P,U,V

  428 

 

 

 

 

 

RCM-8

T,P,U,V

  528 

 

 

 

 

 

RCM-8

T,U,V

  608 

 

 

 

 

 

MicroCat

C,T

  618 

 

 

 

 

 

Bottom

 

  628 

CENTRAL D-1

71°  58.887' S

173°  11.446' E

02-Mar-03

 

MicroCat

C,T,P

  423 

 

 

 

 

 

RCM-8

T,P,U,V

  523 

 

 

 

 

 

RCM-8

T,P,U,V

  723 

 

 

 

 

 

MicroCat

C,T,P

  923 

 

 

 

 

 

RCM-8

T,U,V

  1,103 

 

 

 

 

 

MicroCat

C,T

  1,113 

 

 

 

 

 

Bottom

 

  1,123 

CENTRAL E-1

71°  57.090' S

173°  12.757' E

03-Mar-03

22-Mar-03

MicroCat

C,T,P

  107 

 

 

 

 

 

RCM-8

T,P,U,V

  207 

 

 

 

 

 

RCM-8

T,P,U,V

  407 

 

 

 

 

 

MicroCat

C,T,P

  707 

 

 

 

 

 

RCM-8

T,P,U,V

  1,007 

 

 

 

 

 

MicroCat

C,T,P

  1,207 

 

 

 

 

 

RCM-8

T,U,V

  1,387 

 

 

 

 

 

MicroCat

C,T

  1,397 

 

 

 

 

 

Bottom

 

  1,407 

CENTRAL E-2

71°  54.827' S

173°  12.657' E

24-Mar-03

 

MicroCat

C,T,P

  380 

 

 

 

 

 

RCM-8

T,P,U,V

  480 

 

 

 

 

 

RCM-8

T,P,U,V

  680 

 

 

 

 

 

MicroCat

C,T,P

  980 

 

 

 

 

 

RCM-8

T,U,V

  1,280 

 

 

 

 

 

MicroCat

C,T,P

  1,480 

 

 

 

 

 

RCM-8

T,U,V

  1,760 

 

 

 

 

 

MicroCat

C,T

  1,770 

 

 

 

 

 

Bottom

 

  1,780 

WEST A-1

72°  00.603' S

172°  49.571' E

06-Mar-03

 

RCM-8

T,P,U,V

  388 

 

 

 

 

 

RCM-8

T,P,U,V

  488 

 

 

 

 

 

RCM-8

T,U,V

  568 

 

 

 

 

 

MicroCat

C,T,P

  578 

 

 

 

 

 

Bottom

 

  588 

WEST B-1

71°  58.182' S

172°  45.384' E

06-Mar-03

 

RCM-8

T,P,U,V

  401 

 

 

 

 

 

RCM-8

T,P,U,V

  601 

 

 

 

 

 

MicroCat

C,T,P

  801 

 

 

 

 

 

RCM-8

T,U,V

  981 

 

 

 

 

 

MicroCat

C,T

  991 

 

 

 

 

 

Bottom

 

  1,001 

WEST C-1

71°  56.314' S

172°  43.656' E

04-Mar-03

 

RCM-8

T,P,U,V

  408 

 

 

 

 

 

RCM-8

T,P,U,V

  608 

 

 

 

 

 

MicroCat

C,T,P

  908 

 

 

 

 

 

RCM-8

T,P,U,V

  1,208 

 

 

 

 

 

MicroCat

C,T,P

  1,408 

 

 

 

 

 

RCM-8

T,U,V

  1,588 

 

 

 

 

 

MicroCat

C,T

  1,598 

 

 

 

 

 

Bottom

 

  1,608 

ADP-1

71°  58.887' S

172°  35.683' E

06-Mar-03

 

MicroCat

C,T,P

  753 

 

 

 

 

 

MicroCat

C,T,P

  828 

 

 

 

 

 

Doppler CM

T,P,U,V

  887 

 

 

 

 

 

MicroCat

C,T,P

  888 

 

 

 

 

 

Bottom

 

  903 

 

 

 

The deployment of all AnSlope-1 moorings took place during the first week of the cruise, 1-6 March 2003.  Unfavorable ice conditions were observed throughout the deployment period and the operational opportunities around the planned mooring sites were much reduced.  A decision to not attempt the recovery and redeployment of any of the moorings was made early on.  Fast converging ice floes managed to pinch flotation packages and hang three moorings at the sea surface for up to 2.5 hours after anchor launch.  In all occasions the freeing of these moorings was possible thanks to Captain Joe’s skilful maneuvering of the Palmer.  Nonetheless, some instruments were briefly dragged over the ice during the deployment of ice-hang moorings as the anchors eventually fell to the bottom.  Because these delayed deployments were also subject to a more significant drift with the ice, the final mooring locations were somewhat off the target isobaths, e.g. moorings Central D-1, B-1, and E-1 landed at 1123m, 544m and 1407m rather than the intended 1000m, 500m and 1600m. 

 

Two of the eleven moorings were subject to relatively high risk of failure for the long-term measuring period.  The top instrument of mooring Central E-1 lay just 100m below the sea surface, so that the whole mooring could be dragged and destroyed by passing icebergs.  Although the final location of mooring Central B-1 was not ideal, the top two of its four instruments were handled quite roughly during the delayed deployment, likely suffering some damage or malfunction thereafter.  These two moorings were recovered on March 22 and 23, 2003.  Central B-1 remained hidden under a small ice floe for several hours, while the acoustic release was constantly ranged to narrow down its location.  Eventually the Palmer managed to free the mooring by crunching up the offending ice floe.

 

Except for the top Aanderaa on Central B-1, which experienced a failure of its data storage unit prior to its deployment, data from all other instruments were fully recovered.  Three of the recovered Aanderaas had parts replaced prior to redeployment.  Preliminary inspection of the data collected from all recovered current meters and MicroCats revealed no gaps or any apparent malfunctioning during the 20-day record length of their first deployment.  Central E-2 and Central B-2 moorings were redeployed on March 24 and 25, 2003.   Again, less than optimal ice conditions were encountered during these deployments.  Central E-2 was suspended from an ice floe for about 35 minutes after anchor launch, and it had to be freed with the Palmer’s help.

 

Acknowledgements.  The great success of the mooring program carried out during AnSlope-1 was largely due to the detailed and careful direction demonstrated by Jay Simpkins and Kathryn Brooksforce.  We are very grateful to Captain Joe for his patience and masterful handling of the N. B. Palmer during mooring work.  Deck operations were safe and clear at all times, thanks to the skillful team work provided by Raytheon personnel Steve Tarrant, Annie Coward, Chris McGuire, and Jen Huggins (MTs.); Karl Newyear (MPC); Laura Tudor (MST) and Bruce Felix (ET); Amy Bratcher (Texas A&M university); Bryan Klostermeyer (Coast Guard); Bruce Huber (LDEO); the officers and crew of the N. B. Palmer (ship’s deck machinery); and a legion of other willing assistants that always brought the right instruments at the right time.

 

 

 

IV    Turbulence Measurements, Bottom Pressure Sensor, and Tides Modeling

L. Padman, Earth & Space Research

 

CTD-mounted Microstructure Profiling System (CMiPS)

 

The primary goal of CMiPS is to measure temperature and conductivity gradients (dT/dz and dC/dz respectively) at the small spatial scales (~1-20 cm) associated with ocean turbulence and double-diffusive convection. CMiPS records data from two high-resolution temperature sensors and one micro-conductivity probe, plus data from a 3-axis accelerometer and a pressure sensor. Data are recorded internally at 512 Hz per channel, and downloaded after each CTD cast. The effective vertical resolution for vertical gradients of T and C is about 2-5 cm. CMiPS was deployed on most CTD casts during AnSlope-1.  The nominal depth rating for CMiPS is 3500 m. The deepest cast during AnSlope-1 was ~2900 m.  While not a conclusive observation, it does appear that repeated cycling of CMiPS below ~2000 m degrades the thermistor performance, and we need to look into the manufacturing of new probes for future cruises.

 

The CMiPS C sensor performed well throughout the program.  The primary T sensor (T1) performed well except for a short period (CTDs 155-162). The secondary T sensor T2) was noisier that T1 and in general has not been analyzed at sea since its signal is essentially redundant with T1.  The source of the additional noise on the T2 channel has not been determined.

 

CMiPS is mounted within the CTD rosette, with sensors ~15 cm above the lower rosette frame. To work well, the sensors must see relatively undisturbed water.  This is only possible when the CTD fall rate is greater than some value.  The standard rate of 50 m/minute generally worked well: the “safety” speeds of 10 and 20 m/minute, used near the surface and when approaching the bottom, generally degrade the data to the point where they cannot be used for turbulence studies.  It is possible that some data from the rapidly flowing high-salinity plumes (>120 cm/s) will also be unusable because of the interference from turbulence associated with the rosette cage.  In general the most important regions sampled by CMiPS include the base of the mixed layer during periods of significant wind stress, and at the upper edge of cold plumes (both high salinity and low salinity varieties).  We also found that, even though large-scale hydrographic conditions are favorable for double diffusive convection (DDC) to occur, no evidence of significant DDC fluxes was found in the CMiPS records, consistent with the dominance of shear-generated turbulence in this region.

 

Raw CMiPS data are included on the cruise data distribution, but no advanced, processed results are included. These will be web-served after post-processing after the cruise.  Plots of roughly calibrated T, C, dT/dz, dC/dz, 3-axis accelerations (Ax, Ay, Az) and filtered fall speed are included in the “Science//NBP0302/CMiPS” directory, along with a README explanatory file.  These plots are primarily intended as at-sea quality diagnostics, but can also be used as a rough guide to locating regions of ocean turbulence by focusing on the variance of the dT/dz and dC/dz traces.

 

Bottom Pressure Recorder (BPR)

 

The BPR was deployed at 72o 07.223’ S, 173o 34.696’ E, near the “Eastern-A” mooring.  The BPR samples every 30 minutes, and will be used to validate tide models for the region, and in data assimilation studies. The original plan was to recover the BPR towards the end of AnSlope-1 in order to use the 1-month record that we would obtain in AnSlope Year-2 tide-model data assimilation studies.  Heavy sea-ice in the region prevented recovery, but the BPR is capable of recording at the present sample rate until recovery in early 2004.

 

Tide Modeling

 

All velocity data, including vessel-mounted and Lowered ADCP (VM-ADCP and LADCP) and ice motion, indicate strong tidal currents in many regions of the AnSlope study area, notably the outer shelf and slope in the western area either side of the mouth of Drygalski Trough. Variability in the ship’s ability to move through the ubiquitous thick ice that we encountered this year suggests tidal modulation of the stress divergence on the ice, at least close to the shelf break.  Pressure and temperature records from the recovered Central-E and Central-B moorings confirm the strong tides.  Ross Sea tides are predominantly diurnal, with the principal components (K1 and O1) having roughly the same kinetic energy levels. The result is a very pronounced spring-neap cycle (~2-week period) from negligible currents at neap tide to spring currents that exceed 1 m/s. 

 

VM-ADCP and LADCP data were frequently compared against the predictions of our barotropic (depth-integrated) tides model, the Circum-Antarctic Tidal Simulation Version 2002.1 (CATS02.01).  While more robust calculations will be done after the VM-ADCP data are reprocessed and mooring velocity data become available, it appears now that CATS02.01 underpredicts tidal current magnitudes in the western region by ~25%, and has phase errors of up to 3 hours to the east, past Iselin Bank.  In general, these errors can be attributed to bathymetry errors in the model.  We will update the Ross Sea bathymetry based on recently acquired depth and multibeam data, and also reduce the grid size for a Ross-Sea-only model from the present ~10 km for CATS02.01 to ~2 km.  Increased resolution is necessary to resolve the very steep continental slope to the west of the AnSlope moorings.

 

Acknowledgements.  The excellent performance of CMiPS depended heavily on Chris MacKay’s patient and methodical handling of the instrument, and the able assistance of   the Raytheon Marine Techs, in particular, Steve Tarrant.  The large volume of data from CMiPS was managed on the ship’s network and backed up by the Raytheon Electronics Techs.  Jay Simpkins and Kathryn Brooksforce ably carried out mooring operations in extremely difficult ice conditions.  Grateful thanks also to Karl Newyear (Raytheon MPC) for facilitating the logistics associated with CMiPS use in AnSlope, and to Captain Joe, the officers and crew of N. B. Palmer, for getting us through the ice to where we wanted to go, and providing a great ship to spend time in.