Ka’imimoana – NOAA Teacher at Sea Blog

August 3, 2010April 22, 2021

Wesley Struble, 3 August, 2010

NOAA Teacher at Sea
Wes Struble
Onboard NOAA Ship Ka’imimoana
July 8 – August 10, 2010

Mission: Tropical Atmosphere Ocean (TAO) cruise
Geographical area of cruise: Equatorial Pacific from 110 degrees W Longitude to 95 degrees W Longitude
Date: 3 August 2010

Weather Data from the Bridge
Position: 7 degrees north latitude & 95 degrees west longitude
Cloud Cover: 5/8
Cloud Type: Cumulus, Stratocumulus, & Cirrus
Visibility: 10 nautical miles
Wind Speed: 14 knots; Wind Direction: 240 degrees
Wave Height: 1 foot; Swell Height: 3 – 4 feet
Atmospheric Pressure: 1010.5 mb
Temperature: 27.2 degrees C (81 degrees F)

Science and Technology Log

As I have mentioned before many of the buoys in this part of the Pacific Ocean are badly vandalized and some are completely missing. Buoys that have been deployed for 6 months or more often sit low in the water. This is not because the flotation toroid loses buoyancy (although when damaged they can take on large volumes of water), rather it is usually due to the massive amounts of marine life that tends to cling to the buoy and its underwater substructure.

When the buoy is slowly lifted onto the fantail work area at the stern of the ship it will be encrusted with barnacles that can add up to an additional 500 to 1000 lbs to the buoy’s weight. Many are attached directly to the float’s surface while others have extended themselves and hang down several inches. Sometimes they have completely covered the substructure. These barnacles create a lot of extra work for the science crew – scraping, cleaning, and repainting of the buoy toroid.

struble_log7_img_2 — A colorful crab found on the buoy’s substructure during cleaning

In addition to the barnacles one often finds small crabs. Most of these are no bigger than a half dollar coin (although we did find one larger specimen – see the included photo). One of the most odd and dangerous creatures often present hidden in and around the barnacles are Fireworms (see photos). These particular polychaeta organisms can reach up to 20 inches in length and have a diameter about the same size as an average adult human finger. They are covered with a very impressive set of spines and/or hairs that carry a potent toxin that stings and burnstouched. I have been told that the sting is particularly painful. These organisms can get relatively large and at times there can be quite a few on one buoy. The science team has to be wary when they are handling and cleaning a buoy so as to avoid touching these creatures. On the previous buoy we found a total of six.

In addition, we even found one small fish that got caught in the substructure and brought in with the buoy. It is not difficult to understand barnacles attaching to the buoy substructure because we know that ships often will have problems with barnacles on their hulls. But it is more difficult to understand how Fireworms and crabs (which usually inhabit the sea floor) could be living on the buoys where the water is over 10,000 feet deep!

struble_log7_img_3 — Two Fireworms removed during a buoy cleaning

We have also had more aerial visitors the last several days (probably due to our relative proximity to the Galapagos Islands – which are currently about 200 nautical miles to the east). Earlier today some members of the crew sighted a Boobie and we are now being followed by a small flock of frigate birds. In fact, one of the frigate birds was hiding inside the central cavity of the buoy. It escaped when we began retrieving the buoy line.

struble_log7_img_4 — SST Tonya Watson prepares an Argo float for release

We just released an Argo buoy yesterday afternoon. There are a number of differences between the Argo buoys and any of the other floats or buoys we work with here on the KA. First of all they are much smaller and lighter (they weigh about 60 pounds, but are precision weighted in order to maximize buoyancy ability. Nothing extra can be put on them without buoyancy compensation being taken into consideration) than the large TAO buoys (which weigh in the neighborhood of 1500 lbs.). Most buoys are anchored to the ocean floor in order to get a constant data return from a particular location. The Argo buoy, on the other hand, is a drifting buoy, like a disposable/portable CTD – it is not tethered to the sea bed but drifts with the currents collecting temperature, salinity, and density readings.

The other main difference is the way that Argo buoys collect data. These buoys are semi-autonomous being programmed to follow a particular sequence of data collection events and motions. When released the buoy begins floating at the surface in a horizontal position. There is a small hole in a compartment at the base of the buoy. This cavity slowly fills with water causing the buoy to flip to an upright position. When in this position the buoy’s antenna is out of the water and is able to transmit data to the data collection center. After a time it slowly sinks to a depth of 2000 meters (over 6000 feet or over 1 mile) where it remains for 10 days. After this period the buoy then rises to the surface to expose its antenna and transmit data, which it does for a period of hours depending on how long it takes to transmit the data. There are many Argo buoys drifting in the Pacific and you can see their current positions and review the collected data on this web site http://www.argo.ucsd.ed

struble_log7_img_5 — KA crew member Francis Loziere prepares to release an Argo float

struble_log7_img_6 — Argo float drifting away from the KA

Personal Log

I have been at sea now for just about four weeks and I am starting to get a bit anxious to get back home. Assuming there are no problems or difficulties we should be pulling into Manzanillo, Mexico on the morning of the 10th of August. After being out of sight of land for over a month it will be a welcome sight. It has been a very interesting experience to get up in the morning day after day, week after week, and see nothing but water in every direction for as far as one can see. It took me a while to adjust to the constant motion of the ship – now I take it for granted and don’t really think about it that much. I am curious how I will react and how it will feel when I step back on land and have a completely stable surface on which to walk. The ship seemed very large when I first came on board but as you can imagine as the days and weeks have gone by the vessel has gotten smaller and smaller.

Animals Seen

We had a rare treat during one of our recent buoy operations. While recovering the buoy at 5 degrees north latitude we noticed many fish in the water around the ship – especially off the stern. All of a sudden off the starboard side a small school (10 – 20) of large Mahi mahi started jumping out of the water in arcs as they swam. They did this for several hundred meters, first moving parallel to the ship and then off the starboard stern. A number of them were very large (4 – 5 feet) and a beautiful blue color. It makes one wonder if they are enjoying themselves.

We also have had quite a few birds, mostly gulls and frigate birds, beginning to follow the ship, although I did see a smaller bird darting around the fantail that I could not identify (but it reminded me of an oversized starling).

July 31, 2010April 22, 2021

Wesley Struble, 31 July, 2010

NOAA Teacher at Sea
Wes Struble
Onboard NOAA Ship Ka’imimoana
July 8 – August 10, 2010

Mission: Tropical Atmosphere Ocean (TAO) cruise
Geographical area of cruise: Equatorial Pacific from 110 degrees W Longitude to 95 degrees W Longitude
Date: Thursday, 31 July 2010

Weather Data from the Bridge

Current Position: 2.25 degrees South Latitude & 95 degrees West Longitude;
Cloud Cover: 5/8,
Cloud types: Nimbostratus, Stratus, & Altostratus;
Visibility: 10 nautical miles;
Wind Speed: 13 knots;
Wind Direction: 130 degrees;
Wave Height: 1 – 2 feet;
Swell Height: 4 – 5 feet,
Atmospheric Pressure: 1014.0 mb;
Temperature: 20.0 degrees C (68 degrees F)

Science and Technology Log

It is easy to get wrapped up in the day- to-day cruise activities that are involved in maintaining the buoy array and the ship. Lest we forget, I wanted to spend a little time in this log discussing the overall purpose that has led to the investment of all this technology, science, and financial resources.

struble_log6_img_0 — A moment of respite during a buoy deployment operation

This cruise (and many others that follow on a regularly scheduled basis) maintains the TAO buoy array. TAO stands for Tropical Atmosphere and Ocean. The buoy array is located at approximately 15 degree intervals from 95 degrees West Longitude (just west of the Galapagos Islands) across the Pacific to 135 degrees East Longitude (north of the Island of New Guinea). In addition, the buoys are placed north and south of the equator at 8 degrees, 5 degrees, 2 degrees with one buoy positioned on the equator itself.

These buoys measure a variety of ocean and atmosphere conditions: Air temperature, wind speed, wind direction, rainfall, and relative humidity. They also measure water temperature and conductivity. The buoys generally transmit their data hourly. Besides the huge amount of information that is collected over time that can be used to study atmospheric and oceanographic weather conditions, the TAO array also has a very specific goal – to collect data to increase our understanding the El Niño/La Niña cycle, otherwise known as the Southern Oscillation.

struble_log6_img_2 — NOAA Corps Ensign Alise Parrish at the controls of Aftcon (Aft control room) during a buoy deployment

Most people have at least heard of the El Niño phenomenon but, other than knowing that it somehow affects weather patterns, many are ata loss when asked to actually explit. The El Niño is a cyclic weathphenomenon that affects a very large portion of the globe. In its simplest form it is a shifting of warm Pacific Ocean water from the western part of the basin (near New Guinea, Indonesia, and northern Australia) across the equatorial Pacific toward the South American Continent near Peru/Ecuador.

In normal climate years the Trade winds (the Trade winds are easterly winds) and ocean currents (specifically the Equatorial current – a west flowing current) work together to keep the warm equatorial waters in the western Pacific piled up near New Guinea & Indonesia). These warm waters produce huge amounts of evaporation pumping massive amounts of moisture into the atmosphere in this part of the globe. This moisture returns to the earth in the form of the monsoons and rainy seasons so typical for that part of the world.

struble_log6_img_3 — NOAA Corps Ensign Linh Nguyen catching some sun and reading time during a cool afernoon on near the equator

During an El Niño cycle the Trade Winds and currents weaken allowing the warm western Pacific water to move east across the basin relocating the warm water nearer the South American continent. This rearrangement of ocean water – warm water to the east and colder water to the west – tends to suppress the rainy seasons and monsoons in the western Pacific and brings huge amounts of moisture and storms to the eastern Pacific. Hence, countries, such as New Guinea, India, Indonesia, and others in the region, which depend on the rain and moisture, are left dry and often experience significant drought conditions. These droughts place many people’s livelihoods and even their lives in danger due to starvation and economic loss.

On the other side of the ocean those countries in the eastern Pacific (from Peru north through California) will often have their coasts battered by large storms causing huge amounts of destruction and loss of life. In addition, in the interior they often experience heavy rains in areas that are normally mildly arid. This produces disastrous and lethal flash floods and mud slides. In those areas with little or no sanitation removal, poor or non-existent sewage treatment systems, in combination with compromised drinking water delivery systems can be followed by deadly outbreaks of typhoid and cholera and other life threatening diseases.

With these awful potential consequences, knowing when conditions for an El Niño cycle are in their early stages would be very helpful. The TAO array acts like an early warning system. During the Cold War the United States depended heavily on the DEW (Distant Early Warning) line in northern Canada, Alaska, and Greenland. This was a series of radar stations that looked north over the pole to identify a launch of nuclear missiles soon after they left the ground from the former Soviet Union. The idea being that it would give the U.S. as much time as possible to prepare for the strike and to prepare a response. In a similar way the TAO array is a distant early warning system that registers the changes in ocean temperature and current direction as the warm water of the El Niño moves east across the Pacific. This information gives the countries affected by an El Niño time to prepare for all the possible problems they might experience. The system is expensive to maintain but, much like hurricanes, if you know it is coming well ahead of time preparations can save millions or billions of dollars and thousands of lives.

Personal Log

Yesterday I spent some time with Tonya Watson (the SST) in the wet lab. She explained the operation of the Autosal and ran a few samples. This machine indirectly measures the salinity of sea water by actually measuring the conductivity of the sample. I hope to explain this in some detail in a future log. Later in the day one of the crew members, Frank Monge, caught a very large and brilliantly colored, Mahi mahi. We are hoping to see more marine life as we get closer to the Galapagos Islands. The water will be shallower and warmer and I hope to be able to spot some whales. The weather conditions have continued to remain cool, mostly in the 70’s, with mixed clouds, wind, and sunshine. I am grateful that the cooler than normal temperatures have been the rule for this cruise.

July 26, 2010April 22, 2021

Wesley Struble, 26 July, 2010

NOAA Teacher at Sea
Wes Struble
Onboard NOAA Ship Ka’imimoana
July 8 – August 10, 2010

Geographical area of cruise: Equatorial Pacific from 110 degrees W Longitude to 95 degrees W Longitude
Date: 26 July 2010

Weather Data from the Bridge

Position: 8 degrees South Latitude and 104.5 degrees West Longitude
Cloud Cover: 5/8 with cumulus and stratocumulus clouds
Visibility: 10 nautical miles
Wind bearing: 150 degrees
Wind Speed: 17 Knots
Wave height: 2 – 3 feet
Swell Height: 6 – 9 feet
Atmospheric Pressure: 1016.6 mb
Temperature: 23.7 degrees C (74.7 degrees F)

struble_log5_img_1 — Muster Station 4 on the boat deck and the Life Raft

The sea has been rough the last several days with large swells up to 12 feet or more that are really causing the ship to pitch quite strongly. The captain has had the anti-roll tanks filled and that has helped but the ship still pitches and rolls quite a bit. I am typing this up on deck sitting at a picnic table because the chair in my room is a typical desk chair with small wheels and if I use it I wind up rolling all over the room.

We are approaching the southern extreme of the TAO at 110 degrees West Longitude. After we visit the last buoy on this line located at 8 degrees south latitude, we will plot a course due east and head for the 95 degree West longitude line (about 900 nautical miles east). We expect to arrive there in a few days after which we will do maintenance on the buoy located at 8 degrees south latitude and then proceed north following 95 degrees West longitude.

Today we had two emergency drills (as we do every week). These drills are not the same as we have in school where alarm rings and the principal measures the amount of time it takes to get the entire school evacuated. On a ship it is much more complicated because if (for example) there is a fire we cannot simplyevacuate the ship and call the fire department – we are the fire department! With this in mind there is a detailed plato follow every time there is a drill. are three common emergency bell signals and a drill that matches each. Three long bells signal that a man is overboard.this happens every person has a stationwhich they are required to report.

My station is the buoy deck (the aft part of the ship) and my job is to find the person in the water, point to their location, and not lose sight of them. This might seem straightforward, but with the moving of the ship, large waves, and enormous swells (behind which a floating person can easily disappear) it makes it a bit tricky.

During man overboard there are many people acting as spotters placed at different stations on the deck so that the location of the man overboard is always known. Once the location has been established the skiff will be lowered into the water and the person retrieved. Six short bells followed by one long bell is the signal that means abandon ship.

As with all drills every person has a specific station to which they are to report and has particular duties for which they are responsible. If we were actually required to abandon ship then my first task is to report to station four which is located on the port side of the ship on what is called the boat deck. Once there the officer in charge of the group takes role to make sure all are accounted for. We are all required to bring three things: a life jacket (which you don immediately), your “Gumby” suit (a kind of water survival suit that keeps you warm and dry in cold water), and a small sack containing a pair of long pants, a long sleeve shirt, and a hat (all for protection from exposure).

My job is to deploy the Jacobs ladder (this is the ladder used to climb down the side of the ship to access the inflatable life raft) and bring several large jugs of drinking water. In addition, if no one else is available then I would also deploy the life raft.

A fire drill (or collision) is represented by one long (longer than 10 seconds) continuous bell. During a fire drill I am to report to the mess (with several other people) and act as a runner and await further instructions. Fire drills usually entail some sort of scenario where a mock fire is reported in some part of the ship. There is usually a discussion before the drill to be certain that everyone understands what this particular drill is trying to accomplish. Our first fire drill was designed to have a mock fire on the boat deck caused by ruptured or leaking fuel cans. Our second fire drill was a scenario designed to respond to a fire with a lot of smoke in the galley. These drilhave been a real learning experience for me. They are helpful because they build confidence and cut down immensely on confusion and response time in case of a real fire.

Personal Log

Up till this point I have been pleasantly surprised at how cool and breezy the cruise has been. I expected that the temperatures would be in the 90’s and the humidity in the same range. However, the temperature has rarely reached 80 degrees F (most of the time in the mid to upper 70’s) and even though the humidity has been high the constant breezes have kept it very comfortable. In addition, much of the cruise has taken place under various amounts of cloud cover. We have been at sea 19 days and only a handful of them have been clear and sunny. In fact, it has been much hotter at my home in north Idaho than it has been here on the equator. I have lived in equatorial regions before so I know that this is definitely an anomaly – but I hope it continues.

struble_log5_img_5 — Early Evening over the East Pacific

July 23, 2010April 22, 2021

Wesley Struble, 23 July, 2010

NOAA Teacher at Sea
Wes Struble
Onboard NOAA Ship Ka’imimoana
July 8 – August 10, 2010

Mission: Tropical Atmosphere Ocean (TAO) Cruise
Geographical area of cruise: Equatorial Pacific from 110 degrees W Longitude to 95 degrees W Longitude
Date: Friday, 23 July 2010

Weather Data from the Bridge

Current location: 4 degrees South Latitude & 110 degrees West Longitude
Cloud Cover: 5/8
Cloud Type: Stratocumulus
Visibility: 10 nautical miles
Wind Bearing: 100 degrees
Wind Speed: 20 Kt
Wave Height: 2 feet
Swell Height: 5 – 7 feet
Barometric Pressure: 1015.5 mb
Temperature: 24.8 degrees C (76.6 degrees F)

Science and Technology Log

There are a variety of buoys used by NOAA in the Pacific Ocean. One of the more interesting is the ADCP buoy. ADCP stands for Acoustic Doppler Current Profiler. This buoy is anchored to the sea floor like most of the other buoys deployed on this cruise. The major difference is that the ADCP buoy does not float at the surface but rather is tethered with a line short enough to keep it submerged approximately 300 meters below the surface of the sea. In addition, it is only deployed with the TAO buoys at the equator and not at any of the other TAO buoy locations. The buoy’s name defines its function – current profiling – using acoustic signals (similar to sonar) the buoy provides a profile (or vertical map) of the ocean currents from the depth at which the buoy is tethered to the surface. The ADCP is able to measure both the speed of the current and the direction in which it is moving. Even though the TAO buoy at the same latitude is generally visited more often, the ADCP buoy is visited only once per year. During the visit the buoy is retrieved, cleaned, damaged parts replaced or repaired, data downloaded, batteries replaced, and sensors upgraded (if necessary).

struble_log4_img_1 — Buoy with newly attached ADCP unit – A

struble_log4_img_2 — KA skiff at the ADCP buoy

The flotation component of the buoy is a large orange sphere just over four feet in diameter. This float is made of syntactic foam. In general, foam is a mixture of two substances: a gas phase in a solid or liquid phase. Syntactic foam should not be confused with the common foam with which we are all familiar (like the typical Styrofoam coffee cup). Most of these foams are generally composed of expanded polystyrene (a thermoplastic polymer) where the gas phase is air and the solid phase is polystyrene. Syntactic foams on the other hand use other substances for the components.

struble_log4_img_3 — The ADCP acoustic transmitters & receivers

One of the more common syntactic foams uses small glass spheres 10 – 200 micrometers (millionths of a meter) in diameter. These glass spheres are filled with air during the manufacturing process. The spheres are then mixed in with some type of epoxy resin and allowed to cure to produce the foam. The buoyancy of the foam is affected by the size, number, and wall thickness of the glass spheres. Some of the applications that typically utilize syntactic foams are the manufacture of radar transparent materials, acoustic attenuating materials, and more specifically deep sea buoyancy floats. Our float is anchored to the sea floor with a large (several thousand pound) weight that prevents it from drifting. The material used to attach it to the anchor is very stable and exhibits little elongation under tension, thus keeping the buoy consistently at the same depth. The payload (the ADCP itself) is approximately 1 meter long and about 20 centimeters in diameter and is mounted in a circular well that is bored vertically through the center of the float. The ADCP has four sending/receiving units mounted at the top of the main body. One can see these in the photographs. These units send and receive a 75 kHz signal that reflects (echoes) off the sea/air boundary and returns to the buoy.

When we were close to the location of the ADCP buoy one of the scientists activated an acoustic trigger that released the buoy from its sea floor mooring anchor. Since it was almost 1000 feet under water it took a few minutes for the float to reach the surface. When the buoy was spotted the ship made a slow pass to visually inspect the float and to launch the skiff. The skiff towed a long and very strong line from the ship which was then attached to the top of the buoy. At this point the skiff was brought back aboard. The ship then came about so that the buoy was directly a stern. When all was ready the winch began to retrieve the line and slowly bring the buoy on board. When it reached the deck of the fantail it was made secure and the tether line (that attached the buoy to the anchor) was tied off to a chain on the ship’s deck.

struble_log4_img_4 — Working on the ADCP buoy on the fantail of the KA – B

The buoy was then disconnected from its tether line and the line was attached to a large winch and all several thousand meters of it was rolled onto a number of large empty spools and stored on board. While the anchor line was being retrieved the science crew downloaded the stored data from the ADCP and prepared the buoy for redeployment. When the deck hands were ready the process was reversed. First, the tether line was attached to the buoy and it was lowered over the fantail. Then the line was slowly played out. When the ship was in the appropriate position she began to move forward as the crew played out line. When they reached the end of the line a large (several thousand pound) anchor was attached, lowered, and released. This entire process took the better part of a day.

struble_log4_img_5 — Crew member Nemo McKay & Scientist Will Thompson retrieving the ADCP buoy

Personal Log

I have enjoyed getting to see the crew work together. One can tell that they clearly get along well and appear to enjoy working together because of all the friendly banter that passes between them. I have been impressed with how conscious they are about safety. I have been able to begin participating in some of the work deck activity during the buoy operations and it has helped in my understanding of what actually takes place. It has also helped me to get to know a number of the crew members better.

“Did You Know?”

Did you know that the greatest buoy equipment problem that occurs in this area of the ocean is vandalism? Many of the buoys are damaged, stolen/cut loose, or destroyed. This might be done either out of anger and frustration, for financial gain (the buoys have quite a large mass of aluminum framing and electronic equipment), or by accident. Regardless of the reason, much time, data, and financial resources are lost and consumed in maintaining TAO array in the Pacific Ocean.

July 19, 2010April 22, 2021

Wesley Struble, 19 July, 2010

NOAA Teacher at Sea
Wes Struble
Onboard NOAA Ship Ka’imimoana
July 8 – August 10, 2010

Mission: Tropical Atmosphere Ocean (TAO) cruise
Geographical area of cruise: Equatorial Pacific: 110 deg W Longitude to 95 deg W Longitude
Date: Monday, 19 July 2010

Weather Data from the Bridge
Cloud Cover: 5/8, Cloud Type” Cumulus,
Visibility: 10 Nautical miles,
Wind bearing: 150 degrees,
Wind speed: 20 knots,
Wave height: 2 – 3 feet,
Swell height: 6 -7 feet,
Atmospheric pressure: 1015.5 mb,
Temperature: 24.5 degrees C (76.1 degrees F)
Current Position: 2 degrees North Latitude, 110 degrees West Longitude

Science and Technology Log

I recently had the opportunity to spend some time talking with Senior Survey Technician (SST), Tonya Watson. Tonya was a Cold War Ocean Systems Technician for four and half years in the US Navy, worked for six years at the California State Dept of Water Resources in the benthic macro invertebrate lab and water quality lab, and has been a civilian Wage Mariner in NOAA for six and a half years both on the Hydrographic vessel Rainier and on the Ka’imimoana (KA). She has an Associates of Science degree from Shasta College and triumphs people who have to rely on work experience without the benefit of four year degrees. Her primary responsibility is running the CTD (Conductivity, Temperature, and Density/Depth) sensor array.

struble_log3_img_1 — Senior Survey Tech, Tonya Watson

Collecting data from the CTD involves lowering a large cylindrical aluminum frame (about 5 feet high and 5 feet in diameter) to a predetermined depth, typically 1000 or 3000 meters (0.6 miles or 1.9 miles), into the sea and slowly retrieving it to the surface, thus creating a classic temperature salinity profile on the way down and collecting water samples for salinity processing on the way up. A typical 3000 meter run takes about 4 hours from start to finish and the CTD is generally deployed at each buoy station and at a number of intermediate latitude coordinates.

struble_log3_img_2 — Above: The CTD; Right: An open Niskin bottle

The platform has numerous points onto which a variety of sensors and ballast may be secured, such as other current profiling sensors like an ADCP (Acoustic Doppler Current Profiler), or varied optics. The SST monitors the operation of the sensors (when the sensors are actually operating and collecting data) and handles tag lines (lines that control the horizontal position of the CTD) during the deployment and retrieval of the CTD package and communicates via radio with a winch operator who operates a “J” Frame winch from a control station located directly above the Survey Operations room. While the CTD is being deployed, a NOAA Corps conning officer is navigating the ship from a remote helm called the Bridge Wing. This location permits the officer to observe the deployment and attempt to hold the ship as stable as possible using only rudder maneuvering by watching the angle of the CTD cable entering the water. The conning officer has to be paying close attention to the wind direction and local ocean currents – anything that will affect the position and motion of the vessel, in order to avoid having the package get fouled under the boat or in the screws. The whole operation can be likened to a musical trio – each playing a different instrument but working to play in harmony to complement one another and complete the piece of music: The conning officer stabilizing the ship, the hoist operator raising and lowering the CTD, and the SST monitoring and operating the sensors, while all three continuously communicate back and forth. It is a fine example of effective team work.

struble_log3_img_0 — Crewmember, Francine Grains, operating the J-hooist during the CTD deployment

struble_log3_img_4 — NOAA Corps Officer, Sarah Slaughter, at the starboard bridge wing during the CTD deployment

The CTD also has the ability to collect water samples during the retrieval phase of operation. The sensors send back a continuous stream of data during the entire round trip measuring the conductivity, the temperature, and the density (depth) of the sea water. In addition, there are a number of 5L water sampling bottles (called Niskin Bottles) secured to the CTD platform that can be remotely triggered to close bringing water samples back from specific depths (they are left open on the way down to avoid being crushed by the immense pressure). These water samples are analyzed in the KA’s wet lab for salinity (concentration of salt) in an Autosal.

The results from the lab work are then compared to the CTD conductivity data log for the same depth. Because there is a direct mathematical relationship between electrical conductivity and salt concentration, this procedure compares the two outcomes looking for a high level of precision (an effective way to verifying the accuracy of the electronic data). Also, an important historical database can be created for an area of the ocean not often accessible to many scientists, which can show trends in temperature and salinity.

Once the data is collected the SST uses various software to put the file into a more readable and easier to use format, and distributed via DVD and ftp upload to the various organizations referred to as “”customers. These customers are other government institutions (both US and foreign), universities, or even other research organizations. In addition, much of this data is available online to the general public for those that are interested. Besides the typical CTD measurements that are made during a standard run other instruments can be mounted on the CTD platform. For example, sensors that measure water clarity (transmissometer), dissolved carbon dioxide concentration, dissolved oxygen concentration, and more can be added to the frame.

Personal Log

The first buoy we reached was at 8 deg N, 110 deg W Longitude. There were no problems with this buoy so this visit was simply for a visual inspection and this we accomplished by making several passes circling around it. Since this buoy is moored in French territorial waters (it is not far from the Clipperton Islands, which is owned by France) we had to obtain permission from the French government to be able to do more than cruise straight by the buoy. We did not receive that permission until the morning of the day we were scheduled to reach the buoy. During this time a number of the crew members put fishing lines out off the fantail (the extreme stern) of the ship. The buoys appear to attract various small fish which of course attract bigger fish and so on up the food chain. In a short time they had caught four nice size (3 – 4 feet long) Mahi mahi (also known as the Dolphin Fish). I assume we will be having a fish dinner sometime very soon. After the inspection we ran a CTD to 3000 meters that did not finish until quite late at night.

struble_log3_img_5 — The 8 deg North, 110 deg West, TAO Buoy

struble_log3_img_6 — Crew member Dana Mancinelli with her Mahi mahi

Animals Seen

I already mentioned that we caught a number of Mahi mahi during the day but during the evening CTD run we had a real treat. Normally a large powerful spotlight is pointed at the water’s surface where the CTD is placed into and removed from the water. During this evening run I joined several of the science members of the crew on deck at the ship’s railing watching squid drawn to the bright spotlight in the water. At times we saw 6 or 7 squid at a time near the surface. They appeared a pinkish red color and were up to approximately a foot long or so. After a while we spied a shadowy figure swimming around and when it came close to the surface we realized it was a small shark no doubt drawn by either the light or the prospects of an evening meal.