NOAA Teacher at Sea
Heather Diaz
Onboard NOAA Ship David Starr Jordan July 6 – 15, 2006
Mission: Juvenile Shark Abundance Survey Geographical Area: U.S. West Coast Date: July 7, 2006
Boy Scout Troop 271, from San Diego, CA, arrives aboard the ship. Chief Boatswain Chico Gomez and Dr. Russ Vetter are also aboard the skiff. The Boy Scouts were participating in an oceanography course on Santa Catalina Island, and the troop was able to take a tour of the ship
Science and Technology Log
This morning everyone woke up ready to catch some more sharks. We set the first line at 6am. It soaked for about 4 hours. Then, we hauled in the line around 10am. During the first set, we caught 7 blue sharks. Unfortunately, we also had one blue shark which died on the line. They think it must have become tangled up on the line, and it died. It was not a very large animal. They dissected it and researchers will use the samples to discover more about these incredible creatures. The afternoon set started around 12pm. We hauled the line in around 4pm. This time, we caught 1 blue, 1 mako, and 1 pelagic ray.
In the afternoon, we picked up another scientist, Dr. Russ Vetter, at Twin Harbors on the coast of Catalina Island. He will be helping us process the animals and tag them, along with Suzy and Rand. We also had 18 Boy Scouts from Troop 271 from San Diego, CA join us. They were brought aboard by Chico, who shuttled them over on the skiff from their campsite on Catalina Island. They had just finished taking a week long course on oceanography and they came aboard to see what our ship was doing. I heard one of them say, “This is awesome, I can’t wait to be able to do this when I grow up!” I think there may be some future NOAA Corps officers in the making! They all seemed genuinely excited to learn about the sharks we are studying, and many of them said they wanted to come back and see more. They all left with big smiles on their faces, and the camp “mom” was very excited to see what an impact the visit had on the boys.
Personal Log
The sunrise this morning was gorgeous! California sea lions and dolphins played alongside the ship all day, and we had a wonderful time watching them and enjoying the sunshine. The scenery is also gorgeous, with a great view of Santa Barbara Island not too far off in the distance.
Oh, one thing that happened during this set which was kind of sad is that we caught 1 blue shark that had gotten tangled up in the line and died, so when we hauled it in, it was dead. So, the pulled it on deck and dissected it. I was able to get some video of it. They are so cute when they are so small like that! They took some DNA samples and some other body parts from it. I didn’t stick around to see what they did with the rest of it. Someone had asked for the jaw (a scientist from Long Beach Aquarium), but if they get another one, I will try to get a jaw. It’s truly amazing to see how their jaw protrudes. Also, I noticed that their teeth are almost translucent. Very interesting!
The bait smelled particularly bad this afternoon. But, we were off the coast of Catalina Island, so the scenery was gorgeous! I saw several dolphin playing, and even a few sea lions playing in the water nearby.
The sunset was equally as gorgeous tonight as it was yesterday, and we finished the evening off near Catalina Island. It was great to see the Boy Scouts come aboard as everything about the ship was exciting to them. I wanted to spend more time talking with them, but they had to go back to shore so that we could move to our next block. I hope that some of them continue to pursue their interest in science! Perhaps someday they will be the Chief Scientist or CO of this cruise!
I am looking forward to seeing more of the Channel Islands! I have only ever seen one of them, and I can’t wait to see Anacapa, as I have seen many photographs of this beautiful little island.
NOAA Teacher at Sea
Heather Diaz
Onboard NOAA Ship David Starr Jordan July 6 – 15, 2006
Mission: Juvenile Shark Abundance Survey Geographical Area: U.S. West Coast Date: July 6, 2006
California sea lions catch a nap on a buoy marker in San Diego Harbor as the DAVID STARR JORDAN leaves port
Science and Technology Log
After everyone boarded the ship and we were underway, the OOD, Junior Officer Sean Finney held a short welcome aboard meeting. He explained the expectations of the scientific crew and regulations while aboard the ship. Afterwards, the Chief Scientist, Dr. Suzy Kohin, held a meeting to explain our mission and to show us how the longlines would be set.
The mission of our cruise is to complete the second leg of the Juvenile Shark Abundance Survey, which is done annually. The first leg was completed last week. During this leg, we will resample the same blocks, so that the data can be compared. Data will then be analyzed from the last 10 years to see if there have been in changes in the mako and blue shark populations. The primary targets for this survey are the juvenile pelagic sharks, the mako and blue sharks. Any other animal that is caught will be measured and that data will also be recorded. Sharks will be tagged and released. If there happens to be a shark that is no longer alive or who is too unhealthy to be released, they will be dissected and specific parts will be preserved for further research. We are hoping that this will not happen. We will also be taking a DNA sample from each shark that is caught. At the end of each set, temperature and latitude and longitude will be recorded. Primary and Secondary Blocks have been predetermined (as these have been the same for the survey over the past 10 years); however, there are a few days in which we may do sets in areas where the temperature of the water or slope of the ocean floor appear to be optimal for catching sharks to tag.
In addition to the primary survey, we will also be doing a Swordfish Feasibility Study, which is a project being conducted by Dr. Heidi Dewar. She is looking to see if it is possible to catch swordfish in this area using a longline set, similar to the one we are using for the Shark Survey. They are also looking at whether or not it would be possible to control the fish well enough to be able to tag its dorsal fin.
Following our meetings, we practiced putting on our “gumby gear” (survival suit), which is made of neoprene and is intended to be worn only during abandon ship situations. It is called “gumby gear” because it covers a person from head to toe in bright red neoprene. Crew members aboard the ship are expected to keep their abandon ship gear close by in case of an emergency, and we have abandon ship drills and fire drills once a week. Every stateroom is equipped with two survival suits and two life jackets. Man overboard drills are conducted once every month or so.
The first longline, which we set at 4pm, was considered a practice set. Setting the longline is comprised of several jobs. The first job is done by Rand Rasmussen. He begins the process by preparing the bait. For the shark sets, we use frozen mackerel. Rand Rasmussen counts out the frozen mackerel and thaws them in 2 coolers using sea water. The mackerel are not baited completely thawed and are actually easier to bait if they are still a little frozen.
The next step is that the deck crew members prepare the lines by taking part of the line and unrolling it from the main roll. They then string it through a pulley that runs along the side of the ship. After the line is ready, the bridge positions the ship so that we are in line with where we should be setting the line. Then, when everyone is in place, they toss the flag. The flag is a flag that is connected to a long pole. The bottom of the pole has a float on it, so that it stands upright. There is also a bright yellow bag that looks like a windsock (called a sea anchor), which is also thrown into the water. This catches the current, and helps to keep that end of the line straight.
Then, one person will unclip the leaders. These are made up of a gangion clip at one end, about 3 fathoms (18 feet) of steel wire, and a stainless steel hook at the other end. The gangions are kept in cans, with 2 rows on 4 sides to which the gangions are clipped. The hooks are looped inside one end of the gangion to keep our hands safe and out of the way from hands that might reach into the can. There are 2 cans of gangions/hooks, and we set around 200 hooks during each set. Once the gangion is unclipped from the can, the hook is removed from the loop, and both ends are handed off to the baiter. The baiter puts the hook into the mackerel’s mouth, then loops it out the underside of the mouth and is then pushed into the back, making a sort of loop around the spine with the hook. The line is then pulled tight.
The baited line is then passed off to the “clipper”. This person waits for a small crimp to pass by on the line as it comes through the pulley and goes down into the water (towards the flag). There are actually 2 small crimps on the line which serve two purposes. First, they keep the gangions from sliding off the line or moving positions. Second, it makes sure that the spacing is uniform on the line. The spacing for this survey is about 25 feet between each gangion. The clipper grabs the line with one hand, and then clips the gangion into the “slot” with the other. The line moves very quickly because the ship is actually moving forward the whole time at a few knots, so the clipper must be fast and accurate.
After 5 baited lines have been clipped, a buoy is clipped on in what would then be the 6th slot on the line. The buoy goes through 2 stages of preparation. First, the buoy is taken from the port side of the ship, where they are stored while not in use. Then, they are clipped on a line near the setting line. One person takes a leader line of nylon rope (again, about 3 fathoms long) and they attach it to the buoy. Then they pass it off to a buoy person, who counts the gangions as they go by and then passes the buoy off to the clipper at the appropriate time.
While the scientists are working with the line, the deck crew is also working with the line at the winch. There are always at least 2 deck crew members on hand to supervise the set. One person runs the winch, and they can adjust the winch to run the line faster or slower as needed. The other person carefully watches the line, to make sure that everyone is being safe and that the line is moving along safely. They signal the winch operator if the line needs to be stopped or sped up. They also keep in constant contact with the bridge to tell them how the set is going.
The bridge can watch the set process through a camera, which they can maneuver so that they can see the line as it comes off the winch, as it is being baited, and as it is deployed in the water. In addition, they can see the line on a computer screen which shows them the “box” where they are trying to set the line. The box is an area on the navigational chart that the scientists have determined as the area in which they would like to set the line. We aren’t concerned about keeping the entire set within the box once we start, but the start point is selected so that most of the line will be in the box. The bridge is responsible for watching for any other boats/ships that might be in the area which could interfere with our line.
Once all the buoys and lines have been deployed, the deck crew disconnects the lines from the winch and attaches the line at the back of the ship. The bridge then watches the line while it “soaks” to make sure it stays as straight as possible. The standard length of soak time for this survey is 4 hours. While we are soaking, the scientists usually take a nap, play a game, catch up on email or research, relax on deck or in the crew’s lounge, get a temperature profile, prepare tags for the haul, catch up on data entry from previous sets, etc.
When it is time to haul, all of the scientists and 3 deck hands are needed. The set up is a little different when we haul in the line, because there are 2 main areas of activity instead of just one. At the very rear of the ship, there is the tagging/measuring area. This is done on two levels. The top level, which is on the same level as the aft deck, is where the data recorders and the deck hand that is operating the platform/cradle lift are located. They are on opposite sides of the ramp. The bottom level is at the bottom of the ramp and is where the platform and the “cradle” are located. Usually Suzy Kohin, the Chief Scientist, and 2 or 3 other scientists are down on the platform during the haul-in. I will explain more about all these jobs below.
The area of activity nearest to the front (bow) of the ship begins with the deck crew members and the line. Once the line is disconnected from the back of the ship, it is brought forwards so that it is in line with the winch. It is threaded across a sort of pulley, and is reconnected to the winch. Two deck hands make sure the line is wound back on the main roll of line evenly. To do this, one person operates the winch’s speed, and they can stop it if necessary, while the other person keeps pressure on the line by holding it with a special tool. This makes sure the line winds correctly and does not get snagged.
Once the line is connected, the process is ready to begin. The bridge gives permission for us to begin hauling in the line, and the first person, who stands near the pulley, unclips the gangion from the line. That person then passes it off to one of two de-baiters. These people pull the bait off the hook and drop it into the ocean. They then put the hook into the gangion loop and pass the whole thing back to the clipper. The clipper then clips the gangions back into their can (the exact reverse of the process when we set). When buoys come up, the buoy line is handed over to a buoy person, who pulls up the leader line and disconnects the buoy from it. They then coil the leader back into its basket while another person takes the buoy to the other side of the deck and attaches it to a line where it is kept while not in use. If there is an animal on the line, everyone yells, “Shark!”, or whatever the animal is. This alerts those at the rear of the ship that there is an animal coming to them. The line that has the animal on it is unclipped, and then a “rope leader” is attached to it, which makes it possible to tie off the line to the ship if there are too many to be processed right away. Then someone “wrangles” the shark to the rear of the ship by literally walking the animal along the side of the boat until they reach the cradle. It’s a very important job because they have to keep enough tension on the animal that the hook doesn’t slip out of their mouth, but they have to also be careful not to pull the animal up and out of the water, which could cause injury to the animal.
The cradle is a sort of half-tube that can be raised and lowered so that it is either closer or farther away from the water. When an animal is brought around, the cradle is lowered so that it is in the water. One of the scientists takes the leader line and takes off the rope. They then pull the animal into the cradle so that its head is facing the port side of the ship. The other scientist is waiting for the animal and he catches its mouth and eyes with one hand and covers the animal’s face with a wet cloth so that it can’t see and to help calm the animal. He uses his arm and other hand to hold the animal down. The scientist that lead the animal into the cradle also gets down on the platform and uses his arms to keep the animal still.
The first thing that is done is a DNA sample. This is done by the Chief Scientist who uses hemostats to hold a small section of the animal’s fin (in the case of a shark, this is the dorsal fin). Then a small scalpel is used to remove a tiny section of fin. This is held in the grip of the hemostat, which is then passed up to the data recorder on deck. They put the sample into a small glass jar which is then labeled with the animal’s number and species. Most DNA samples collected were from makos because the researchers are trying to determine the population genetics structure of the shortfin mako shark in the North Pacific, though 3 other types of animals were also caught.
Once the DNA sample is done, the Chief Scientist inserts an ID tag, called a spaghetti tag, which is from NMFS (National Marine Fisheries Services) into the animal, just in front of the dorsal fin. This is done by making a very small cut with the scalpel, and then the tag is inserted with a long metal probe, which lodges the tag underneath the skin. The tag information is recorded by the data recorder, who later completes a registration card which will identify the animal by the date caught, length, sex, and species. The registration card is kept on file, so that if the animal is ever caught in the future, they can track where the animal has been.
After the spaghetti tag is done, they do another tag, which is placed directly on the dorsal fin. This is called a Roto tag. To do this, the Chief Scientist punches a hole in the dorsal fin with a punch tool. Then, the tag is lined up with the hole and is riveted together. This tag number is also recorded by the data recorder. On some animals, they also place satellite tags and pop-off archival tags, but I have to learn more about how those work. We didn’t do any of those today. The Roto tag has a special tag on it with instructions for fishermen. If the animal is ever recaught, they can send the tag and some of the animal’s vertebrae in for a one hundred dollar reward. This is only done on animals which receive the OTC injection.
Once the animal has been tagged, they turn it on one side to get the sex. This is also recorded by the data recorder. Then, they inject the animal with OTC (oxytetracycline) which is supposed to stain the animal’s vertebrae, which can later help to determine the age of the animal (like the rings on a tree). It also works as an antibiotic, though that is not its primary purpose. This injection is given just about in the middle of what most people would consider the belly of the animal into the visceral cavity. The dosage is based on the approximate length of the animal and is measured out of a small needle. The Chief Scientist gives the injection and holds the tiny hole where the injection was given for a few seconds to prevent any of the OTC from leaking out.
Then, they flip the animal back onto its stomach so that they can remove the hook. They record where the hook was located (either the jaw or if they swallowed it). They usually have to cut the barbed end of the hook off with bolt cutters. The line and the broken hook are then thrown up to the deck to be recycled and refitted with new hooks for use again.
Once the hook is out, the animal is pushed to the end of the cradle and the tip of its nose is lined up with the very edge of the cradle. The side of the cradle has a measuring stick on it. They hold the tail out straight and measure to the very end of it along the tape. Once they have a measurement, they lower the cradle down into the water, and gently push the animal out the end so that it can swim away. Usually makos dive straight down, but blues tend to swim around a while on the surface before diving out of sight.
Everything happens very quickly, so those who are processing the animal must be quick and efficient. The entire process takes no more than a few minutes, which is intended to limit the amount of stress on the animal, and so that we don’t keep them out of the water any longer than absolutely necessary.
Personal Log
When we pulled out of the harbor, I was standing on the fly bridge (the very top). I could see all the other ships and the other boat yards. One cool thing I saw was the Naval Dolphin Training Station. It just looks like a bunch of square cement rings. I could see the dolphins in them, though I don’t know if the pix came out or not. I also saw a pier that was loaded with sea lions. In front of that, we passed a buoy marker which had become the napping place for 2 sea lions…they were very cute. Once we were at sea, I was able to get in my room (room 01-1) and put my things away. Then, I hit the bed and fell sound asleep. While I was asleep Chico Gomez, Chief Boatswain, and Sean Suk caught some Bonita….very pretty fish! I didn’t get to see them whole. But, the meat was a gorgeous salmony-pink color. They said they will smoke it tomorrow afternoon. They said I can try fishing sometime this week. I will give it a try in a few days.
Because this afternoon was our first set, everyone was very excited to do all of the jobs. I chose to do baiting first, and then I switched to doing the unclipping. Both were fun, and everyone talks and laughs, so it was fun. I was really excited to finally be on board and to get to meet everyone. Hauling in the first set was amazing, and I got to see so many sharks! After the set, I spent the time unpacking and getting things ready for the rest of the cruise.
We caught 11 blues, 3 makos, and 1 pelagic ray. We also caught 1 mola mola, but I didn’t see it. I am looking forward to seeing a mola at some point. I couldn’t believe how different it was to see sharks so close, and not in an aquarium!
Today I learned how to tell the difference between a mako and a blue shark…the makos have more streamlined noses, a more silvery color, and they have a more symmetrical tail. The blues have a definite blue color to them, and their tails are distinctively larger on top than on the bottom. Also, makos have a more “thick” area in front of their tail, kind of like the keel of a boat, whereas the blues are more streamlined. You can also tell the difference by their teeth. Mako sharks have little, almost needle-like teeth, whereas the blue sharks have triangular teeth which are serrated on the sides (that is, if you happen to get close enough to see one with its jaws open!). But, they are all very cute!
The ray was also very amazing to see…they are a kind of steely-grey color, and kind of “spaceship” shaped. Very different than the rays I’ve seen around the waters near Florida. I can’t wait to see more sharks and other sea animals tomorrow!
NOAA Teacher at Sea
Brenton Burnett
Onboard NOAA Ship David Starr Jordan June 26 – July 6, 2006
Mission: Shark Abundance Survey Geographical Area: California Coast Date: July 1, 2006
A hooked pelagic ray swims aside the DAVID STARR JORDAN.
Weather Data from Bridge
Visibility: 10 nautical miles (nm)
Wind direction: 315 degrees
Wind speed: 12 kts
Sea wave height: 1’
Swell wave height: 2-4’
Seawater temperature: 19.6 degrees C
Sea level pressure: 1012.5 mb
Cloud cover: Clear
Science and Technology Log
Today’s first run was sharkless but instead we did catch eight pelagic stingrays. In the afternoon we caught two smaller makos and another ray. As I mentioned yesterday, chimera, skates and rays, and sharks make up Class Chondrichthyes. The chimera are the most ancient grouping of these cartilaginous fish. Later came the skates, rays, and sharks in the Subclass Elasmobranch which make up 96% of the cartilaginous fish species. In general, the rays and skates are characterized by a flattened body with their pectoral fins fully attached to the head. This design is an adaptation to living on the seafloor. Creatures that live here are described as benthic. This lifestyle is in contrast to sea life that lives in the open ocean, which is described as pelagic.
Which of the toy models is a ray and which is a skate? Skates have dorsal fins located near the ends of their tails
The pelagic stingray is the only stingray that is not benthic. This behavior may be a relatively recent occurrence on evolutionary time scales, however, as it retains a number of characteristics best designed tails. Like all skates and rays, their mouths are located under their flattened body. In this position, they can swim along the bottom and suck in prey off the seafloor. I recently witnessed such feeding as I fed a bat ray at SeaWorld last week.
The gills of skates and rays (collectively known as the batoids) are located underneath, or ventral, to the body. When resting on the bottom, water flow through the gills is limited and so obtaining oxygen would be a problem if it weren’t for another feature common in cartilaginous fish, the spiracle. Most sharks also have spiracles, which are small holes on either side of their head. They have a respiratory function. In rays and skates these spiracles are located just behind the eyes up on the top of the head. When the pelagic rays are out of the water, the opening and closing of the spiracles as they breathed was obvious. There are two features most useful in distinguishing a skate from a ray. Most skates have one or two dorsal fins located far back on their tails, and they never have spines that are typical of rays.
The spine of a ray is often toxic and used as a defense by the ray. When the pelagic rays were brought on board, the first priority was the safety of the humans. The spine was snipped or if possible, the ray is placed upside down on foam that ultimately will take a spine “hit” and from then on cover the spine. The toxin of a ray’s spine is not delivered in the way a snake’s fangs might inject its poison. A ray’s spine is serrated and acts like a harpoon or barbed hook, preventing removal in the opposite direction from which it was inserted. The spine of a stingray has serrated edges but is in the form of a mucous that fills two that make it virtually impossible to remove a grooves on the underside of the spine.
The spiracles of a stingray are located just behind the eyes. The spine, sometimes two or three of them, is found near the base of the tail.
A pelagic ray is on the shark platform belly up. Its spine is safely lodged into the foam. A puncture made by the spine that may then be infected by the toxic mucous. Telling shark from batoid is not always easy. The order of sharks known as angel sharks bear resemblance to batoids but their pectoral fins are clearly not fully attached to the head, and their mouths are at the front of the head and not underneath as it is in all rays and skates. Other kinds of sharks and rays that can be confused are the sawshark, which is a shark, and the sawfish, which is a ray. Both have a bizarre flattened snout from which teeth stick laterally, or sideways, outwards. They both have a thicker more sharklike body. Both have two dorsal fins, a set of pectoral fins and a set of pelvic fins. But they are no more closely related than any shark is to any ray. When two different types of animals (or plants, or other living thing) are faced with similar challenges, they can sometimes independently evolve in a way that arrives at a similar solution. Bats, birds and butterflies each independently evolved flight. Triceratops and rhinos evolved head horns. Mako sharks and dolphins evolved sleek torpedo shaped bodies for rapid swimming.
A pelagic ray is on the shark platform belly up. Its spine is safely lodged into the foam.
And sawsharks and sawfish have independently evolved a saw shaped snout. Each is believed to use their snout to capture and kill prey. But they also retain their sharkiness Angel sharks are flattened like a ray but their pectoral fins are distinctly unattached from the head. Angel sharks have mouths at the front of the head while all batoids have mouths located ventrally, or under the body. There five known species of sawsharks. They, like most other sharks, have their gill slits on the sides of their head. Also, their pectoral fins are not fully attached to the head. Sawsharks have a pair of barbels coming from the sides of their snouts, giving them a mustachioed appearance. Sawsharks like other sharks have a sensitivity to the electrical disturbances created by moving fish and other prey. Their snout enhances this sensitivity. But the sawfish has no such electrical organ. The sawfish does have pectoral fins that attach fully to the head where the sawshark’s pectoral fins do not. Additionally, the pectoral and pelvic fins of the sawfish are flatter and more flush with the body. And the gills of the sawfish are underneath the head, but they are found on the side of the head on the sawshark. Lastly, another feature that distinguishes the two are the sawshark barbels that stick out from the middles of their snouts like moustaches—sawfish do not have these.
The spine of a stingray has serrated edges that make it virtually impossible to remove a spine by simply pulling it out the way it went in.
I need to address a couple of student questions that I don’t believe I’ve yet answered:
Oxytetracycline (OTC), the dye used to stain the vertebrae for aging studies, is not known to do harm to the shark if given in excess. However, a table of calculated dosages based on length is used because if too much OTC is used, growth layers other than just the present one will also become stained.
The J-hooks typically used are about four inches in length. The shark abundance survey has been going on since 1994, and to maintain consistent and scientifically comparable data, they continue to use these hooks.
Sharks have few enemies in the oceans. They tend to be the top predators in their food webs, but as the vast majority of sharks are less than one meter (three feet) long, they can be come prey for other, larger sharks, or even whales like orca. By far the species that poses the largest threat to them are humans. Mostly humans kill sharks when it is other types of fish that meant to be caught. The shark would then be referred to as “by-catch”. At other times sharks are intentionally caught for their meat or as sport—this is often the case for mako sharks.
Angel sharks are flattened like a ray but their pectoral fins are distinctly unattached from the head.
Sawfish have their gills located underneath their head like all other batoids.
Oxytetracycline is light sensitive, meaning it reacts and breaks down when exposed to enough light. For this reason the bottle is brown and kept in a bag, and loaded syringes are kept inside a glove for ready use.
The J-hook and somewhat smaller circle hook are used for mako and thresher shark lines.
Personal Log
I continue to have a good time here, if not for the sights and sounds but for the people I am working with. Lots of interesting, friendly, and fun-loving folks. And, happily, they have been quite tolerant, and even obliging of me walking around with my video camera catching this and that.
Angel sharks have mouths at the front of the head while all batoids have mouths located ventrally, or under the body.There five known species of sawsharks. They, like most other sharks, have their gill slits on the sides of their head. Also, their pectoral fins are not fully attached to the head.Sawsharks have a pair of barbels coming from the sides of their snouts, giving them a mustachioed appearance.Sawfish have their gills located underneath their head like all other batoids.Oxytetracycline is light sensitive, meaning it reacts and breaks down when exposed to enough light. For this reason the bottle is brown and kept in a bag, and loaded syringes are kept inside a glove for ready use.The J-hook (right) and somewhat smaller circle hook are used for mako and thresher shark lines.
NOAA Teacher at Sea
Brenton Burnett
Onboard NOAA Ship David Starr Jordan June 26 – July 6, 2006
Mission: Shark Abundance Survey Geographical Area: California Coast Date: June 30, 2006
Weather Data from Bridge
Visibility: 10 nautical miles (nm)
Wind direction: 250 degrees
Wind speed: 9 kts
Sea wave height: <1
Swell wave height: 1-2’
Seawater temperature: 17.6 degrees C
Sea level pressure: 1015 mb
Cloud cover: Clear
Russ Vetter and Rand Rasmussen position a blue shark so they can measure its length and remove the hook.
Science and Technology Log
Today was a slower day in terms of numbers of sharks—we only caught three. But the mood was good because each of the sharks caught was large enough to accommodate satellite tags. And, we caught one of each species of shark that we anticipate seeing—a blue, a thresher and a mako. The mako was particularly lively giving a good kick as it left the shark trough. Any of the sharks tagged on this trip, or others in the same effort, can be monitored here. On this cruise we have attached SPOT tags to two makos (on Tuesday #60986 and today, #60998), a blue (#60989) and a thresher (#53797). Note: I’m told that all four of these MAY be listed as blues on the website until the website is fully updated, but the tracks of all four sharks should be viewable right now!
All sharks are in the phylum Chordata. They, along with rays and skates, and a strange and even more ancient group of fish called chimera, make up Class Chondrichthyes, which are the fish with skeletons made of cartilage. The only bony material in a shark is its teeth and for this reason very few shark fossils beyond teeth are found. The other classes of chordates are the jawless fishes (hagfish and lamprey), the bony fishes (minnows, mola, cod, seahorses, etc.), amphibians, reptiles, mammals and birds.
The goblin shark—perhaps the ugliest shark ever!
Each class is divided up into orders, and there are eight orders of sharks— one order includes the sawsharks, another the whale shark and wobbegong, and another the angelsharks (which have some resemblance to rays). The frilled and cow sharks make up another order, the bullhead sharks another, and there is an order for the dogfish sharks (including the spiny dogfish which might be the most numerous of all shark species—closer to shore, we may hook one). All of these orders are sharks but when people think of sharks they typically envision either mackeral sharks, which include great whites, makos, tigers and threshers, or the ground sharks, which include leopard sharks, hammerheads and blue sharks.
The 16 species of mackeral sharks are among the most specialized of sharks. Many, like the mako, are swift swimmers. Threshers have a tail that is as long as the rest of their body is. It is believed that they use this tail to “corral” fish and then slap the fish to stun them. The goblin shark lives in the dark of the deep and has a strange snout jaw structure that makes it arguably the ugliest shark. The first of these was caught in 1897 near Japan. A scientist there delivered it to Professor David Starr Jordan, for whom the National Oceanic and Atmospheric Administration ship we are on is named.
The ship awaits the return of its Zodiac boat.
With over 200 species, the ground sharks are the most diverse and varied order of sharks. The blue shark is a generalist living in open waters in nearly all of the world’s oceans. Others, like the catsharks are benthic, or bottom-dwelling. Most are small and harmless but some are the largest of predatory sharks. All of them have what’s called a nictitating eyelid which covers the eyes to protect them as the shark bites.
Personal Log
During today’s afternoon set, we inadvertently lost a buoy that was intended to be clipped to the longline. Fortunately, such a mishap is occasion to let loose the ship’s two engine Zodiac. Myself, Stephanie Snyder (an intern with NOAA), Miguel Olvera, and crewmembers Chico Gomez and David Gothan, set out to retrieve it. The buoy was dropped early in the set so we had to travel a couple miles out. On the way, we briefly saw four molas. Later a sea lion passed by.
An adventure here, an adventure there—the fifth day is as interesting as the first!
NOAA Teacher at Sea
Brenton Burnett
Onboard NOAA Ship David Starr Jordan June 26 – July 6, 2006
Mission: Shark Abundance Survey Geographical Area: California Coast Date: June 29, 2006
Weather Data from Bridge
Visibility: 10 nautical miles (nm)
Wind direction: 306 degrees
Wind speed: 15 kts
Sea wave height: 1-2’
Swell wave height: 2-3’
Seawater temperature: 19.8 degrees C
Sea level pressure: 1017 mb
Cloud cover: Partly cloudy
The beaks of a variety of squids and a fisheye lens found in a blue shark’s stomach.
Science and Technology Log
While today’s catches were lighter than yesterday’s, there were some very interesting new sights to see. One blue shark that made it up on deck, threw up some of its stomach contents. Out came the remains of a pelagic (open water) crab and a number of squid beaks. The largest of these beaks was three centimeters (just over an inch) in diameter and the smallest less than a half a centimeter. Blue sharks are perhaps the most widely distributed shark, living in all oceans except in the polar latitudes. As such, they are generalists and eat squid, fish, smaller sharks and even birds. Jacques Cousteau even filmed blues shepherding virtually invisible krill into balled clusters so they could swim through the ball to feast. While setting the afternoon line, I saw a curved tip dorsal fin break the surface off the starboard bow. Then it disappeared under a wave. Moments later as we caught up to it, a large disc of a fish could be seen below the fin—a mola!! Molas are the largest bony fish though they are not the largest of all fishes. That honor belongs to the docile plankton-eating whale shark. Molas can reach a length over 4 m (13 feet), though the one we saw was closer to 2 m (6 feet). Whale sharks, however, can grow to over 20 m (70 feet) long.
Bottlenose dolphins porpoising in front of the bow
Later, as we hauled the afternoon set, another mild surprise—a pelagic stingray was caught on our line! Once aboard, the highest priority was to disarm the poisonous spine projecting from the base of the stingray’s tail. While Sean Suk, another Southwest Fisheries Science Center (SWFSC) researcher, held the ray down, Suzy Kohin was able to clip the spine disabling the ray, but not harming it. Rays and skates evolved flattened bodies as an adaptation as benthic, or bottom feeders. Rays and skates, or batoids as they are called collectively, have a mouth positioned on the bottoms of their bodies so they can best feed along the bottom of the ocean. Pelagic rays, as their name implies, live in the open ocean. So the pelagic ray has evolved a unique style of feeding. When approaching a school of fish, this ray will turn upside down and curl its wings above it forming a funnel. This funnel shape directs the fish right to its mouth.
In the evening, after our work was done for the day, a few of us were on the stern deck when a school of dolphins approached. Soon they surrounded the ship and a group of six or seven stayed with us porpoising at our bow for close to thirty minutes! “Porpoising” is the arched jumping above the water as dolphins swim. This behavior allows these mammals to breathe while maintaining their pace. Porpoising should not be confused with breaching which is a more vertical jump from the water. Breaching behavior has been observed in a number of whale species, but also in some sharks. The two shark species best known for breaching happen to be the two species we are most interested in on this cruise—makos and threshers. Scientists are not certain why whales breach, nor are they entirely certain why sharks breach. At least a partial answer may be that they are making an attack on prey. Many sharks, not just blues, are known to eat sea birds, and makos, specifically, have been seen jumping from the water in attempts to attack floating sea birds. White sharks, the larger cousins of makos, are known to breach but in False Bay near Dyer Island off South Africa, this behavior could even be described as common. The unique seafloor topography there forces the southern fur seals to repeatedly swim from surface to seafloor as they make their way to the island (if they didn’t they would be eaten by the sharks outright). Researchers have discovered that as the great whites pursue the seals from the depths their momentum takes them up and fully out of the water in spectacular breaches.
Personal Log
Every day on board brings something new to this mountain man. On deck, when critters aren’t appearing on board or in the sea, there are always science folks to answer questions. Of course, that is when they aren’t watching World Cup soccer via the satellite TV. ‘Til, tomorrow…
